Your search keyword '"Mark A. Batzer"' showing total 186 results

1. Owl Monkey

Author

Jessica M, Storer, Jerilyn A, Walker, Lydia C, Rewerts, Morgan A, Brown, Thomas O, Beckstrom, Scott W, Herke, Christian, Roos, and Mark A, Batzer

Subjects

Aotus trivirgatus, Alu Elements, Animals, Aotidae, Sequence Analysis, DNA, Phylogeny

Abstract

Owl monkeys (genus

Published

2022

2. Cebidae

Author

Jessica M, Storer, Jerilyn A, Walker, Morgan A, Brown, and Mark A, Batzer

Abstract

Phylogenetic relationships among Cebidae species of platyrrhine primates are presently under debate. Studies prior to whole genome sequence (WGS) availability utilizing unidirectional

Published

2022

3. A high-quality bonobo genome refines the analysis of hominid evolution

Author

Melanie Sorensen, Yafei Mao, Sofie R. Salama, Claudia Rita Catacchio, Andy Wing Chun Pang, Françoise Thibaud-Nissen, Carl Baker, LaDeana W. Hillier, Ruiyang Li, Arvis Sulovari, Philip C. Dishuck, PingHsun Hsieh, Katherine M. Munson, Ludovica Mercuri, Jason D Fernandes, Jessica M. Storer, Joyce V. Lee, Benedict Paten, Mark A. Batzer, Peter A. Audano, David Porubsky, Tzu-Hsueh Huang, Jason G. Underwood, Evan E. Eichler, Jinna Hoffman, William T. Harvey, Kendra Hoekzema, Jerilyn A. Walker, Ian T. Fiddes, David Gordon, Marina Haukness, Alex Hastie, Alexandra P. Lewis, Francesca Antonacci, Mario Ventura, Shwetha C. Murali, Francesco Montinaro, Ilaria Piccolo, and Mark Diekhans

Subjects

Pan troglodytes, Sequence assembly, Genomics, Biology, Genome informatics, Genome, Article, Evolutionary genetics, Coalescent theory, Evolution, Molecular, 03 medical and health sciences, Segmental Duplications, Genomic, 0302 clinical medicine, Animals, Sequencing, Phylogeny, 030304 developmental biology, Segmental duplication, 0303 health sciences, Gorilla gorilla, Multidisciplinary, Bonobo, Pongo, Molecular Sequence Annotation, Sequence Analysis, DNA, Pan paniscus, biology.organism_classification, Genome evolution, Genes, Evolutionary biology, Eukaryotic Initiation Factor-4A, Female, Human genome, Mobile genetic elements, 030217 neurology & neurosurgery

Abstract

The divergence of chimpanzee and bonobo provides one of the few examples of recent hominid speciation1,2. Here we describe a fully annotated, high-quality bonobo genome assembly, which was constructed without guidance from reference genomes by applying a multiplatform genomics approach. We generate a bonobo genome assembly in which more than 98% of genes are completely annotated and 99% of the gaps are closed, including the resolution of about half of the segmental duplications and almost all of the full-length mobile elements. We compare the bonobo genome to those of other great apes1,3–5 and identify more than 5,569 fixed structural variants that specifically distinguish the bonobo and chimpanzee lineages. We focus on genes that have been lost, changed in structure or expanded in the last few million years of bonobo evolution. We produce a high-resolution map of incomplete lineage sorting and estimate that around 5.1% of the human genome is genetically closer to chimpanzee or bonobo and that more than 36.5% of the genome shows incomplete lineage sorting if we consider a deeper phylogeny including gorilla and orangutan. We also show that 26% of the segments of incomplete lineage sorting between human and chimpanzee or human and bonobo are non-randomly distributed and that genes within these clustered segments show significant excess of amino acid replacement compared to the rest of the genome., A high-quality bonobo genome assembly provides insights into incomplete lineage sorting in hominids and its relevance to gene evolution and the genetic relationship among living hominids.

Published

2021

4. Genome Organisation: Human

Author

Mark A. Batzer and David H. Kass

Subjects

Computational biology, Biology, Genome

Published

2021

5. Recently Integrated

Author

Jessica M, Storer, Jerilyn A, Walker, Catherine E, Rockwell, Grayce, Mores, Thomas O, Beckstrom, Joseph D, Orkin, Amanda D, Melin, Kimberley A, Phillips, Christian, Roos, and Mark A, Batzer

Subjects

Alu Elements, Sapajus, Animals, Cebus, Genomics, Phylogeny

Abstract

Capuchins are platyrrhines (monkeys found in the Americas) within the Cebidae family. For most of their taxonomic history, the two main morphological types of capuchins, gracile (untufted) and robust (tufted), were assigned to a single genus

Published

2022

6. Owl Monkey Alu Insertion Polymorphisms and Aotus Phylogenetics

Author

Jessica M. Storer, Jerilyn A. Walker, Lydia C. Rewerts, Morgan A. Brown, Thomas O. Beckstrom, Scott W. Herke, Christian Roos, and Mark A. Batzer

Subjects

Genetics, Aotidae, owl monkey, Alu, Aotus, phylogeny, Platyrrhini, Genetics (clinical)

Abstract

Owl monkeys (genus Aotus), or “night monkeys” are platyrrhine primates in the Aotidae family. Early taxonomy only recognized one species, Aotus trivirgatus, until 1983, when Hershkovitz proposed nine unique species designations, classified into red-necked and gray-necked species groups based predominately on pelage coloration. Recent studies questioned this conventional separation of the genus and proposed designations based on the geographical location of wild populations. Alu retrotransposons are a class of mobile element insertion (MEI) widely used to study primate phylogenetics. A scaffold-level genome assembly for one Aotus species, Aotus nancymaae [Anan_2.0], facilitated large-scale ascertainment of nearly 2000 young lineage-specific Alu insertions. This study provides candidate oligonucleotides for locus-specific PCR assays for over 1350 of these elements. For 314 Alu elements across four taxa with multiple specimens, PCR analyses identified 159 insertion polymorphisms, including 21 grouping A. nancymaae and Aotus azarae (red-necked species) as sister taxa, with Aotus vociferans and A. trivirgatus (gray-necked) being more basal. DNA sequencing identified five novel Alu elements from three different taxa. The Alu datasets reported in this study will assist in species identification and provide a valuable resource for Aotus phylogenetics, population genetics and conservation strategies when applied to wild populations.

Published

2022

7. Cebidae Alu Element Alignments and a Complex Non-Human Primate Radiation

Author

Jessica M. Storer, Jerilyn A. Walker, Morgan A. Brown, and Mark A. Batzer

Subjects

Space and Planetary Science, Cebidae, Alu, phylogeny, platyrrhine, Paleontology, General Biochemistry, Genetics and Molecular Biology, Ecology, Evolution, Behavior and Systematics

Abstract

Phylogenetic relationships among Cebidae species of platyrrhine primates are presently under debate. Studies prior to whole genome sequence (WGS) availability utilizing unidirectional Alu repeats linked Callithrix and Saguinus as sister taxa, based on a limited number of genetic markers and specimens, while the relative positions of Cebus, Saimiri and Aotus remained controversial. Multiple WGS allowed computational detection of Alu-genome junctions, however random mutation and evolutionary decay of these short-read segments prevented phylogenetic resolution. In this study, WGS for four Cebidae genomes of marmoset, squirrel monkey, owl monkey and capuchin were analyzed for full-length Alu elements and each locus was compared to the other three genomes in all possible combinations using orthologous region sequence alignments. Over 2000 candidates were aligned and subjected to visual inspection. Approximately 34% passed inspection and were considered shared in their respective category, 48% failed due to the target being present in all four genomes, having N’s in the sequence or other sequence quality anomalies, and 18% were determined to represent near parallel insertions (NP). Wet bench locus specific PCR confirmed the presence of shared Alu insertions in all phylogenetically informative categories, providing evidence of extensive incomplete lineage sorting (ILS) and an abundance of Alu proliferation during the complex radiation of Cebidae taxa.

Published

2022

8. Author Correction: Comparative and demographic analysis of orang-utan genomes

Author

Devin P. Locke, LaDeana W. Hillier, Wesley C. Warren, Kim C. Worley, Lynne V. Nazareth, Donna M. Muzny, Shiaw-Pyng Yang, Zhengyuan Wang, Asif T. Chinwalla, Pat Minx, Makedonka Mitreva, Lisa Cook, Kim D. Delehaunty, Catrina Fronick, Heather Schmidt, Lucinda A. Fulton, Robert S. Fulton, Joanne O. Nelson, Vincent Magrini, Craig Pohl, Tina A. Graves, Chris Markovic, Andy Cree, Huyen H. Dinh, Jennifer Hume, Christie L. Kovar, Gerald R. Fowler, Gerton Lunter, Stephen Meader, Andreas Heger, Chris P. Ponting, Tomas Marques-Bonet, Can Alkan, Lin Chen, Ze Cheng, Jeffrey M. Kidd, Evan E. Eichler, Simon White, Stephen Searle, Albert J. Vilella, Yuan Chen, Paul Flicek, Jian Ma, Brian Raney, Bernard Suh, Richard Burhans, Javier Herrero, David Haussler, Rui Faria, Olga Fernando, Fleur Darré, Domènec Farré, Elodie Gazave, Meritxell Oliva, Arcadi Navarro, Roberta Roberto, Oronzo Capozzi, Nicoletta Archidiacono, Giuliano Della Valle, Stefania Purgato, Mariano Rocchi, Miriam K. Konkel, Jerilyn A. Walker, Brygg Ullmer, Mark A. Batzer, Arian F. A. Smit, Robert Hubley, Claudio Casola, Daniel R. Schrider, Matthew W. Hahn, Victor Quesada, Xose S. Puente, Gonzalo R. Ordoñez, Carlos López-Otín, Tomas Vinar, Brona Brejova, Aakrosh Ratan, Robert S. Harris, Webb Miller, Carolin Kosiol, Heather A. Lawson, Vikas Taliwal, André L. Martins, Adam Siepel, Arindam RoyChoudhury, Xin Ma, Jeremiah Degenhardt, Carlos D. Bustamante, Ryan N. Gutenkunst, Thomas Mailund, Julien Y. Dutheil, Asger Hobolth, Mikkel H. Schierup, Oliver A. Ryder, Yuko Yoshinaga, Pieter J. de Jong, George M. Weinstock, Jeffrey Rogers, Elaine R. Mardis, Richard A. Gibbs, and Richard K. Wilson

Subjects

Multidisciplinary

Published

2022

9. Evolution of Alu Subfamily Structure in the Saimiri Lineage of New World Monkeys

Author

Jasmine N. Baker, Paulina Gonzalez-Quiroga, Kacie R. Phillippe, Miriam K. Konkel, Jackson R. Mierl, Mark A. Batzer, John A. Vanchiere, Jerilyn A. Walker, Corey P. St. Romain, and Michael W. Denham

Subjects

0106 biological sciences, 0301 basic medicine, Genome evolution, Lineage (genetic), Subfamily, Alu, viruses, Alu element, Retrotransposon, 010603 evolutionary biology, 01 natural sciences, Genome, Evolution, Molecular, 03 medical and health sciences, Short Interspersed Element, Alu Elements, biology.animal, evolution, parasitic diseases, Genetics, Animals, Primate, Saimiri, Ecology, Evolution, Behavior and Systematics, biology, retrotransposon, 3. Good health, 030104 developmental biology, Evolutionary biology, subfamilies, Research Article

Abstract

Squirrel monkeys, Saimiri, are commonly found in zoological parks and used in biomedical research. S. boliviensis is the most common species for research; however, there is little information about genome evolution within this primate lineage. Here, we reconstruct the Alu element sequence amplification and evolution in the genus Saimiri at the time of divergence within the family Cebidae lineage. Alu elements are the most successful SINE (Short Interspersed Element) in primates. Here, we report 46 Saimiri lineage specific Alu subfamilies. Retrotransposition activity involved subfamilies related to AluS, AluTa10, and AluTa15. Many subfamilies are simultaneously active within the Saimiri lineage, a finding which supports the stealth model of Alu amplification. We also report a high resolution analysis of Alu subfamilies within the S. boliviensis genome [saiBol1].

Published

2017

10. Sensitivity of the polyDetect computational pipeline for phylogenetic analyses

Author

Mark A. Batzer, Jerilyn A. Walker, Vallmer E Jordan, and Jessica M. Storer

Subjects

Biophysics, Alu element, 01 natural sciences, Biochemistry, Genome, DNA sequencing, Homology (biology), Evolution, Molecular, 03 medical and health sciences, Phylogenetics, Alu Elements, Cebidae, Animals, Molecular Biology, Phylogeny, 030304 developmental biology, 0303 health sciences, Phylogenetic tree, biology, 010401 analytical chemistry, Cell Biology, Sequence Analysis, DNA, biology.organism_classification, 0104 chemical sciences, Taxon, Evolutionary biology

Abstract

Alu elements are powerful phylogenetic markers. The combination of a recently-developed computational pipeline, polyDetect, with high copy number Alu insertions has previously been utilized to help resolve the Papio baboon phylogeny with high statistical support. Here, the polyDetect method was applied to the highly contentious Cebidae phylogeny within New World monkeys (NWM). The polyDetect method relies on conserved homology/identity of short read sequence data among the species being compared to accurately map predicted shared Alu insertions to each unique flanking sequence. The results of this comprehensive assessment indicate that there were insufficient sequence homology/identity stretches in non-repeated DNA sequences among the four Cebidae genera analyzed in this study to make this strategy phylogenetically viable. The ~20 million years of evolutionary divergence of the Cebidae genera has resulted in random sequence decay within the short read data, obscuring potentially orthologous elements in the species tested. These analyses suggest that the polyDetect pipeline is best suited to resolving phylogenies of more recently diverged lineages when high-quality assembled genomes are not available for the taxa of interest.

