Your search keyword '"Humble, Emily"' showing total 17 results

1. Population genomics of the white-beaked dolphin (Lagenorhynchus albirostris): Implications for conservation amid climate-driven range shifts

Author

Gose, Marc-Alexander, Humble, Emily, Brownlow, Andrew, Wall, Dave, Rogan, Emer, Sigurðsson, Guðjón Már, Kiszka, Jeremy J., Thøstesen, Charlotte Bie, IJsseldijk, Lonneke L., ten Doeschate, Mariel, Davison, Nicholas J., Øien, Nils, Deaville, Rob, Siebert, Ursula, and Ogden, Rob

Published

2024

2. Developmental validation of Oxford Nanopore Technology MinION sequence data and the NGSpeciesID bioinformatic pipeline for forensic genetic species identification

Author

Vasiljevic, Nina, Lim, Marisa, Humble, Emily, Seah, Adeline, Kratzer, Adelgunde, Morf, Nadja V., Prost, Stefan, and Ogden, Rob

Published

2021

3. Genomic data reveal strong differentiation and reduced genetic diversity in island golden eagle populations.

Author

Sato, Yu, Humble, Emily, and Ogden, Rob

Subjects

*GOLDEN eagle, *WHOLE genome sequencing, *GENETIC variation, *POPULATION genetics, *CONSERVATION genetics, *INBREEDING

Abstract

Understanding population structure and the extent and distribution of genetic diversity are recognized as central issues in endangered species research, with broad implications for effective conservation management. Advances in whole genome sequencing techniques provide greater resolution of genome-wide genetic diversity and inbreeding. Subspecies of golden eagles (Aquila chrysaetos) in Scotland (A. c. chrysaetos) and Japan (A. c. japonica) are endangered; it is therefore important to understand genetic diversity and inbreeding of these small island populations to increase the chances of conservation success. We investigated this using whole genome sequencing data from golden eagles in Scotland, continental Europe, Japan, and the USA. Following determination of population genetic structure, analysis of heterozygosity and nucleotide diversity revealed reduced levels of genetic diversity together with runs of homozygosity, suggesting evidence of inbreeding attributable to recent shared parental ancestry in the island populations. These results highlight the need to consider genetic reinforcement of small isolated golden eagle populations from neighbouring outbred populations, alongside existing efforts to boost population size through within-island conservation translocations and captive breeding programmes. [ABSTRACT FROM AUTHOR]

Published

2024

4. Comparative population genomics of manta rays has global implications for management.

Author

Humble, Emily, Hosegood, Jane, Carvalho, Gary, Bruyn, Mark, Creer, Simon, Stevens, Guy M. W., Armstrong, Amelia, Bonfil, Ramon, Deakos, Mark, Fernando, Daniel, Froman, Niv, Peel, Lauren R., Pollett, Stephen, Ponzo, Alessandro, Stewart, Joshua D., Wintner, Sabine, and Ogden, Rob

Abstract

Understanding population connectivity and genetic diversity is of fundamental importance to conservation. However, in globally threatened marine megafauna, challenges remain due to their elusive nature and wide‐ranging distributions. As overexploitation continues to threaten biodiversity across the globe, such knowledge gaps compromise both the suitability and effectiveness of management actions. Here, we use a comparative framework to investigate genetic differentiation and diversity of manta rays, one of the most iconic yet vulnerable groups of elasmobranchs on the planet. Despite their recent divergence, we show how oceanic manta rays (Mobula birostris) display significantly higher heterozygosity than reef manta rays (Mobula alfredi) and that M. birostris populations display higher connectivity worldwide. Through inferring modes of colonization, we reveal how both contemporary and historical forces have likely influenced these patterns, with important implications for population management. Our findings highlight the potential for fisheries to disrupt population dynamics at both local and global scales and therefore have direct relevance for international conservation of marine species. [ABSTRACT FROM AUTHOR]