Published

2019

11. Amplification Dynamics of Platy-1 Retrotransposons in the Cebidae Platyrrhine Lineage

Author

Lydia C. Rewerts, Joseph D. Orkin, Jessica M. Storer, Jasmine N. Baker, Amanda D. Melin, Kimberley A. Phillips, Miriam K. Konkel, Corey P. St. Romain, Yahor Sukharutski, Mark A. Batzer, Sarah A. Brantley, Jackson R. Mierl, Jerilyn A. Walker, Breanna Threeton, and Madeline M Foreman

Subjects

0106 biological sciences, Retroelements, Retrotransposon, 010603 evolutionary biology, 01 natural sciences, Genome, insertion, polymorphism, 03 medical and health sciences, biology.animal, parasitic diseases, evolution, Genetics, Cebidae, Animals, Ecology, Evolution, Behavior and Systematics, Aotus nancymaae, 030304 developmental biology, New World monkey, 0303 health sciences, biology, Squirrel monkey, Gene Amplification, Marmoset, biology.organism_classification, Saimiri boliviensis, Evolutionary biology, subfamilies, Research Article

Abstract

Platy-1 elements are Platyrrhine-specific, short interspersed elements originally discovered in the Callithrix jacchus (common marmoset) genome. To date, only the marmoset genome has been analyzed for Platy-1 repeat content. Here, we report full-length Platy-1 insertions in other New World monkey (NWM) genomes (Saimiri boliviensis, squirrel monkey; Cebus imitator, capuchin monkey; and Aotus nancymaae, owl monkey) and analyze the amplification dynamics of lineage-specific Platy-1 insertions. A relatively small number of full-length and lineage-specific Platy-1 elements were found in the squirrel, capuchin, and owl monkey genomes compared with the marmoset genome. In addition, only a few older Platy-1 subfamilies were recovered in this study, with no Platy-1 subfamilies younger than Platy-1-6. By contrast, 62 Platy-1 subfamilies were discovered in the marmoset genome. All of the lineage-specific insertions found in the squirrel and capuchin monkeys were fixed present. However, ∼15% of the lineage-specific Platy-1 loci in Aotus were polymorphic for insertion presence/absence. In addition, two new Platy-1 subfamilies were identified in the owl monkey genome with low nucleotide divergences compared with their respective consensus sequences, suggesting minimal ongoing retrotransposition in the Aotus genus and no current activity in the Saimiri, Cebus, and Sapajus genera. These comparative analyses highlight the finding that the high number of Platy-1 elements discovered in the marmoset genome is an exception among NWM analyzed thus far, rather than the rule. Future studies are needed to expand upon our knowledge of Platy-1 amplification in other NWM genomes.

Published

2019

12. Discovery of a new repeat family in the Callithrix jacchus genome

Author

Brygg Ullmer, Miriam K. Konkel, Erika L. Arceneaux, Mark A. Batzer, Sarah A. Brantley, Robert Hubley, Sreeja Sanampudi, and Arian F.A. Smit

Subjects

0301 basic medicine, Genetics, Lineage (genetic), Subfamily, Retroelements, biology, Research, Alu element, Marmoset, Callithrix, Retrotransposon, biology.organism_classification, Genome, Evolution, Molecular, 03 medical and health sciences, Short Interspersed Element, 030104 developmental biology, Alu Elements, biology.animal, Animals, Phylogeny, Genetics (clinical)

Abstract

We identified a novel repeat family, termed Platy-1, in the Callithrix jacchus (common marmoset) genome that arose around the time of the divergence of platyrrhines and catarrhines and established itself as a repeat family in New World monkeys (NWMs). A full-length Platy-1 element is ∼100 bp in length, making it the shortest known short interspersed element (SINE) in primates, and harbors features characteristic of non-LTR retrotransposons. We identified 2268 full-length Platy-1 elements across 62 subfamilies in the common marmoset genome. Our subfamily reconstruction and phylogenetic analyses support Platy-1 propagation throughout the evolution of NWMs in the lineage leading to C. jacchus. Platy-1 appears to have reached its amplification peak in the common ancestor of current day marmosets and has since moderately declined. However, identification of more than 200 Platy-1 elements identical to their respective consensus sequence, and the presence of polymorphic elements within common marmoset populations, suggests ongoing retrotransposition activity. Platy-1, a SINE, appears to have originated from an Alu element, and hence is likely derived from 7SL RNA. Our analyses illustrate the birth of a new repeat family and its propagation dynamics in the lineage leading to the common marmoset over the last 40 million years.

Published

2016

13. The comparative genomics and complex population history of

Author

Jeffrey, Rogers, Muthuswamy, Raveendran, R Alan, Harris, Thomas, Mailund, Kalle, Leppälä, Georgios, Athanasiadis, Mikkel Heide, Schierup, Jade, Cheng, Kasper, Munch, Jerilyn A, Walker, Miriam K, Konkel, Vallmer, Jordan, Cody J, Steely, Thomas O, Beckstrom, Christina, Bergey, Andrew, Burrell, Dominik, Schrempf, Angela, Noll, Maximillian, Kothe, Gisela H, Kopp, Yue, Liu, Shwetha, Murali, Konstantinos, Billis, Fergal J, Martin, Matthieu, Muffato, Laura, Cox, James, Else, Todd, Disotell, Donna M, Muzny, Jane, Phillips-Conroy, Bronwen, Aken, Evan E, Eichler, Tomas, Marques-Bonet, Carolin, Kosiol, Mark A, Batzer, Matthew W, Hahn, Jenny, Tung, Dietmar, Zinner, Christian, Roos, Clifford J, Jolly, Richard A, Gibbs, and Kim C, Worley

Subjects

Gene Flow, Male, Polymorphism, Genetic, Base Sequence, Whole Genome Sequencing, viruses, SciAdv r-articles, Genomics, Biological Evolution, humanities, Haplotypes, Anthropology, embryonic structures, Animals, Humans, Hybridization, Genetic, Female, Phylogeny, Research Articles, Papio, Research Article

Abstract

We analyzed genome sequences from 6 baboon species and found evidence of ancient and recent hybridization among divergent species., Recent studies suggest that closely related species can accumulate substantial genetic and phenotypic differences despite ongoing gene flow, thus challenging traditional ideas regarding the genetics of speciation. Baboons (genus Papio) are Old World monkeys consisting of six readily distinguishable species. Baboon species hybridize in the wild, and prior data imply a complex history of differentiation and introgression. We produced a reference genome assembly for the olive baboon (Papio anubis) and whole-genome sequence data for all six extant species. We document multiple episodes of admixture and introgression during the radiation of Papio baboons, thus demonstrating their value as a model of complex evolutionary divergence, hybridization, and reticulation. These results help inform our understanding of similar cases, including modern humans, Neanderthals, Denisovans, and other ancient hominins.

Published

2018

14. The common marmoset genome provides insight into primate biology and evolution

Author

San Juana Ruiz, Daniel Gerlach, Tomas Vinar, Brona Brejova, Saba Sajjadian, Miriam K. Konkel, Muthuswamy Raveendran, Yih Shin Liu, Paul Flicek, Lubomir Tomaska, Donna M. Muzny, Daniel R. Schrider, Megan C. Ranck, Kjersti Aagaard, Huyen Dinh, Jayantha B. Tennakoon, Lucinda Fulton, Lynne V. Nazareth, Brygg Ullmer, George M. Weinstock, Kim D. Delehaunty, Xose S. Puente, Charles E. Vejnar, Shyam Prabhakar, Matthew W. Hahn, J. Scott Moncrieff, Mark A. Batzer, Tina Graves, Catherine C. Fontenot, Carlos López-Otín, Corinna N. Ross, Catrina Fronick, Jeffrey Rogers, Nirmala Arul Rayan, Mario Ventura, Pieter J. De Jong, Elaine R. Mardis, Steve Searle, Christie LKovar, David Haig, Ngoc Nguyen, Shalini N. Jhangiani, Margaret Morgan, Crystal M. Warner, Mimi M. Chandrabose, Keith G. Mansfield, Vandita Joshi, Kathryn Beal, Saverio B. Capuano, Magali Ruffier, Ling Ling Pu, Jerilyn A. Walker, Marvin Diep Dao, John Lopez, Irene Newsham, Yuanqing Wu, Jan Hinnerk Vogel, Arian F.A. Smit, Javier Herrero, Andrew Cree, Tomas Marques-Bonet, Oronzo Capozzi, LaDeana W. Hillier, Robert S. Fulton, Claudio Casola, Mariano Rocchi, Benjamin Soibam, Suzette D. Tardif, Derek E. Wildman, Evgenia V. Kriventseva, Kim C. Worley, Baoli Zhu, Jennifer F. Hughes, Robert Hubley, Geoffrey Okwuonu, Jennifer Hume, Lora Lewis, Ricardo C.H. del Rosario, Devin P. Locke, Lora Perales, David Rio Deiros, David J. Witherspoon, Yi Han, Brian J. Raney, David Rodríguez, Stephen Fitzgerald, Jireh Santibanez, Albert J. Vilella, R. Gerald Fowler, Qing Wang, Belen Lorente-Galdos, Ramatu Ayiesha Gabisi, Víctor Quesada, Weimin Xiao, Nicoletta Archidiacono, Emre Karakor, Helen Skaletsky, R. Alan Harris, Evgeny M. Zdobnov, Richard A. Gibbs, Wesley C. Warren, Patrick Minx, Preethi H. Gunaratne, Rita A. Wright, Doriana Misceo, Jinchuan Xing, Evan E. Eichler, Lynn B. Jorde, Carolin Kosiol, Rick K. Wilson, Sandra L. Lee, University of St Andrews. School of Biology, University of St Andrews. Centre for Biological Diversity, National Human Genome Research Institute (US), National Institutes of Health (US), National Science Foundation (US), Howard Hughes Medical Institute, Louisiana State University, Cullen Foundation, European Research Council, Ministerio de Ciencia e Innovación (España), Instituto Nacional de Bioinformática (España), Gerlach, Daniel, Kriventseva, Evgenia, and Zdobnov, Evgeny

Subjects

endocrine system, animal structures, Evolució molecular, Evolution, QH301 Biology, animal diseases, Molecular Sequence Data, QH426 Genetics, Polymorphism, Single Nucleotide, Genome, Article, Evolution, Molecular, QH301, Phylogenetics, biology.animal, Genetics, Animals, ddc:576.5, Primate, Amino Acid Sequence, Polymorphism, QH426, Phylogeny, New World monkey, biology, Reproduction, Polimorfisme genètic, Callithrix/genetics, Molecular, Marmoset, Callithrix, Single Nucleotide, Sequence Analysis, DNA, biology.organism_classification, Reproduction/genetics, DNA/methods, body regions, MicroRNAs/genetics, MicroRNAs, Evolutionary biology, Female, Sequence Analysis

Abstract

The Marmoset Genome Sequencing and Analysis Consortium.-- Worley, Kim C. et al., We report the whole-genome sequence of the common marmoset (Callithrix jacchus). The 2.26-Gb genome of a female marmoset was assembled using Sanger read data (6×) and a whole-genome shotgun strategy. A first analysis has permitted comparison with the genomes of apes and Old World monkeys and the identification of specific features that might contribute to the unique biology of this diminutive primate, including genetic changes that may influence body size, frequent twinning and chimerism. We observed positive selection in growth hormone/insulin-like growth factor genes (growth pathways), respiratory complex I genes (metabolic pathways), and genes encoding immunobiological factors and proteases (reproductive and immunity pathways). In addition, both protein-coding and microRNA genes related to reproduction exhibited evidence of rapid sequence evolution. This genome sequence for a New World monkey enables increased power for comparative analyses among available primate genomes and facilitates biomedical research application. © 2014 Nature America, Inc., The marmoset genome project was funded by the National Human Genome Research Institute (NHGRI), including from grants U54 HG003273 (R.A. Gibbs) and U54 HG003079 (R.K.W.), with additional support from the US National Institutes of Health (NIH), including from grants R01 DK077639 (S.D.T.), R01 GM59290 (L.B.J. and M.A.B.), HG002385 (E.E.E.) and P51-OD011133 (Southwest NPRC), and support from the National Science Foundation (NSF BCS-0751508 to D.E.W.) and the VEGA grant agency: 1/0719/14 (T.V.) and 1/1085/12 (B.B.). C.C.F. and M.C.R. were supported in part by a Howard Hughes Medical Institute grant to Louisiana State University through the Undergraduate Biological Sciences Education program. J.X. was supported by NHGRI grant K99 HG005846. P.H.G. was supported by the Cullen Foundation. T.M.-B. was supported by European Research Council Starting Grant (260372) and MICINN (Spain) grant BFU2011-28549. B.L.-G. was supported by the Spanish National Institute of Bioinformatics (see URLs).

Published

2014

15. LINEs and SINEs of primate evolution

Author

Mark A. Batzer, Miriam K. Konkel, and Jerilyn A. Walker

Subjects

Long interspersed nuclear element, Short Interspersed Element, Genome evolution, Evolution of primates, Homo sapiens, Evolutionary biology, Anthropology, Retrotransposon, General Medicine, Genome project, Biology, Genome, Article

Abstract

The primate order is a monophyletic group thought to have diverged from the Euarchonta more than 65 million years ago (mya).1 Recent paleontological and molecular evolution studies place the last common ancestor of primates even earlier (≥ 85 mya).2 More than 300 extant primate species are recognized today,3,4 clearly emphasizing their diversity and success. Our understanding of the evolution of primates and the composition of their genomes has been revolutionized within the last decade through the increasing availability and analyses of sequenced genomes. However, several aspects of primate evolution have yet to be resolved. DNA sequencing of a wider array of primate species now underway will provide an opportunity to investigate and expand upon these questions in great detail. One of the most surprising findings of the human (Homo sapiens) genome project was the high content of repetitive sequences, in particular of mobile DNA.5 This finding has been replicated in all available and analyzed primate draft genome sequences analyzed to date.5–7 In fact, transposable elements (TEs) contribute about 50% of the genome size of humans,5 chimpanzees (Pan troglodytes),6 and rhesus macaques (Macacca mulatta).7 The proportion of TEs among the overall genome content is likely even higher due to the decay of older mobile elements beyond recognition, rearrangements of genomes over the course of evolution, and the challenge of sequencing and assembling repeat-rich regions of the genome.8,9 Retrotransposons (see glossary) – in particular L1, long interspersed element 1 (LINE1), and Alu, a short interspersed element (SINE) – are prominent in primate genomes, and have played a major role in genome evolution and architecture. The evolution and success of the primate-specific LINE and SINE subfamilies (L1 and Alu in particular), their application in phylogenetic studies, and their impact on the architecture of primate genomes will be the focus of this review. In addition, we will briefly cover the emergence and impact of SVA (SINE-R/VNTR/Alu) – a composite retrotransposon of relatively recent origin – and of other SINEs that are not common to all primates.

Published

2010

16. Internal priming: An opportunistic pathway for L1 and Alu retrotransposition in hominins

Author

Mark A. Batzer, Erin M. Conlin, Shurjo K. Sen, and Deepa Srikanta

Subjects

DNA Repair, Retroelements, DNA repair, Alu element, Priming (immunology), Retrotransposon, Computational biology, Biology, Models, Biological, Genome, Article, Alu Elements, Genetics, Animals, Humans, DNA Breaks, Double-Stranded, DNA Primers, Genome, Human, Computational Biology, Hominidae, General Medicine, Human genetics, Reverse transcriptase, Mutagenesis, Insertional, Long Interspersed Nucleotide Elements, Human genome, Signal Transduction

Abstract

Retrotransposons, specifically Alu and L1 elements, have been especially successful in their expansion throughout primate genomes. While most of these elements integrate through an endonuclease-mediated process termed target primed reverse transcription, a minority integrate using alternative methods. Here we present evidence for one such mechanism, (which we term internal priming) and demonstrate that loci integrating through this mechanism are qualitatively different from “classical” insertions. Previous examples of this mechanism are limited to cell culture assays, which show that reverse transcription can initiate upstream of the 3′ polyA tail during retrotransposon integration. To detect whether this mechanism occurs in vivo as well as in cell culture, we have analyzed the human genome for internal priming events using recently integrated L1 and Alu elements. Our examination of the human genome resulted in the recovery of twenty events involving internal priming insertions, which are structurally distinct from both classical TPRT-mediated insertions and non-classical insertions. We suggest two possible mechanisms by which these internal priming loci are created and provide evidence supporting a role in staggered DNA double-strand break repair. Also, we demonstrate that the internal priming process is associated with inter-chromosomal duplications and the insertion of filler DNA.

Published

2009

17. Reading between the LINEs to see into the past

Author

David A. Ray, Mark A. Batzer, and Roy N. Platt

Subjects

Mammals, Genetics, Transposable element, Genetic diversity, Genome evolution, Genome, Retroelements, Biodiversity, Interspersed Repetitive Sequences, Biology, Article, humanities, Evolution, Molecular, Long Interspersed Nucleotide Elements, Evolutionary biology, Phylogenetics, Molecular evolution, DNA Transposable Elements, Animals, Humans, human activities, Phylogeny

Abstract

Transposable elements are an important source of genome diversity and have crucial role in genome evolution.. A recent study by Zhao et al. describes novel patterns of transposable element (TE) diversification in the genome of the extinct mammoth, Mammuthus primigenius. Analysis of Mammuthus has provided a unique genome landscape, a pivotal species for understanding TEs and genome evolution, and hints at the diversity we verge on discovering by expanding our taxonomic sampling among genomes. Strategies based on the work. might also revolutionize investigations of the interface between TE dynamics and genome diversity.

Published

2009

18. Mobile elements create structural variation: Analysis of a complete human genome

Author

Mark A. Batzer, Qiong Zhou, Jinchuan Xing, Abdel Halim Salem, Kyudong Han, Chad D. Huff, Yuhua Zhang, Shurjo K. Sen, Lynn B. Jorde, Samuel Levy, and Ewen F. Kirkness

Subjects

Genetics, Letter, Genome, Human, Molecular Sequence Data, Computational Biology, Genetic Variation, Alu element, Retrotransposon, Sequence Analysis, DNA, Computational biology, Biology, Polymorphism, Single Nucleotide, Genome, DNA sequencing, Structural variation, Alu Elements, DNA Transposable Elements, Humans, Human genome, Mobile genetic elements, Gene Deletion, Genetics (clinical), Reference genome

Abstract

Structural variants (SVs) are common in the human genome. Because approximately half of the human genome consists of repetitive, transposable DNA sequences, it is plausible that these elements play an important role in generating SVs in humans. Sequencing of the diploid genome of one individual human (HuRef) affords us the opportunity to assess, for the first time, the impact of mobile elements on SVs in an individual in a thorough and unbiased fashion. In this study, we systematically evaluated more than 8000 SVs to identify mobile element-associated SVs as small as 100 bp and specific to the HuRef genome. Combining computational and experimental analyses, we identified and validated 706 mobile element insertion events (including Alu, L1, SVA elements, and nonclassical insertions), which added more than 305 kb of new DNA sequence to the HuRef genome compared with the Human Genome Project (HGP) reference sequence (hg18). We also identified 140 mobile element-associated deletions, which removed ∼126 kb of sequence from the HuRef genome. Overall, ∼10% of the HuRef-specific indels larger than 100 bp are caused by mobile element-associated events. More than one-third of the insertion/deletion events occurred in genic regions, and new Alu insertions occurred in exons of three human genes. Based on the number of insertions and the estimated time to the most recent common ancestor of HuRef and the HGP reference genome, we estimated the Alu, L1, and SVA retrotransposition rates to be one in 21 births, 212 births, and 916 births, respectively. This study presents the first comprehensive analysis of mobile element-related structural variants in the complete DNA sequence of an individual and demonstrates that mobile elements play an important role in generating inter-individual structural variation.

Published

2009

19. Identification of repeat structure in large genomes using repeat probability clouds

Author

David D. Pollock, Todd A. Castoe, Mark A. Batzer, Dale J. Hedges, and Wanjun Gu

Subjects

Time Factors, Nearest neighbor search, Pseudogene, Oligonucleotides, Biophysics, Sequence alignment, Computational biology, Biology, Sensitivity and Specificity, Biochemistry, Genome, Article, Alu Elements, Sliding window protocol, Humans, Gene family, False Positive Reactions, Molecular Biology, Probability, Repetitive Sequences, Nucleic Acid, Genetics, Genome, Human, Cell Biology, Identification (information), Chromosomes, Human, Pair 1, Human genome, Algorithms

Abstract

The identification of repeat structure in eukaryotic genomes can be time-consuming and difficult because of the large amount of information ( approximately 3 x 10(9) bp) that needs to be processed and compared. We introduce a new approach based on exact word counts to evaluate, de novo, the repeat structure present within large eukaryotic genomes. This approach avoids sequence alignment and similarity search, two of the most time-consuming components of traditional methods for repeat identification. Algorithms were implemented to efficiently calculate exact counts for any length oligonucleotide in large genomes. Based on these oligonucleotide counts, oligonucleotide excess probability clouds, or "P-clouds," were constructed. P-clouds are composed of clusters of related oligonucleotides that occur, as a group, more often than expected by chance. After construction, P-clouds were mapped back onto the genome, and regions of high P-cloud density were identified as repetitive regions based on a sliding window approach. This efficient method is capable of analyzing the repeat content of the entire human genome on a single desktop computer in less than half a day, at least 10-fold faster than current approaches. The predicted repetitive regions strongly overlap with known repeat elements as well as other repetitive regions such as gene families, pseudogenes, and segmental duplicons. This method should be extremely useful as a tool for use in de novo identification of repeat structure in large newly sequenced genomes.

Published

2008

20. Evolutionary dynamics of transposable elements in the short-tailed opossum Monodelphis domestica

Author

Wanjun Gu, Mark A. Batzer, Jerzy Jurka, Oleksiy Kohany, David D. Pollock, Matthew Wakefield, and Andrew J. Gentles

Subjects

Genetics, Whole genome sequencing, Letter, Genome, food and beverages, Retrotransposon, Exaptation, Biology, biology.organism_classification, Monodelphis, Monodelphis domestica, Time, Evolution, Molecular, Mice, Phylogenetics, DNA Transposable Elements, Animals, Humans, Human genome, Base Pairing, Phylogeny, Genetics (clinical)

Abstract

The complete genome sequence of a marsupial, the short-tailed opossum Monodelphis domestica (Mikkelsen et al. 2007), provides a unique opportunity to investigate the evolutionary forces that have shaped mammalian genomes. Monodelphis is the first sequenced metatherian species, and as such, provides an important target against which to compare eutherians (placental mammals) and increase the depth of our understanding of the evolution of the Amniota. Currently, it is estimated that metatherians and eutherians diverged from a common ancestor ∼170–190 million years ago (Mya). Further back, the divergence from avian and reptile taxa occurred around ∼300 My. Thus, the positioning of Monodelphis between avians and eutherians makes it invaluable for evolutionary comparisons. Furthermore, Monodelphis is the only metatherian that is commonly maintained as a laboratory stock (VandeBerg and Robinson 1997). Insights from the unusually large (∼3.6 Gb) genome sequence should provide numerous new hypotheses for experimental investigations, and hopefully illuminate previously unresolved questions. In addition to the human genome, we now have complete sequences available for mouse, rat, dog, and chicken, among others (Waterston et al. 2002; Gibbs et al. 2004; International Chicken Genome Sequencing Consortium 2005; Lindblad-Toh et al. 2005). Initial draft sequences for the cow, wallaby, and cat are also forthcoming. One of the major features of most genomes is the presence of transposable elements (TEs). Although at times dismissed as “parasitic” residents of genomes, it is increasingly recognized that TEs have been major players in shaping genomic landscapes (Brosius and Gould 1992; Kidwell and Lisch 2001; Deininger and Batzer 2002; Brosius 2003; Deininger et al. 2003). In addition to their effects due to insertional mutagenesis, high-copy number TEs provide a substrate for illegitimate homologous recombinations, causing rearrangements that may be deleterious or advantageous (Sen et al. 2006). Deletion of genomic segments by recombination between TEs is associated with numerous human diseases, while the complementary duplication of regions provides new material for evolutionary innovation (for example, see Deininger and Batzer 1999; Edelmann et al. 1999; Bailey et al. 2002; Babcock et al. 2003). Furthermore, TEs have been exapted by their host genomes into useful roles. In some cases, such as recruitment of a Mariner transposase into the primate gene SETMAR ∼40–58 Mya (Cordaux et al. 2006), exaptation makes direct use of the coding potential of autonomous elements (TEs that can catalyze their own transposition or retrotransposition). But an increasingly recognized phenomenon is the co-opting of nonautonomous elements as functional noncoding elements (Bejerano et al. 2006; Kamal et al. 2006). This fulfills the vision originally espoused by McClintock, Davidson, and Britten, that TEs, and repetitive DNA in general, may be critical “control elements” in modern genomes (McClintock 1961; Davidson and Britten 1979). Here we investigate the impact of TEs on the Monodelphis genome, and their possible role in mammalian evolution. We primarily focus on aspects of TEs in Monodelphis that highlight differences from other species. In addition, we discuss some commonalities such as the exaptation of ancient repeats that have been highly conserved across a remarkable phylogenetic range.