Published

2023

5. Conservation management strategy impacts inbreeding and mutation load in scimitar-horned oryx.

Author

Humble, Emily, Stoffel, Martin A., Dicks, Kara, Ball, Alex D., Gooley, Rebecca M., Chuven, Justin, Pusey, Ricardo, Al Remeithi, Mohammed, Koepfli, Klaus-Peter, Pukazhenthi, Budhan, Senn, Helen, and Ogden, Rob

Subjects

*INBREEDING, *GENETIC mutation, *WILDLIFE management, *HOMOZYGOSITY, *ANTELOPES

Abstract

In an age of habitat loss and overexploitation, small populations, both captive and wild, are increasingly facing the effects of isolation and inbreeding. Genetic management has therefore become a vital tool for ensuring population viability. However, little is known about how the type and intensity of intervention shape the genomic landscape of inbreeding and mutation load. We address this using whole-genome sequence data of the scimitar-horned oryx (Oryx dammah), an iconic antelope that has been subject to contrasting management strategies since it was declared extinct in the wild. We show that unmanaged populations are enriched for long runs of homozygosity (ROH) and have significantly higher inbreeding coefficients than managed populations. Additionally, despite the total number of deleterious alleles being similar across management strategies, the burden of homozygous deleterious genotypes was consistently higher in unmanaged groups. These findings emphasize the risks associated with deleterious mutations through multiple generations of inbreeding. As wildlife management strategies continue to diversify, our study reinforces the importance of maintaining genome-wide variation in vulnerable populations and has direct implications for one of the largest reintroduction attempts in the world. [ABSTRACT FROM AUTHOR]

Published

2023

6. Rapid in situ identification of biological specimens via DNA amplicon sequencing using miniaturized laboratory equipment.

Author

Pomerantz, Aaron, Sahlin, Kristoffer, Vasiljevic, Nina, Seah, Adeline, Lim, Marisa, Humble, Emily, Kennedy, Susan, Krehenwinkel, Henrik, Winter, Sven, Ogden, Rob, and Prost, Stefan

Published

2022

7. Phylogenomics and species delimitation for effective conservation of manta and devil rays.

Author

Hosegood, Jane, Humble, Emily, Ogden, Rob, de Bruyn, Mark, Creer, Simon, Stevens, Guy M. W., Abudaya, Mohammed, Bassos‐Hull, Kim, Bonfil, Ramon, Fernando, Daniel, Foote, Andrew D., Hipperson, Helen, Jabado, Rima W., Kaden, Jennifer, Moazzam, Muhammad, Peel, Lauren R, Pollett, Stephen, Ponzo, Alessandro, Poortvliet, Marloes, and Salah, Jehad

Subjects

*MOBULIDAE, *SPECIES, *BIODIVERSITY conservation, *SPECIES diversity

Abstract

Practical biodiversity conservation relies on delineation of biologically meaningful units. Manta and devil rays (Mobulidae) are threatened worldwide, yet morphological similarities and a succession of recent taxonomic changes impede the development of an effective conservation strategy. Here, we generate genome‐wide single nucleotide polymorphism (SNP) data from a geographically and taxonomically representative set of manta and devil ray samples to reconstruct phylogenetic relationships and evaluate species boundaries under the general lineage concept. We show that nominal species units supported by alternative data sources constitute independently evolving lineages, and find robust evidence for a putative new species of manta ray in the Gulf of Mexico. Additionally, we uncover substantial incomplete lineage sorting indicating that rapid speciation together with standing variation in ancestral populations has driven phylogenetic uncertainty within Mobulidae. Finally, we detect cryptic diversity in geographically distinct populations, demonstrating that management below the species level may be warranted in certain species. Overall, our study provides a framework for molecular genetic species delimitation that is relevant to wide‐ranging taxa of conservation concern, and highlights the potential for genomic data to support effective management, conservation and law enforcement strategies. [ABSTRACT FROM AUTHOR]