Published

2007

21. Genome of the marsupial Monodelphis domestica reveals innovation in non-coding sequences

Author

Frances Letendre, Vasilia Magnisalis, Helen Vassiliev, Rebecca Reyes, Maura Costello, St Christophe Acer, Pen MacDonald, Geneva Young, Katherine Thompson, Iain MacCallum, Tarjei S. Mikkelsen, Andy Vo, Eva Markiewicz, Yeshi Lokyitsang, Sharon Stavropoulos, Rachel Mittelman, Xiaohui Xie, Diallo Ferguson, James Cuff, Terence P. Speed, Catherine Stone, Tanya Mihova, Janine E. Deakin, Aaron M. Berlin, David A. Ray, David D. Pollock, Ben Kanga, Kunsang Gyaltsen, Scott Anderson, Gary Gearin, Nabil Hafez, Lisa Chuda, Marco A. Marra, David B. Jaffe, Leonid Boguslavskiy, Asha Kamat, Jonathan Butler, Alicia Franke, Lynne Aftuck, Sheridon Channer, Rosie Levine, Kerstin Lindblad-Toh, Birhane Hagos, Imane Bourzgui, Monika D. Huard, Tamrat Negash, Jamal Abdulkadir, Tsering Wangchuk, Georgius De Haan, Sheila Fisher, Justin Abreu, Abderrahim Farina, Kebede Maru, M. Erii Husby, Peter Kisner, Kunsang Dorjee, Jacob L. Glass, Tashi Lokyitsang, Nyima Norbu, Jennifer Baldwin, Christina R. Gearin, Otero L. Oyono, Atanas Mihalev, Yama Thoulutsang, Katie D'Aco, Choe Norbu, Christopher Strader, Edda Koina, Allen Alexander, Barry O'Neill, William Brockman, Wanjun Gu, Richard Elong, Keenan Ross, Shailendra Yadav, Alan Dupes, Seva Kashin, James Meldrim, Dmitry Khazanovich, Passang Dorje, Adal Abebe, April Cook, Matthew Breen, Randy L. Jirtle, Shangtao Liu, Jean L. Chang, Patrick Cahill, Claire M. Wade, Chee Whye Chin, Dennis C. Friedrich, Tina Goode, Cecil Rise, Robert D. Nicholls, Peter Rogov, Adam Brown, Oana Mihai, Sujaa Raghuraman, Adam Wilson, Marcia Lara, Chelsea D. Foley, Susan Faro, Sampath Settipalli, Thu Nguyen, Matthew Wakefield, Xiaohong Liu, Anna Montmayeur, Jerzy Jurka, Ngawang Sherpa, Riza M. Daza, Evan Mauceli, Senait Tesfaye, Sharleen Grewal, Susan McDonough, Leo Goodstadt, Manuel Garber, John M. Greally, Valentine Mlenga, Manfred Grabherr, Charles Matthews, Andrew Zimmer, Teena Mehta, Harindra Arachi, Mark A. Batzer, Rakela Lubonja, Margaret Priest, Diana Shih, Joseph Graham, Panayiotis V. Benos, Lance S. Davidow, Alex Lipovsky, Stephen M. J. Searle, Andreas Heger, Timothy A. Hore, Patrick Cooke, Leonidas Mulrain, Tsering Wangdi, Jennifer A. Marshall Graves, Sante Gnerre, Michelle L. Baker, Jacqueline E. Schein, Michael Weiand, Jessica Spaulding, Charlotte Henson, Jane Wilkinson, Terry Shea, Shannon E. Duke, William McCusker, Kerri Topham, Jerome Naylor, Lu Shi, Fritz Pierre, Claude Bonnet, Shaun Mahony, Michele Clamp, Katherine Belov, John L. VandeBerg, Nicole Stange-Thomann, Annie Lui, Radhika Das, Pema Phunkhang, Andrew J. Gentles, Elizabeth P. Ryan, Erica Anderson, Jill Falk, Bronwen Aken, Robert Nicol, Ted Sharpe, Sahal Osman, Missole Doricent, Michael Kleber, Jeannie T. Lee, Paul D. Waters, Melissa Fazzari, Jinlei Liu, Loryn Gadbois, Lisa Zembek, Daniel Bessette, Pasang Bachantsang, Adam Navidi, Caleb Webber, Tashi Bayul, Brikti Abera, Mayumi Oda, Gavin A. Huttley, Jennifer L. Hall, Chris P. Ponting, Michael Kamal, Kimberly Dooley, Mieke Citroen, Tsamla Tsamla, Ira Topping, Eric S. Lander, Edward Grandbois, Christopher Patti, Louis Meneus, Tracey Honan, Zuly E. Parra, Nga Nguyen, Todd Sparrow, Dawa Thoulutsang, Leanne Hughes, Yama Cheshatsang, Qing Yu, Niall J. Lennon, Nathaniel Novod, Christina Demaso, Anthony T. Papenfuss, Paul B. Samollow, Toby Bloom, Andrew Hollinger, Boris Boukhgalter, Talene Thomson, Zac Zwirko, Georgia Giannoukos, Michael C. Zody, Danni Zhong, Jason Blye, Stuart DeGray, Marc Azer, Robert D. Miller, Amr Abdouelleil, Brian Hurhula, Filip Rege, John Stalker, Andrew Barry, Pablo Alvarez, Norbu Dhargay, Krista Lance, Chris T. Amemiya, Jerilyn A. Walker, Jennifer R. Weidman, Peter An, Erin E. Dooley, William Lee, and Alville Collymore

Subjects

Genetics, Base Composition, Genome evolution, Genome, Multidisciplinary, Genomics, Opossums, Biology, biology.organism_classification, Polymorphism, Single Nucleotide, Synteny, Monodelphis domestica, Evolution, Molecular, X Chromosome Inactivation, Opossum, Molecular evolution, Protein Biosynthesis, DNA Transposable Elements, Animals, Humans, Gene family, Gene conversion, Conserved Sequence

Abstract

We report a high-quality draft of the genome sequence of the grey, short-tailed opossum (Monodelphis domestica). As the first metatherian ('marsupial') species to be sequenced, the opossum provides a unique perspective on the organization and evolution of mammalian genomes. Distinctive features of the opossum chromosomes provide support for recent theories about genome evolution and function, including a strong influence of biased gene conversion on nucleotide sequence composition, and a relationship between chromosomal characteristics and X chromosome inactivation. Comparison of opossum and eutherian genomes also reveals a sharp difference in evolutionary innovation between protein-coding and non-coding functional elements. True innovation in protein-coding genes seems to be relatively rare, with lineage-specific differences being largely due to diversification and rapid turnover in gene families involved in environmental interactions. In contrast, about 20% of eutherian conserved non-coding elements (CNEs) are recent inventions that postdate the divergence of Eutheria and Metatheria. A substantial proportion of these eutherian-specific CNEs arose from sequence inserted by transposable elements, pointing to transposons as a major creative force in the evolution of mammalian gene regulation.

Published

2007

22. Evolutionary and Biomedical Insights from the Rhesus Macaque Genome

Author

Carolin Kosiol, Belinda Giardine, Janet A. Hopkins, Andrew G. Clark, Ryan D. Hernandez, Peng Wang, Peter D. Stenson, Yu-Hui Rogers, Aaron L. Halpern, Andrew D. Kern, Webb Miller, Kymberlie H. Pepin, Melissa J. Hubisz, Kimberly D. Delehaunty, Robert E. Palermo, Matthew W. Hahn, Erica Sodergren, Brian P. Walenz, Scott M. Smith, Sandra L. Lee, Xiang Qin, Yucheng Feng, Ewen F. Kirkness, Vandita Joshi, Xiaoqiu Huang, Amanda F. Svatek, Fan Yang, Young Ho Kim, Laura Clarke, John E. Karro, Courtney Sherell White, Jessica Kolb, David Glenn Smith, Clay Davis, Jian Ma, Shobha Patil, Todd Wylie, Arian F.A. Smit, Shalini N. Jhangiani, Michael G. Katze, Edward V. Ball, Jennifer Godfrey, Heather A. Lawson, Brian J. Raney, Michael Holder, Ross C. Hardison, Christian J. Buhay, Zhangwan Li, Alicia Hawes, Eric J. Vallender, David A. Wheeler, James C. Wallace, Galt P. Barber, Jinchuan Xing, Yufeng Shen, Kayla E. Smith, Marvin Diep Dao, Jeffrey Rogers, Evan E. Eichler, Cynthia Pfannkoch, Jireh Santibanez, Kateryna D. Makova, Kashif Hirani, Robert M. Kuhn, Yanru Ren, David Neil Cooper, David Haussler, Carlos Bustamante, Adam Siepel, Mimi N. Chandrabose, Xiaoming Liu, George M. Weinstock, Teresa Utterback, Jarret Glasscock, Tomas Vinar, R. Alan Harris, Anis Karimpour-Fard, San Juana Ruiz, Lucinda Fulton, Asif T. Chinwalla, Aniko Sabo, Xinwei She, Charles Addo-Quaye, David L. Nelson, Lora Lewis, Hui Ke, Eli Venter, Donna M. Muzny, Alison Marklein, Bruce T. Lahn, Grace Pai, Brian W. Schneider, Shannon Dugan-Rocha, Henry Xing-Zhi Song, Jeremiah D. Degenhardt, Kyudong Han, Huaiyang Jiang, Stephanie M. Moore, Ian Schenck, Dinh Ngoc Ngo, Michael J. Cox, Heidie A. Paul, Ann S. Zwieg, Kim C. Worley, Craig Pohl, Rui Chen, Robert L. Strausberg, Ling-Ling Pu, Donna Karolchik, Jonathan R. Pollack, Geoffrey Okwuonu, Jennifer Hume, Elaine R. Mardis, David N. Messina, W. James Kent, William E. O'Brien, Fan Hsu, Andrew R. Jackson, Huyen Dinh, Hui Wang, LaDeana W. Hillier, Richard A. Gibbs, Alexandra Denby, Wesley C. Warren, Brygg Ullmer, Laura J. Dumas, Yih-shin Liu, Tony Attaway, Richard K. Wilson, Patrick Minx, James M. Sikela, Lan Zhang, Sandra Hines, Steven J. M. Jones, Amit Indap, Ze Cheng, Karin A. Remington, Stephanie Bell, Jungnam Lee, Kelly E. Bernard, Sang-Gook Han, Mariano Rocchi, Judith Hernandez, Betsy Ferguson, Hildegard Kehrer-Sawatzki, Ziad Khan, Aleksandar Milosavljevic, Joanne O. Nelson, Jeffery P. Demuth, Richard Burhans, David A. Parker, Lynne V. Nazareth, Roger E. Bumgarner, Marco A. Marra, Robert Baertsch, Andrew Cree, Paul Havlak, J. Craig Venter, Kay Prüfer, Rasmus Nielsen, Ewan Birney, Miriam K. Konkel, Mark A. Batzer, Arthur M. Lesk, Jacqueline E. Schein, Granger G. Sutton, Yan Ding, Yue Liu, Andy Peng Xiang, Miklós Csürös, Selina Vattathil, John W. Wallis, R. Gerald Fowler, Shiaw-Pyng Yang, Ramatu Ayiesha Gabisi, and Toni T. Garner

Subjects

Male, Biomedical Research, Pan troglodytes, Macaque, Human accelerated regions, Genome, Evolution, Molecular, Species Specificity, Gene Duplication, biology.animal, Animals, Humans, Primate, Gene Rearrangement, Genetics, Whole genome sequencing, Multidisciplinary, biology, Genetic Diseases, Inborn, Genetic Variation, Sequence Analysis, DNA, Gene rearrangement, biology.organism_classification, Macaca mulatta, Rhesus macaque, Homo sapiens, Evolutionary biology, Multigene Family, Mutation, Female

Abstract

The rhesus macaque ( Macaca mulatta ) is an abundant primate species that diverged from the ancestors of Homo sapiens about 25 million years ago. Because they are genetically and physiologically similar to humans, rhesus monkeys are the most widely used nonhuman primate in basic and applied biomedical research. We determined the genome sequence of an Indian-origin Macaca mulatta female and compared the data with chimpanzees and humans to reveal the structure of ancestral primate genomes and to identify evidence for positive selection and lineage-specific expansions and contractions of gene families. A comparison of sequences from individual animals was used to investigate their underlying genetic diversity. The complete description of the macaque genome blueprint enhances the utility of this animal model for biomedical research and improves our understanding of the basic biology of the species.

Published

2007

23. An integrated map of structural variation in 2,504 human genomes

Author

Oliver Stegle, Ken Chen, Scott E. Devine, Mark Gerstein, Charles Lee, Eliza Cerveira, Klaudia Walter, Mallory Romanovitch, Evan E. Eichler, Nicholas F. Parrish, Shane A. McCarthy, Miriam K. Konkel, Steven A. McCarroll, Jing Zhang, Robert Sebra, Min Wang, Eric-Wubbo Lameijer, Gabor T. Marth, Seva Kashin, Xiangqun Zheng-Bradley, Tobias Rausch, Kai Ye, Chengsheng Zhang, Andrey A. Shabalin, Francesco Paolo Casale, Andreas Schlattl, Mark Chaisson, Jerilyn A. Walker, Jieming Chen, Fuli Yu, Christopher E. Mason, Richard A. Gibbs, Li Ding, Bradley J. Nelson, Paul Flicek, Adam Auton, Matthew Pendleton, Eugene J. Gardner, Andrew Quitadamo, Zechen Chong, John Huddleston, Markus His Yang Fritz, Ankit Malhotra, Taejeong Bae, Laura Clarke, Yan Zhang, Fereydoun Hormozdiari, Danny Antaki, Goo Jun, Amina Noor, Gargi Dayama, Sascha Meiers, Elif Dal, Adrian M. Stütz, Peter S. Chines, Eric E. Schadt, Yu Kong, Thomas Zichner, Benjamin Raeder, Andreas Untergasser, Jan O. Korbel, Donna M. Muzny, Xinghua Shi, Peter H. Sudmant, Madhusudan Gujral, Alexej Abyzov, Hugo Y. K. Lam, Maika Malig, Mark A. Batzer, Robert E. Handsaker, Ryan E. Mills, Xian Fan, Xinmeng Jasmine Mu, Ali Bashir, Jeffrey M. Kidd, S. Emery, Can Alkan, Fatma Kahveci, Wanding Zhou, Androniki Menelaou, Erik Garrison, and Jonathan Sebat

Subjects

Unclassified drug, Gene loss, Intron, Genome-wide association study, Homozygosity, Gene inactivation, 0302 clinical medicine, Human genetics, Mutation Rate, Haplotype, Priority journal, Sequence Deletion, Genetics, 0303 health sciences, education.field_of_study, Multidisciplinary, Homozygote, Gene linkage disequilibrium, Genomics, Physical Chromosome Mapping, Polymerase chain reaction, Untranslated region, Human, Quantitative trait locus, Genotype, Clinical article, Genetics, Medical, Population, Genomic Structural Variation, Molecular Sequence Data, Quantitative Trait Loci, DNA sequence, Computational biology, Biology, Polymorphism, Single Nucleotide, Structural variation, 03 medical and health sciences, Disease association, Humans, Genetic Predisposition to Disease, Amino Acid Sequence, education, Gene mapping, 030304 developmental biology, Demography, Human genome, Genome, Human, Serine proteinase inhibitor, Genetic Variation, SPINK14 protein, Sequence Analysis, DNA, Single nucleotide polymorphism, Gene structure, Genetics, Population, Haplotypes, Expression quantitative trait loci, Genetic association, Genetic variability, Glycoprotein, 030217 neurology & neurosurgery, Dual specificity phosphatase, Genome-Wide Association Study

Abstract

Structural variants are implicated in numerous diseases and make up the majority of varying nucleotides among human genomes. Here we describe an integrated set of eight structural variant classes comprising both balanced and unbalanced variants, which we constructed using short-read DNA sequencing data and statistically phased onto haplotype blocks in 26 human populations. Analysing this set, we identify numerous gene-intersecting structural variants exhibiting population stratification and describe naturally occurring homozygous gene knockouts that suggest the dispensability of a variety of human genes. We demonstrate that structural variants are enriched on haplotypes identified by genome-wide association studies and exhibit enrichment for expression quantitative trait loci. Additionally, we uncover appreciable levels of structural variant complexity at different scales, including genic loci subject to clusters of repeated rearrangement and complex structural variants with multiple breakpoints likely to have formed through individual mutational events. Our catalogue will enhance future studies into structural variant demography, functional impact and disease association.

Published

2015

24. Human Genomic Deletions Mediated by Recombination between Alu Elements

Author

Hui Wang, Richard Cordaux, Matthew D. Dyer, Shurjo K. Sen, Jianxin Wang, Kyudong Han, Pauline A. Callinan, Mark A. Batzer, Ping Liang, and Jungnam Lee

Subjects

Transposable element, Lineage (genetic), Pan troglodytes, Molecular Sequence Data, Alu element, Genomics, Biology, Polymerase Chain Reaction, Genome, Article, Chimpanzee genome project, Macular Degeneration, 03 medical and health sciences, 0302 clinical medicine, Genetics, Animals, Humans, Genetics(clinical), Gene, Genetics (clinical), Repetitive Sequences, Nucleic Acid, 030304 developmental biology, Recombination, Genetic, 0303 health sciences, Genome, Human, 030220 oncology & carcinogenesis, Human genome, Monte Carlo Method, Gene Deletion

Abstract

Recombination between Alu elements results in genomic deletions associated with many human genetic disorders. Here, we compare the reference human and chimpanzee genomes to determine the magnitude of this recombination process in the human lineage since the human-chimpanzee divergence approximately 6 million years ago. Combining computational data mining and wet-bench experimental verification, we identified 492 human-specific deletions (for a total of approximately 400 kb) attributable to this process, a significant component of the insertion/deletion spectrum of the human genome. The majority of the deletions (295 of 492) coincide with known or predicted genes (including 3 that deleted functional exons, as compared with orthologous chimpanzee genes), which implicates this process in creating a substantial portion of the genomic differences between humans and chimpanzees. Overall, we found that Alu recombination-mediated genomic deletion has had a much higher impact than was inferred from previously identified isolated events and that it continues to contribute to the dynamic nature of the human genome.

Published

2006

25. Extensive individual variation in L1 retrotransposition capability contributes to human genetic diversity

Author

Richard Cordaux, Maria del Carmen Seleme, Haig H. Kazazian, Laurel A Bastone, Melissa R. Vetter, and Mark A. Batzer

Subjects

Genetics, education.field_of_study, Polymorphism, Genetic, Multidisciplinary, Models, Genetic, Retroelements, Population, Genetic Variation, Population genetics, Locus (genetics), Retrotransposon, Human genetic variation, Biological Sciences, Biology, Evolution, Molecular, Genetics, Population, Genetic variation, Humans, Human genome, Allele, education, Alleles

Abstract

Despite being scarce in the human genome, active L1 retrotransposons continue to play a significant role in its evolution. Because of their recent expansion, many L1s are not fixed in humans, and, when present, their mobilization potential can vary among individuals. Previously, we showed that the great majority of retrotransposition events in humans are caused by highly active, or hot, L1s. Here, in four populations of diverse geographic origins (160 haploid genomes), we investigated the degree of sequence polymorphism of three hot L1s and the extent of individual variation in mobilization capability of their allelic variants. For each locus, we found one previously uncharacterized allele in every three to five genomes, including some with nonsense and insertion/deletion mutations. Single or multiple nucleotide substitutions drastically affected the retrotransposition efficiency of some alleles. One-third of elements were no longer hot, and these so-called cool alleles substantially increased the range of individual susceptibility to retrotransposition events. Adding the activity of the three elements in each individual resulted in a surprising degree of variation in mobilization capability, ranging from 0% to 390% of a reference L1. These data suggest that individual variation in retrotransposition potential makes an important contribution to human genetic diversity.

Published

2006

26. Whole genome computational comparative genomics: A fruitful approach for ascertaining Alu insertion polymorphisms

Author

Mark A. Batzer, M. Katherine Gonder, Ping Liang, Lei Song, David A. Ray, Sarah A. Tishkoff, Jianxin Wang, and Sami Azrak

Subjects

endocrine system, Molecular Sequence Data, Population, Alu element, Retrotransposon, Computational biology, Biology, Genome, Article, Alu Elements, hemic and lymphatic diseases, Genetics, Animals, Humans, Amino Acid Sequence, Gene conversion, education, Gene, Comparative genomics, education.field_of_study, Polymorphism, Genetic, Sequence Homology, Amino Acid, Genome, Human, Computational Biology, Genomics, General Medicine, Mutagenesis, Insertional, Genetics, Population, Chromosomes, Human, Pair 6, Human genome

Abstract

Alu elements are the most active and predominant type of short interspersed elements (SINEs) in the human genome. Recently inserted polymorphic (for presence/absence) Alu elements contribute to genome diversity among different human populations, and they are useful genetic markers for population genetic studies. The objective of this study is to identify polymorphic Alu insertions through an in silico comparative genomics approach and to analyze their distribution pattern throughout the human genome. By computationally comparing the public and Celera sequence assemblies of the human genome, we identified a total of 800 polymorphic Alu elements. We used polymerase chain reaction-based assays to screen a randomly selected set of 16 of these 800 Alu insertion polymorphisms using a human diversity panel to demonstrate the efficiency of our approach. Based on sequence analysis of the 800 Alu polymorphisms, we report three new Alu subfamilies, Ya3, Ya4b, and Yb11, with Yb11 being the smallest known Alu subfamily. Analysis of retrotransposition activity revealed Yb11, Ya8, Ya5, Yb9, and Yb8 as the most active Alu subfamilies and the maintenance of a very low level of retrotransposition activity or recent gene conversion events involving S subfamilies. The 800 polymorphic Alu insertions are characterized by the presence of target site duplications (TSDs) and longer than average polyA-tail length. Their pre-integration sites largely follow an extended “NT-AARA” motif. Among chromosomes, the density of Alu insertion polymorphisms is positively correlated with the Alu-site availability and is inversely correlated with the densities of older Alu elements and genes.

Published

2006

27. dbRIP: A highly integrated database of retrotransposon insertion polymorphisms in humans

Author

Sami Azrak, Lei Song, Deepak Grover, Jianxin Wang, Ping Liang, and Mark A. Batzer

Subjects

Genetics, Mutation, Polymorphism, Genetic, Retroelements, Genome, Human, Retrotransposon, Genome project, Computational biology, Genome browser, Biology, medicine.disease_cause, Genome, Article, Human genetics, Mutagenesis, Insertional, Databases, Genetic, medicine, Humans, Human genome, Insertion sequence, Genetics (clinical)

Abstract

Retrotransposons constitute over 40% of the human genome and play important roles in the evolution of the genome. Since certain types of retrotransposons, particularly members of the Alu, L1, and SVA families, are still active, their recent and ongoing propagation generates a unique and important class of human genomic diversity/polymorphism (for the presence and absence of an insertion) with some elements known to cause genetic diseases. So far, over 2,300, 500, and 80 Alu, L1, and SVA insertions, respectively, have been reported to be polymorphic and many more are yet to be discovered. We present here the Database of Retrotransposon Insertion Polymorphisms (dbRIP; http://falcon.roswellpark.org:9090), a highly integrated and interactive database of human retrotransposon insertion polymorphisms (RIPs). dbRIP currently contains a nonredundant list of 1,625, 407, and 63 polymorphic Alu, L1, and SVA elements, respectively, or a total of 2,095 RIPs. In dbRIP, we deploy the utilities and annotated data of the genome browser developed at the University of California at Santa Cruz (UCSC) for user-friendly queries and integrative browsing of RIPs along with all other genome annotation information. Users can query the database by a variety of means and have access to the detailed information related to a RIP, including detailed insertion sequences and genotype data. dbRIP represents the first database providing comprehensive, integrative, and interactive compilation of RIP data, and it will be a useful resource for researchers working in the area of human genetics.

Published

2006

28. Human Population Genetic Structure and Diversity Inferred from Polymorphic L1(LINE-1) and Alu Insertions

Author

Mark A. Batzer, Justin D. Fowlkes, Christopher T. Ostler, David J. Witherspoon, Stéphane Boissinot, Lynn B. Jorde, Bridget A. Anders, Stephen Wooding, Elizabeth E. Marchani, Anthony V. Furano, Alan R. Rogers, David A. Ray, and W. S. Watkins

Subjects

Genetics, Conservation genetics, education.field_of_study, Population, Biology, Genome, Phylogenetics, Evolutionary biology, Genetic variation, Genetic structure, Human genome, education, Allele frequency, Genetics (clinical)

Abstract

Background/Aims: The L1 retrotransposable element family is the most successful self-replicating genomic parasite of the human genome. L1 elements drive replication of Alu elements, and both have had far-reaching impacts on the human genome. We use L1 and Alu insertion polymorphisms to analyze human population structure. Methods: We genotyped 75 recent, polymorphic L1 insertions in 317 individuals from 21 populations in sub-Saharan Africa, East Asia, Europe and the Indian subcontinent. This is the first sample of L1 loci large enough to support detailed population genetic inference. We analyzed these data in parallel with a set of 100 polymorphic Alu insertion loci previously genotyped in the same individuals. Results and Conclusion: The data sets yield congruent results that support the recent African origin model of human ancestry. A genetic clustering algorithm detects clusters of individuals corresponding to continental regions. The number of loci sampled is critical: with fewer than 50 typical loci, structure cannot be reliably discerned in these populations. The inclusion of geographically intermediate populations (from India) reduces the distinctness of clustering. Our results indicate that human genetic variation is neither perfectly correlated with geographic distance (purely clinal) nor independent of distance (purely clustered), but a combination of both: stepped clinal.

Published

2006

29. Chompy: An infestation of MITE-like repetitive elements in the crocodilian genome

Author

Mark A. Batzer, Scott W. Herke, David A. Ray, Dale J. Hedges, Justin D. Fowlkes, Lindsey M. Goodwin, Daniel K. LaVie, Llewellyn D. Densmore, and Erin W Barnes

Subjects

Comparative genomics, Genetics, Transposable element, Alligators and Crocodiles, biology, Alligator, Interspersed repeat, Gene Dosage, Crocodylus moreletii, General Medicine, biology.organism_classification, Genome, Interspersed Repetitive Sequences, Multigene Family, biology.animal, DNA Transposable Elements, Animals, American alligator, Genome size

Abstract

Interspersed repeats are a major component of most eukaryotic genomes and have an impact on genome size and stability, but the repetitive element landscape of crocodilian genomes has not yet been fully investigated. In this report, we provide the first detailed characterization of an interspersed repeat element in any crocodilian genome. Chompy is a putative miniature inverted-repeat transposable element (MITE) family initially recovered from the genome of Alligator mississippiensis (American alligator) but also present in the genomes of Crocodylus moreletii (Morelet’s crocodile) and Gavialis gangeticus (Indian gharial). The element has all of the hallmarks of MITEs including terminal inverted repeats, possible target site duplications, and a tendency to form secondary structures. We estimate the copy number in the alligator genome to be ¨46,000 copies. As a result of their size and unique properties, Chompy elements may provide a useful source of genomic variation for crocodilian comparative genomics. D 2005 Elsevier B.V. All rights reserved.