Published

2020

8. From DNA to biomass: opportunities and challenges in species quantification of bulk fisheries products.

Author

Hansen, Brian Klitgaard, Farrant, Gregory Kevin, Ogden, Rob, Humble, Emily, Ólafsdóttir, Guðbjörg, Bekkevold, Dorte, Knudsen, Steen Wilhelm, Møller, Peter Rask, and Nielsen, Einar Eg

Subjects

FISHERY products, FISH DNA, ATLANTIC cod, FERMENTED fish, DNA, FISH stocking, FISHERY management

Abstract

Fisheries enforcement relies on visual catch identification and quantification at sea or when landed. Silage (fish dissolved in acid) and fish blocks (block frozen fish) are promising methods for on-board processing and storage of low-value catches. We examined the use of non-destructive sampling and two DNA-based methods, quantitative PCR (qPCR) and metabarcoding, to assess species composition and relative abundance in industrial grade experimental silage and fish blocks. We demonstrate the ability to identify and quantify DNA from fish species in both products. qPCR analysis of small silage samples collected over 21 days detected all target control species. DNA from one species (Atlantic wolffish) was consistently overrepresented while, for three species of gadoids (Atlantic cod, haddock and whiting), the DNA content matched input tissue proportions with high accuracy. qPCR and metabarcoding of fish blocks, sampled as run-off water and exterior swabs, provided consistent species detection, with the highest variance observed in quantification from swab samples. Our analysis shows that DNA-based methods have significant potential as a tool for species identification and quantification of complex on-board-processed seafood products and are readily applicable to taxonomically and morphologically similar fish. There is, however, a need for establishing DNA/weight calibration factors for primary fisheries species. [ABSTRACT FROM AUTHOR]

Published

2020

9. Chromosomal‐level genome assembly of the scimitar‐horned oryx: Insights into diversity and demography of a species extinct in the wild.

Author

Humble, Emily, Dobrynin, Pavel, Senn, Helen, Chuven, Justin, Scott, Alan F., Mohr, David W., Dudchenko, Olga, Omer, Arina D., Colaric, Zane, Lieberman Aiden, Erez, Al Dhaheri, Shaikha Salem, Wildt, David, Oliaji, Shireen, Tamazian, Gaik, Pukazhenthi, Budhan, Ogden, Rob, and Koepfli, Klaus‐Peter

Subjects

*SPECIES diversity, *CLIMATE change, *ENDANGERED species, *CHROMOSOMES, *SINGLE nucleotide polymorphisms

Abstract

Captive populations provide a valuable insurance against extinctions in the wild. However, they are also vulnerable to the negative impacts of inbreeding, selection and drift. Genetic information is therefore considered a critical aspect of conservation management. Recent developments in sequencing technologies have the potential to improve the outcomes of management programmes; however, the transfer of these approaches to applied conservation has been slow. The scimitar‐horned oryx (Oryx dammah) is a North African antelope that has been extinct in the wild since the early 1980s and is the focus of a large‐scale and long‐term reintroduction project. To enable the selection of suitable founder individuals, facilitate post‐release monitoring and improve captive breeding management, comprehensive genomic resources are required. Here, we used 10X Chromium sequencing together with Hi‐C contact mapping to develop a chromosomal‐level genome assembly for the species. The resulting assembly contained 29 chromosomes with a scaffold N50 of 100.4 Mb, and displayed strong chromosomal synteny with the cattle genome. Using resequencing data from six additional individuals, we demonstrated relatively high genetic diversity in the scimitar‐horned oryx compared to other mammals, despite it having experienced a strong founding event in captivity. Additionally, the level of diversity across populations varied according to management strategy. Finally, we uncovered a dynamic demographic history that coincided with periods of climate variation during the Pleistocene. Overall, our study provides a clear example of how genomic data can uncover valuable insights into captive populations and contributes important resources to guide future management decisions of an endangered species. [ABSTRACT FROM AUTHOR]

Published

2020

10. An 85K SNP Array Uncovers Inbreeding and Cryptic Relatedness in an Antarctic Fur Seal Breeding Colony.

Author

Humble, Emily, Paijmans, Anneke J., Forcada, Jaume, and Hoffman, Joseph I.