Published

2005

30. Worldwide Genetic Variation at the 3′-UTR Region of theLDLRGene: Possible Influence of Natural Selection

Author

Prescott L. Deininger, Nelson J. R. Fagundes, Francisco M. Salzano, Sandro L. Bonatto, and Mark A. Batzer

Subjects

Genetics, Untranslated region, Genetic diversity, Natural selection, Haplotype, Genetic variation, Alu element, Locus (genetics), Biology, Balancing selection, Genetics (clinical)

Abstract

Summary The low density lipoprotein receptor gene (LDLR) contains many Alu insertions, and is especially Alu-rich at its 3 � -untranslated region (3 � -UTR). Previous studies suggested that the LDLR 3 � -UTR could regulate gene expression by the stabilization of its mRNA. Given the faster Alu evolutionary rate, and wondering about its consequences in a possibly regulatory locus, we have studied ∼ 800 bp of 222 chromosomes from individuals of African, Asian, Caucasian and Amerind ancestry, to better understand the evolution of the worldwide genetic diversity at this locus. Twenty-one polymorphic sites, distributed in 15 haplotypes, were found. High genetic diversity was observed, concentrated in one Alu insertion (Alu U), which also shows a fast evolutionary rate. Genetic diversity is similar in all populations except Amerinds, suggesting a bottleneck during the peopling of the American continent. Three haplotype clusters (A, B, C) are distinguished, cluster A being the most recently formed (∼ 500,000 years ago). No clear geographic structure emerges from the haplotype network, the global Fst (0.079) being lower than the average for the human genome. When ancestral population growth is taken into account, neutrality statistics are higher than expected, possibly suggesting the action of balancing selection worldwide.

Published

2005

31. Under the genomic radar: The Stealth model of Alu amplification

Author

Mark A. Batzer, Kyudong Han, Dale J. Hedges, Richard Cordaux, Randall K. Garber, Hui Wang, and Jinchuan Xing

Subjects

Primates, Lineage (genetic), Molecular Sequence Data, Oligonucleotides, Alu element, Biology, Genome, Evolution, Molecular, Species Specificity, Alu Elements, Phylogenetics, Genetics, Animals, Humans, Letters, Gene, Phylogeny, Genetics (clinical), DNA Primers, Electrophoresis, Agar Gel, Human mitochondrial molecular clock, Base Sequence, Models, Genetic, Genome, Human, Computational Biology, myr, Sequence Analysis, DNA, Human genome

Abstract

Alu elements are the most successful SINEs (Short INterspersed Elements) in primate genomes and have reached more than 1,000,000 copies in the human genome. The amplification of most Alu elements is thought to occur through a limited number of hyperactive “master” genes that produce a high number of copies during long evolutionary periods of time. However, the existence of long-lived, low-activity Alu lineages in the human genome suggests a more complex propagation mechanism. Using both computational and wet-bench approaches, we reconstructed the evolutionary history of the AluYb lineage, one of the most active Alu lineages in the human genome. We show that the major AluYb lineage expansion in humans is a species-specific event, as nonhuman primates possess only a handful of AluYb elements. However, the oldest existing AluYb element resided in an orthologous position in all hominoid primate genomes examined, demonstrating that the AluYb lineage originated 18–25 million years ago. Thus, the history of the AluYb lineage is characterized by ∼20 million years of retrotranspositional quiescence preceding a major expansion in the human genome within the past few million years. We suggest that the evolutionary success of the Alu family may be driven at least in part by “stealth-driver” elements that maintain low retrotranspositional activity over extended periods of time and occasionally produce short-lived hyperactive copies responsible for the formation and remarkable expansion of Alu elements within the genome.

Published

2005

32. Alu Retrotransposition-mediated Deletion

Author

Randall K. Garber, Scott W. Herke, Jianxin Wang, Ping Liang, Mark A. Batzer, and Pauline A. Callinan

Subjects

Primates, Genome instability, Retroelements, Molecular Sequence Data, Alu element, Retrotransposon, Genomics, Biology, Genome, Genomic Instability, Alu Elements, Structural Biology, Gene Duplication, Gene duplication, Animals, Humans, Molecular Biology, Sequence Deletion, Genetics, Polymorphism, Genetic, Base Sequence, Models, Genetic, Reverse transcriptase, genomic DNA, Chromosome Deletion

Abstract

Alu repeats contribute to genomic instability in primates via insertional and recombinational mutagenesis. Here, we report an analysis of Alu element-induced genomic instability through a novel mechanism termed retrotransposition-mediated deletion, and assess its impact on the integrity of primate genomes. For human and chimpanzee genomes, we find evidence of 33 retrotransposition-mediated deletion events that have eliminated approximately 9000 nucleotides of genomic DNA. Our data suggest that, during the course of primate evolution, Alu retrotransposition may have contributed to over 3000 deletion events, eliminating approximately 900 kb of DNA in the process. Potential mechanisms for the creation of Alu retrotransposition-mediated deletions include L1 endonuclease-dependent retrotransposition, L1 endonuclease-independent retrotransposition, internal priming on DNA breaks, and promiscuous target primed reverse transcription. A comprehensive analysis of the collateral effects by Alu mobilization on all primate genomes will require sequenced genomes from representatives of the entire order.

Published

2005

33. Multiplex polymerase chain reaction for simultaneous quantitation of human nuclear, mitochondrial, and male Y-chromosome DNA: application in human identification

Author

Sudhir K. Sinha, Meredith E. Laborde, Benjamin P. Perodeau, Jerilyn A. Walker, Nadica Stoilova, Mark A. Batzer, Jaiprakash G. Shewale, Kate E. Landry, and Dale J. Hedges

Subjects

Male, Mitochondrial DNA, Biophysics, Genomics, Biology, Y chromosome, DNA, Mitochondrial, Polymerase Chain Reaction, Biochemistry, chemistry.chemical_compound, Multiplex polymerase chain reaction, Humans, Multiplex, Molecular Biology, Quantitation Range, Cell Nucleus, Chromosomes, Human, X, Chromosomes, Human, Y, Hybridization probe, DNA, Cell Biology, DNA Fingerprinting, Molecular biology, chemistry, Female, DNA Probes

Abstract

Human forensic casework requires sensitive quantitation of human nuclear (nDNA), mitochondrial (mtDNA), and male Y-chromosome DNA from complex biomaterials. Although many such systems are commercially available, no system is capable of simultaneously quantifying all three targets in a single reaction. Most available methods either are not multiplex compatible or lack human specificity. Here, we report the development of a comprehensive set of human-specific, target-specific multiplex polymerase chain reaction (PCR) assays for DNA quantitation. Using TaqMan-MGB probes, our duplex qPCR for nDNA/mtDNA had a linear quantitation range of 100 ng to 1 pg, and our triplex qPCR assay for nDNA/mtDNA/male Y DNA had a linear range of 100-0.1 ng. Human specificity was demonstrated by the accurate detection of 0.05 and 5% human DNA from a complex source of starting templates. Target specificity was confirmed by the lack of cross-amplification among targets. A high-throughput alternative for human gender determination was also developed by multiplexing the male Y primer/probe set with an X-chromosome-based system. Background cross-amplification with DNA templates derived from 14 other species was negligible aside from the male Y assay which produced spurious amplifications from other nonhuman primate templates. Mainstream application of these assays will undoubtedly benefit forensic genomics.

Published

2005

34. From the margins of the genome: mobile elements shape primate evolution

Author

Dale J. Hedges and Mark A. Batzer

Subjects

Primates, Repetitive Sequences, Long Interspersed Nucleotide Elements, Zoology, Biology, Genome, General Biochemistry, Genetics and Molecular Biology, Evolution, Molecular, Open Reading Frames, Phylogenetics, Animals, Humans, Short Interspersed Nucleotide Elements, Germ-Line Mutation, Phylogeny, Repetitive Sequences, Nucleic Acid, Models, Genetic, Genome, Human, Exons, Biological evolution, DNA Methylation, Biological Evolution, Primate evolution, Alternative Splicing, Retroviridae, Evolutionary biology, CpG Islands, Mobile genetic elements

Abstract

Summary Asisthecasewithmammalsingeneral,primategenomes are inundated with repetitive sequence. Although much of this repetitive content consists of ‘‘molecular fossils’’ inherited from early mammalian ancestors, a significant portion of this material comprises active mobile element lineages. Despite indications that these elements played a major role in shaping the architecture of the genome, there remain many unanswered questions surrounding the nature of the host-element relationship. Here we review advances in our understanding of the host– mobileelementdynamicanditsoverallimpactonprimate evolution. BioEssays 27:785–794, 2005.

Published

2005

35. The Alu Yc1 subfamily: sorting the wheat from the chaff

Author

Randall K. Garber, Mark A. Batzer, Dale J. Hedges, Scott W. Herke, and N.W. Hazard

Subjects

Genetics, endocrine system, Subfamily, Alu element, Biology, law.invention, law, hemic and lymphatic diseases, Human population genetics, Consensus sequence, Classification methods, Human genome, Molecular Biology, Insertion polymorphism, Genetics (clinical), Polymerase chain reaction

Abstract

Members of the Alu Yc1 subfamily are distinguished from the older Alu Y subfamily by a signature G→A substitution at base 148 of their 281-bp consensus sequence. Members of the much older and larger Alu Y subfamily could have by chance accumulated this signature G→A substitution and be misclassified as belonging to the Alu Yc1 subfamily. Using a Mahanalobis classification method, it was estimated that the “authentic” Alu Yc1 subfamily consists of approximately 262 members in the human genome. PCR amplification and further analysis was successfully completed on 225 of the Yc1 Alu family members. One hundred and seventy-seven Yc1 Alu elements were determined to be monomorphic (fixed for presence) in a panel of diverse human genomes. Forty-eight of the Yc1 Alu elements were polymorphic for insertion presence/absence in diverse human genomes. The insertion polymorphism rate of 21% in the human genome is similar to rates reported previously for other “young” Alu subfamilies. The polymorphic Yc1 Alu elements will be useful genetic loci for the study of human population genetics.

Published

2005

36. Low Levels of Nucleotide Diversity in Crocodylus moreletii and Evidence of Hybridization with C. acutus

Author

Mark A. Batzer, Thomas R. Rainwater, David A. Ray, Peter J. Stafford, Adam G. Finger, Scott T. McMurry, Brady Barr, Jennifer A. Dever, Llewellyn D. Densmore, Jenna McKnight, and Steven G. Platt

Subjects

mtDNA control region, education.field_of_study, biology, Ecology, Population, Crocodylus acutus, Crocodylus moreletii, Zoology, Crocodile, biology.organism_classification, Crocodylus, Nucleotide diversity, biology.animal, Genetics, education, Ecology, Evolution, Behavior and Systematics, Isolation by distance

Abstract

Examinations of both population genetic structure and the processes that lead to such structure in crocodilians have been initiated in several species in response to a call by the IUCN Crocodile Specialist Group. A recent study used microsatellite markers to characterize Morelet’s crocodile (Crocodylus moreletii) populations in north-central Belize and presented evidence for isolation by distance. To further investigate this hypothesis, we sequenced a portion of the mitochondrial control region for representative animals after including samples from additional locales in Belize, Guatemala and Mexico. While there is limited evidence of subdivision involving other locales, we found that most of the differentiation among populations of C. moreletii can be attributed to animals collected from a single locale in Belize, Banana Bank Lagoon. Furthermore, mitochondrial DNA sequence analysis showed that animals from this and certain other locales display a haplotype characteristic of the American crocodile, C. acutus, rather than C. moreletii .W e interpret this as evidence of hybridization between the two species and comment on how these new data have influenced our interpretation of previous findings. We also find very low levels of nucleotide diversity in C. moreletii haplotypes and provide evidence for a low rate of substitution in the crocodilian mitochondrial control region. Finally, the conservation implications of these findings are discussed.

Published

2004

37. Haplotypes in the Dystrophin DNA Segment Point to a Mosaic Origin of Modern Human Diversity

Author

Isabel Arrieta, Ewa Ziętkiewicz, Vania Yotova, David Modiano, Damian Labuda, David E. C. Cole, Tina Wambach, Jean-Paul Moisan, Dominik Gehl, Peter Hechtman, Roman Michalski, Feige Kaplan, and Mark A. Batzer

Subjects

Lineage (genetic), Molecular Sequence Data, Human genetic variation, Biology, Dystrophin, Evolution, Molecular, 03 medical and health sciences, Phylogenetics, Genetic variation, Genetics, Chromosomes, Human, Humans, Genetics(clinical), Allele, Alleles, Phylogeny, Genetics (clinical), 030304 developmental biology, Recombination, Genetic, 0303 health sciences, Polymorphism, Genetic, Base Sequence, Geography, Mosaicism, 030305 genetics & heredity, Haplotype, Genetic Variation, Articles, Haplotypes, Africa, Upper Paleolithic, Microsatellite, Microsatellite Repeats

Abstract

Although Africa has played a central role in human evolutionary history, certain studies have suggested that not all contemporary human genetic diversity is of recent African origin. We investigated 35 simple polymorphic sites and one T(n) microsatellite in an 8-kb segment of the dystrophin gene. We found 86 haplotypes in 1,343 chromosomes from around the world. Although a classical out-of-Africa topology was observed in trees based on the variant frequencies, the tree of haplotype sequences reveals three lineages accounting for present-day diversity. The proportion of new recombinants and the diversity of the T(n) microsatellite were used to estimate the age of haplotype lineages and the time of colonization events. The lineage that underwent the great expansion originated in Africa prior to the Upper Paleolithic (27,000-56,000 years ago). A second group, of structurally distinct haplotypes that occupy a central position on the tree, has never left Africa. The third lineage is represented by the haplotype that lies closest to the root, is virtually absent in Africa, and appears older than the recent out-of-Africa expansion. We propose that this lineage could have left Africa before the expansion (as early as 160,000 years ago) and admixed, outside of Africa, with the expanding lineage. Contemporary human diversity, although dominated by the recently expanded African lineage, thus represents a mosaic of different contributions.

Published

2003

38. Alu elements and hominid phylogenetics

Author

David J. Witherspoon, David A. Ray, Abdel Halim Salem, Mark A. Batzer, Lynn B. Jorde, Randall K. Garber, Dale J. Hedges, Jinchuan Xing, Pauline A. Callinan, and Jeremy S. Myers

Subjects

Primates, Hominidae, Lineage (evolution), Molecular Sequence Data, Alu element, Evolution, Molecular, Monophyly, Alu Elements, Phylogenetics, Sequence Homology, Nucleic Acid, Consensus Sequence, Animals, Humans, Phylogeny, Genetics, Multidisciplinary, Hominini, Base Sequence, biology, Phylogenetic tree, Biological Sciences, biology.organism_classification, Oligodeoxyribonucleotides, Mobile genetic elements, Sequence Alignment

Abstract

Alu elements have inserted in primate genomes throughout the evolution of the order. One particular Alu lineage (Ye) began amplifying relatively early in hominid evolution and continued propagating at a low level as many of its members are found in a variety of hominid genomes. This study represents the first conclusive application of short interspersed elements, which are considered nearly homoplasy-free, to elucidate the phylogeny of hominids. Phylogenetic analysis of Alu Ye5 elements and elements from several other subfamilies reveals high levels of support for monophyly of Hominidae, tribe Hominini and subtribe Hominina. Here we present the strongest evidence reported to date for a sister relationship between humans and chimpanzees while clearly distinguishing the chimpanzee and human lineages.

Published

2003

39. Following the LINEs: An Analysis of Primate Genomic Variation at Human-Specific LINE-1 Insertion Sites

Author

W. Scott Watkins, Huei Jin Ho, Bethaney J. Vincent, Mark A. Batzer, Lynn B. Jorde, Gail Kilroy, Jeremy S. Myers, and Jerilyn A. Walker

Subjects

Primates, Pan troglodytes, Sequence analysis, Molecular Sequence Data, Population, Gene Conversion, Alu element, Biology, Polymerase Chain Reaction, Genome, Cell Line, Evolution, Molecular, Genetics, Animals, Humans, Gene conversion, education, Molecular Biology, Phylogeny, Ecology, Evolution, Behavior and Systematics, education.field_of_study, Gorilla gorilla, Polymorphism, Genetic, Phylogenetic tree, Genetic Variation, Sequence Analysis, DNA, Pan paniscus, Macaca mulatta, Long interspersed nuclear element, Long Interspersed Nucleotide Elements, Macaca nemestrina, Mobile genetic elements

Abstract

The L1 Ta subfamily of long interspersed elements (LINEs) consists exclusively of human-specific L1 elements. Polymerase chain reaction-based screening in nonhuman primate genomes of the orthologous sites for 249 human L1 Ta elements resulted in the recovery of various types of sequence variants for approximately 12% of these loci. Sequence analysis was employed to capture the nature of the observed variation and to determine the levels of gene conversion and insertion site homoplasy associated with LINE elements. Half of the orthologous loci differed from the predicted sizes due to localized sequence variants that occurred as a result of common mutational processes in ancestral sequences, often including regions containing simple sequence repeats. Additional sequence variation included genomic deletions that occurred upon L1 insertion, as well as successive mobile element insertions that accumulated within a single locus over evolutionary time. Parallel independent mobile element insertions at orthologous loci in distinct species may introduce homoplasy into retroelement-based phylogenetic and population genetic data. We estimate the overall frequency of parallel independent insertion events at L1 insertion sites in seven different primate species to be very low (0.52%). In addition, no cases of insertion site homoplasy involved the integration of a second L1 element at any of the loci, but rather largely involved secondary insertions of Alu elements. No independent mobile element insertion events were found at orthologous loci in the human and chimpanzee genomes. Therefore, L1 insertion polymorphisms appear to be essentially homoplasy free characters well suited for the study of population genetics and phylogenetic relationships within closely related species.

Published

2003

40. Human DNA quantitation using Alu element-based polymerase chain reaction

Author

Mark A. Batzer, Sudhir K. Sinha, Gail Kilroy, Jerilyn A. Walker, Jaiprakash G. Shewale, and Jinchuan Xing

Subjects

Sequence analysis, Molecular Sequence Data, Biophysics, Alu element, Biology, Polymerase Chain Reaction, Sensitivity and Specificity, Biochemistry, Genome, Cell Line, law.invention, chemistry.chemical_compound, Alu Elements, law, Sequence Homology, Nucleic Acid, Animals, Humans, Hardware_ARITHMETICANDLOGICSTRUCTURES, Molecular Biology, Polymerase chain reaction, Polymorphism, Genetic, Base Sequence, Genome, Human, DNA, Sequence Analysis, DNA, Cell Biology, Forensic Medicine, Molecular biology, Nuclear DNA, chemistry, Nucleic acid, Human genome, HeLa Cells

Abstract

Human forensic casework requires sensitive quantitation of human nuclear DNA from complex sources. Widely used commercially available systems detect both nonhuman and human primate DNA, often require special equipment, and have a detection limit of approximately 0.1 ng. Multicopy Alu elements include recently integrated subfamilies that are present in the human genome but are largely absent from nonhuman primates. Here, we present two Alu element-based alternative methods for the rapid identification and quantitation of human DNA, inter-Alu PCR and intra-Alu PCR. Using SYBR green-based detection, the effective minimum threshold level for human DNA quantitation was 0.01 ng using inter-Alu- and 0.001 ng using intra-Alu-based PCR. Background cross-amplification with nonhuman DNA templates was detected at low levels using inter-Alu-based PCR, but was negligible using intra-Alu-based PCR. These Alu-based methods have several advantages over currently available systems. First, the assays are PCR based and no additional unique equipment is required. Second, the high copy number of subfamily-specific Alu repeats in the human genome makes these assays human specific within a very sensitive linear range. The introduction of these assays to forensic laboratories will undoubtedly increase the sensitivity and specificity of human DNA detection and quantitation from complex sources.

Published

2003

41. LINE-1 preTa Elements in the Human Genome

Author

Jeremy S. Myers, Lynn B. Jorde, Anthony C. Otieno, Mark A. Batzer, W. Scott Watkins, and Abdel Halim Salem

Subjects

Primates, Genetics, Polymorphism, Genetic, Subfamily, Base Sequence, Genome, Human, Retrotransposon, Sequence Analysis, DNA, Biology, Polymerase Chain Reaction, Genome, Cell Line, Evolution, Molecular, Long interspersed nuclear element, Complete sequence, Long Interspersed Nucleotide Elements, Structural Biology, Human population genetics, Animals, Humans, Human genome, Mobile genetic elements, Sequence Alignment, Molecular Biology

Abstract

The preTa subfamily of long interspersed elements (LINEs) is characterized by a three base-pair “ACG” sequence in the 3′ untranslated region, contains approximately 400 members in the human genome, and has low level of nucleotide divergence with an estimated average age of 2.34 million years old suggesting that expansion of the L1 preTa subfamily occurred just after the divergence of humans and African apes. We have identified 362 preTa L1 elements from the draft human genomic sequence, investigated the genomic characteristics of preTa L1 insertions, and screened individual elements across diverse human populations and various non-human primate species using polymerase chain reaction (PCR) assays to determine the phylogenetic origin and levels of human genomic diversity associated with the L1 elements. All of the preTa L1 elements analyzed by PCR were absent from the orthologous positions in non-human primate genomes with 33 (14%) of the L1 elements being polymorphic with respect to insertion presence or absence in the human genome. The newly identified L1 insertion polymorphisms will prove useful as identical by descent genetic markers for the study of human population genetics. We provide evidence that preTa L1 elements show an integration site preference for genomic regions with low GC content. Computational analysis of the preTa L1 elements revealed that 29% of the elements amenable to complete sequence analysis have apparently escaped 5′ truncation and are essentially full-length (approximately 6 kb). In all, 29 have two intact open reading frames and may be capable of retrotransposition.

Published

2003

42. Mammalian Retroelements

Author

Prescott L. Deininger and Mark A. Batzer

Subjects

Evolution, Molecular, Mammals, Genome, Retroelements, Genome, Human, Genetics, Animals, Humans, Genetics (clinical)

Abstract

The eukaryotic genome has undergone a series of epidemics of amplification of mobile elements that have resulted in most eukaryotic genomes containing much more of this ‘junk’ DNA than actual coding DNA. The majority of these elements utilize an RNA intermediate and are termed retroelements. Most of these retroelements appear to amplify in evolutionary waves that insert in the genome and then gradually diverge. In humans, almost half of the genome is recognizably derived from retroelements, with the two elements that are currently actively amplifying, L1 and Alu, making up about 25% of the genome and contributing extensively to disease. The mechanisms of this amplification process are beginning to be understood, although there are still more questions than answers. Insertion of new retroelements may directly damage the genome, and the presence of multiple copies of these elements throughout the genome has longer-term influences on recombination events in the genome and more subtle influences on gene expression.

Published

2002

43. DNA repair mediated by endonuclease-independent LINE-1 retrotransposition

Author

Mark A. Batzer, Jeremy S. Myers, Nicolas Gilbert, Tammy A. Morrish, Thomas D. Stamato, John V. Moran, Guillermo E. Taccioli, and Bethaney J. Vincent

Subjects

DNA Repair, Retroelements, DNA repair, Molecular Sequence Data, Retrotransposon, CHO Cells, Biology, Polymerase Chain Reaction, Molecular biology, Reverse transcriptase, Long interspersed nuclear element, genomic DNA, chemistry.chemical_compound, Long Interspersed Nucleotide Elements, chemistry, Cricetinae, Complementary DNA, Genetics, Animals, Humans, Primer (molecular biology), DNA

Abstract

Long interspersed elements (LINE-1s) are abundant retrotransposons in mammalian genomes that probably retrotranspose by target site-primed reverse transcription (TPRT). During TPRT, the LINE-1 endonuclease cleaves genomic DNA, freeing a 3' hydroxyl that serves as a primer for reverse transcription of LINE-1 RNA by LINE-1 reverse transcriptase. The nascent LINE-1 cDNA joins to genomic DNA, generating LINE-1 structural hallmarks such as frequent 5' truncations, a 3' poly(A)+ tail and variable-length target site duplications (TSDs). Here we describe a pathway for LINE-1 retrotransposition in Chinese hamster ovary (CHO) cells that acts independently of endonuclease but is dependent upon reverse transcriptase. We show that endonuclease-independent LINE-1 retrotransposition occurs at near-wildtype levels in two mutant cell lines that are deficient in nonhomologous end-joining (NHEJ). Analysis of the pre- and post-integration sites revealed that endonuclease-independent retrotransposition results in unusual structures because the LINE-1s integrate at atypical target sequences, are truncated predominantly at their 3' ends and lack TSDs. Moreover, two of nine endonuclease-independent retrotranspositions contained cDNA fragments at their 3' ends that are probably derived from the reverse transcription of endogenous mRNA. Thus, our results suggest that LINE-1s can integrate into DNA lesions, resulting in retrotransposon-mediated DNA repair in mammalian cells.

Published

2002

44. Alu insertions versus blood group plus protein genetic variability in four Amerindian populations

Author

A. M. Hurtado, Luiza T. Tsuneto, Maria Luiza Petzl-Erler, Mark A. Batzer, Sidia M. Callegari-Jacques, T. A. Weimer, Mara H. Hutz, Sandro L. Bonatto, K. Hill, Francisco M. Salzano, J. Battilana, and Loreta B. Freitas

Subjects

Aging, Genotype, Physiology, Epidemiology, Population, Alu element, Biology, chemistry.chemical_compound, Alu Elements, Genetic variation, Genetics, Humans, Genetic variability, Allele, education, Alleles, education.field_of_study, Polymorphism, Genetic, Indians, South American, Public Health, Environmental and Occupational Health, Genetic Variation, DNA extraction, Genetics, Population, chemistry, Paraguay, Brazil, DNA

Abstract

Do the population relationships obtained using DNA or blood group plus protein markers remain the same or do they reveal different patterns, indicating that the factors which influence genetic variation at these two levels of analysis are diverse? Can these markers shed light on the biological classification of the Aché, a Paraguayan tribe which only recently established more permanent contacts with non-Indians?To consider these questions we typed 193 individuals from four Amerindian tribes in relation to 12 Alu polymorphisms (five of them never studied in these populations), while 22 blood group plus protein systems were studied among the Aché. These data were then integrated with those previously available (blood groups plus proteins) for the three other populations. DNA extraction and amplification, as well as the other laboratory procedures, were performed using standard methods currently in use in our laboratory. The genetic relationships were obtained using the D(A) distance, and the trees were constructed by the neighbour-joining method, both developed by M. Nei and collaborators. Reliability of the trees was tested by bootstrap replications. Other population variability values were also determined using Nei's methods.Alu polymorphism was observed in all populations and for most of the loci; in the seven systems from which we could compare our results with those of other Amerindian groups agreement was satisfactory. Unusual findings on the blood group plus protein systems of the Aché were a very low (5%) HP*1 frequency and the presence of the C(W) phenotype in the Rh blood group. The intertribal patterns of relationship and other aspects of their variation were remarkably congruent in the two sets (Alu; blood group plus protein) of systems.The answer to the first question posed above is affirmative. However, the problem of whether the Aché derived from a Gê group that preceded the Guarani colonization of Paraguay, or are just a differentiated Guarani group, could not be answered with the genetic information available; the second hypothesis seems more likely at present, but the point to be emphasized is the striking genetic distinctiveness of the Aché as compared to other Amerindians.

Published

2002

45. Alu Insertion Polymorphisms for the Study of Human Genomic Diversity

Author

Abdel Halim Salem, Astrid M. Roy-Engel, Randall K. Garber, Son V. Nguyen, Prescott L. Deininger, Erika Vogel, Marion L. Carroll, and Mark A. Batzer

Subjects

endocrine system, Subfamily, Genotype, Molecular Sequence Data, Alu element, Biology, Genome, Alu Elements, Phylogenetics, Sequence Homology, Nucleic Acid, hemic and lymphatic diseases, Genetic variation, Genetics, Humans, Hardware_ARITHMETICANDLOGICSTRUCTURES, Hardware_REGISTER-TRANSFER-LEVELIMPLEMENTATION, Phylogeny, DNA Primers, Polymorphism, Genetic, Base Sequence, Models, Genetic, Genome, Human, Genetic Variation, DNA, ComputingMethodologies_PATTERNRECOGNITION, TheoryofComputation_MATHEMATICALLOGICANDFORMALLANGUAGES, Databases as Topic, Genetic marker, GenBank, Human genome, Hardware_CONTROLSTRUCTURESANDMICROPROGRAMMING, Software, Research Article

Abstract

Genomic database mining has been a very useful aid in the identification and retrieval of recently integrated Alu elements from the human genome. We analyzed Alu elements retrieved from the GenBank database and identified two new Alu subfamilies, Alu Yb9 and Alu Yc2, and further characterized Yc1 subfamily members. Some members of each of the three subfamilies have inserted in the human genome so recently that about a one-third of the analyzed elements are polymorphic for the presence/absence of the Alu repeat in diverse human populations. These newly identified Alu insertion polymorphisms will serve as identical-by-descent genetic markers for the study of human evolution and forensics. Three previously classified Alu Y elements linked with disease belong to the Yc1 subfamily, supporting the retroposition potential of this subfamily and demonstrating that the Alu Y subfamily currently has a very low amplification rate in the human genome.

Published

2001

46. Large-scale analysis of the Alu Ya5 and Yb8 subfamilies and their contribution to human genomic diversity

Author

Lynn B. Jorde, Prescott L. Deininger, Mimi C. Sammarco, Abdel Halim Salem, Jürgen Henke, Astrid M. Roy-Engel, Bethaney J. Vincent, W. Scott Watkins, Son V. Nguyen, Lan Nguyen, Wojciech Makalowski, Zahid Ahmad, Mark A. Batzer, Erika Vogel, Marion L. Carroll, and Jeremy S. Myers

Subjects

Primates, Genotype, Gene Conversion, Gene Dosage, Alu element, Biology, Polymerase Chain Reaction, Gene dosage, Genome, DNA sequencing, Cell Line, Evolution, Molecular, Alu Elements, Structural Biology, Phylogenetics, Animals, Humans, Gene conversion, Molecular Biology, Phylogeny, DNA Primers, Genetics, Polymorphism, Genetic, Base Sequence, Genome, Human, Racial Groups, Computational Biology, Genetic Variation, Mutagenesis, Insertional, Databases as Topic, Evolutionary biology, GenBank, Mutation, CpG Islands, Human genome

Abstract

We have utilized computational biology to screen GenBank for the presence of recently integrated Ya5 and Yb8 Alu family members. Our analysis identified 2640 Ya5 Alu family members and 1852 Yb8 Alu family members from the draft sequence of the human genome. We selected a set of 475 of these elements for detailed analyses. Analysis of the DNA sequences from the individual Alu elements revealed a low level of random mutations within both subfamilies consistent with the recent origin of these elements within the human genome. Polymerase chain reaction assays were used to determine the phylogenetic distribution and human genomic variation associated with each Alu repeat. Over 99 % of the Ya5 and Yb8 Alu family members were restricted to the human genome and absent from orthologous positions within the genomes of several non-human primates, confirming the recent origin of these Alu subfamilies in the human genome. Approximately 1 % of the analyzed Ya5 and Yb8 Alu family members had integrated into previously undefined repeated regions of the human genome. Analysis of mosaic Yb8 elements suggests gene conversion played an important role in generating sequence diversity among these elements. Of the 475 evaluated elements, a total of 106 of the Ya5 and Yb8 Alu family members were polymorphic for insertion presence/absence within the genomes of a diverse array of human populations. The newly identified Alu insertion polymorphisms will be useful tools for the study of human genomic diversity.

Published

2001

47. Evidence for alternate splicing within the mRNA transcript encoding the DNA damage response kinase ATR

Author

Aaron W. Adamson, Ray Braquet, Mark A. Batzer, Son V. Nguyen, Colin Collins, Zhining Den, Jennifer L. Mannino, Wan-Ju Kim, Meredith Wernick, and Kevin D. Brown

Subjects

Male, DNA, Complementary, DNA Repair, Transcription, Genetic, Molecular Sequence Data, Cell Cycle Proteins, Ataxia Telangiectasia Mutated Proteins, Protein Serine-Threonine Kinases, Biology, Cell Line, Jurkat Cells, Exon, Complementary DNA, Tumor Cells, Cultured, Genetics, Humans, Tissue Distribution, RNA, Messenger, Gene, DNA-PKcs, Expressed sequence tag, Base Sequence, Alternative splicing, DNA, Exons, Sequence Analysis, DNA, General Medicine, Molecular biology, Introns, Alternative Splicing, genomic DNA, RNA splicing, Female, HeLa Cells

Abstract

Proper cellular response to genotoxic insult often requires the activity of one or more members of a family of high-molecular weight protein kinases referred to as phosphatidylinositol-3 kinase (PIK)-like proteins. While catalytic activity is an indispensable part of PIK-like protein function, little is currently known about factors that control their activity and/or functions. This deficiency stems, in large part, from our lack of knowledge concerning functionally significant subdomains within the large non-catalytic domain of these proteins. We have determined that the transcript encoding the PIK-like protein ATR undergoes alternate splicing within the region of the mRNA encoding its non-catalytic domain. This conclusion is based on the sequencing of a human expressed sequence tag clone encoding a portion of the ATR cDNA, and is supported by the results of reverse transcriptase-polymerase chain reaction (RT-PCR) assays conducted on total and polyA+ RNA, as well as sequencing of cloned RT-PCR products. Cloning and sequencing of a segment of human genomic DNA indicated that this event arises from splicing of a single 192 bp exon within the ATR gene. Analysis of several human tissues indicated that alternate ATR transcripts are differentially expressed, suggesting that this region of the ATR protein may be of functional importance.

Published

2001

48. Genetic Evidence on the Origins of Indian Caste Populations

Author

P. Govinda Reddy, Mark A. Batzer, Toomas Kivisild, J. Mastan Naidu, Richard Villems, Michael F. Hammer, Arani Rasanayagam, Baskara B. Rao, Chris E. Ricker, Marion L. Carroll, W. Scott Watkins, Son V. Nguyen, Surinder S. Papiha, Lynn B. Jorde, Alan J. Redd, Michael J. Bamshad, Mary E. Dixon, and B. V. Ravi Prasad

Subjects

Adult, Male, Mitochondrial DNA, Asia, Letter, Population, India, Locus (genetics), Biology, DNA, Mitochondrial, Haplogroup, Y Chromosome, Genetic variation, Genetics, Humans, education, Phylogeny, Genetics (clinical), education.field_of_study, Polymorphism, Genetic, Haplotype, Caste, Genetic Variation, Europe, Genetics, Population, Haplotypes, Social Class, Evolutionary biology, Genetic structure

Abstract

The origins and affinities of the approximately 1 billion people living on the subcontinent of India have long been contested. This is owing, in part, to the many different waves of immigrants that have influenced the genetic structure of India. In the most recent of these waves, Indo-European-speaking people from West Eurasia entered India from the Northwest and diffused throughout the subcontinent. They purportedly admixed with or displaced indigenous Dravidic-speaking populations. Subsequently they may have established the Hindu caste system and placed themselves primarily in castes of higher rank. To explore the impact of West Eurasians on contemporary Indian caste populations, we compared mtDNA (400 bp of hypervariable region 1 and 14 restriction site polymorphisms) and Y-chromosome (20 biallelic polymorphisms and 5 short tandem repeats) variation in approximately 265 males from eight castes of different rank to approximately 750 Africans, Asians, Europeans, and other Indians. For maternally inherited mtDNA, each caste is most similar to Asians. However, 20%-30% of Indian mtDNA haplotypes belong to West Eurasian haplogroups, and the frequency of these haplotypes is proportional to caste rank, the highest frequency of West Eurasian haplotypes being found in the upper castes. In contrast, for paternally inherited Y-chromosome variation each caste is more similar to Europeans than to Asians. Moreover, the affinity to Europeans is proportionate to caste rank, the upper castes being most similar to Europeans, particularly East Europeans. These findings are consistent with greater West Eurasian male admixture with castes of higher rank. Nevertheless, the mitochondrial genome and the Y chromosome each represents only a single haploid locus and is more susceptible to large stochastic variation, bottlenecks, and selective sweeps. Thus, to increase the power of our analysis, we assayed 40 independent, biparentally inherited autosomal loci (1 LINE-1 and 39 Alu elements) in all of the caste and continental populations (approximately 600 individuals). Analysis of these data demonstrated that the upper castes have a higher affinity to Europeans than to Asians, and the upper castes are significantly more similar to Europeans than are the lower castes. Collectively, all five datasets show a trend toward upper castes being more similar to Europeans, whereas lower castes are more similar to Asians. We conclude that Indian castes are most likely to be of proto-Asian origin with West Eurasian admixture resulting in rank-related and sex-specific differences in the genetic affinities of castes to Asians and Europeans.

Published

2001

49. Sequential Loss of Two Neighboring Exons of the Tropoelastin Gene During Primate Evolution

Author

Carole Struminger, Simona A. Levi-Minzi, Charles D. Boyd, Mark A. Batzer, Angela M. Christiano, Zoltán Szabó, and Mark Stoneking

Subjects

Primates, Time Factors, Molecular Sequence Data, Population, Polymerase Chain Reaction, Evolution, Molecular, Exon, Species Specificity, Tropoelastin, biology.animal, Genetics, Animals, Humans, Primate, Allele, education, Molecular Biology, Gene, Alleles, Ecology, Evolution, Behavior and Systematics, DNA Primers, Sequence Deletion, education.field_of_study, Base Sequence, Sequence Homology, Amino Acid, biology, Genetic Variation, Vertebrate, DNA, Exons, Rats, biology.protein, Cattle, Tandem exon duplication, Papio

Abstract

Previous evidence has demonstrated the absence of exons 34 and 35 within the 3' end of the human tropoelastin (ELN) gene. These exons encode conserved polypeptide domains within tropoelastin and are found in the ELN gene in vertebrate species ranging from chickens to rats to cows. We have analyzed the ELN gene in a variety of primate species to determine whether the absence of exons 34 and 35 in humans either is due to allelic variation within the human population or is a general characteristic of the Primates order. An analysis of the 3' end of the ELN gene in several nonhuman primates and in 546 chromosomes from humans of varying ethnic background demonstrated a sequential loss of exons 34 and 35 during primate evolution. The loss of exon 35 occurred at least 35-45 million years ago, when Catarrhines diverged from Platyrrhines (New World monkeys). Exon 34 loss, in contrast, occurred only about 6-8 million years ago, when Homo separated from the common ancestor shared with chimpanzees and gorillas. Loss of both exons was probably facilitated by Alu-mediated recombination events and possibly conferred a functional evolutionary advantage in elastic tissue.

Published

1999

50. Cloning and characterization of the prostate-specific membrane antigen promoter

Author

Jay K. Kolls, Paul Schwarzenberger, James A. Eastham, Mark A. Batzer, Robert E. Rhoads, Chris Theodossiou, Michael Patrick Collins, David Good, Jay D. Hunt, and Sidney R. Grimes

Subjects

Regulation of gene expression, Expression vector, Cell, Cell Biology, Biology, Biochemistry, Molecular biology, genomic DNA, medicine.anatomical_structure, Transcription (biology), Cell culture, LNCaP, medicine, Molecular Biology, Gene

Abstract

Prostate-specific membrane antigen (PSMA) is a protein that is expressed predominantly in normal prostate epithelial cells and in most adenocarcinomas of the prostate (Cap) and in virtually all Cap metastases. In this article we describe the cloning of a 2-kb human genomic DNA fragment containing the 5' upstream untranslated region of the PSMA gene and present evidence that it provides promoter activity. When the DNA fragment was cloned into transient expression vectors to examine promoter activity, the vectors were functional in promoting expression in several prostate and nonprostate cell lines in transient transfection assays. A 614-bp fragment derived from the 3' end of the 2-kb fragment may represent the minimal PSMA promoter as determined by deletion mutagenesis. The 2-kb fragment compared with the 614-bp fragment provided higher expression levels when using prostate-derived cell lines (DU 145 and LNCaP). The increased transcription using the 2-kb fragment was not as great in non-prostate cell lines. Little or no transcription over basal levels was seen with a 232-bp promoter fragment. When the concentration of dihydrotestosterone was depleted or supplemented in the growth medium, no significant effect was seen on PSMA-promoted transient expression in LNCaP cells, a prostate cell line. J. Cell. Biochem. 74:395–405, 1999. Published 1999 Wiley-Liss, Inc.

Published

1999