Subjects

*ANIMAL breeding, *HOMOZYGOSITY, *FUR, *SINGLE nucleotide polymorphisms, *GENETIC markers, *BIRD breeding, *FISH breeding

Abstract

High density single nucleotide polymorphism (SNP) arrays allow large numbers of individuals to be rapidly and cost-effectively genotyped at large numbers of genetic markers. However, despite being widely used in studies of humans and domesticated plants and animals, SNP arrays are lacking for most wild organisms. We developed a custom 85K Affymetrix Axiom array for an intensively studied pinniped, the Antarctic fur seal (Arctocephalus gazella). SNPs were discovered from a combination of genomic and transcriptomic resources and filtered according to strict criteria. Out of a total of 85,359 SNPs tiled on the array, 75,601 (88.6%) successfully converted and were polymorphic in 270 animals from a breeding colony at Bird Island in South Georgia. Evidence was found for inbreeding, with three genomic inbreeding coefficients being strongly intercorrelated and the proportion of the genome in runs of homozygosity being non-zero in all individuals. Furthermore, analysis of genomic relatedness coefficients identified previously unknown first-degree relatives and multiple second-degree relatives among a sample of ostensibly unrelated individuals. Such "cryptic relatedness" within fur seal breeding colonies may increase the likelihood of consanguineous matings and could therefore have implications for understanding fitness variation and mate choice. Finally, we demonstrate the cross-amplification potential of the array in three related pinniped species. Overall, our SNP array will facilitate future studies of Antarctic fur seals and has the potential to serve as a more general resource for the wider pinniped research community. [ABSTRACT FROM AUTHOR]

Published

2020

11. RAD Sequencing and a Hybrid Antarctic Fur Seal Genome Assembly Reveal Rapidly Decaying Linkage Disequilibrium, Global Population Structure and Evidence for Inbreeding.

Author

Humble, Emily, Dasmahapatra, Kanchon K., Martinez-Barrio, Alvaro, Gregório, Inês, Forcada, Jaume, Polikeit, Ann-Christin, Goldsworthy, Simon D., Goebel, Michael E., Kalinowski, Jörn, Wolf, Jochen B. W., and Hoffman, Joseph I.

Subjects

*NUCLEOTIDE sequencing, *ARCTOCEPHALUS gazella

Abstract

Recent advances in high throughput sequencing have transformed the study of wild organisms by facilitating the generation of high quality genome assemblies and dense genetic marker datasets. These resources have the potential to significantly advance our understanding of diverse phenomena at the level of species, populations and individuals, ranging from patterns of synteny through rates of linkage disequilibrium (LD) decay and population structure to individual inbreeding. Consequently, we used PacBio sequencing to refine an existing Antarctic fur seal (Arctocephalus gazella) genome assembly and genotyped 83 individuals from six populations using restriction site associated DNA (RAD) sequencing. The resulting hybrid genome comprised 6,169 scaffolds with an N50 of 6.21 Mb and provided clear evidence for the conservation of large chromosomal segments between the fur seal and dog (Canis lupus familiaris). Focusing on the most extensively sampled population of South Georgia, we found that LD decayed rapidly, reaching the background level by around 400 kb, consistent with other vertebrates but at odds with the notion that fur seals experienced a strong historical bottleneck. We also found evidence for population structuring, with four main Antarctic island groups being resolved. Finally, appreciable variance in individual inbreeding could be detected, reflecting the strong polygyny and site fidelity of the species. Overall, our study contributes important resources for future genomic studies of fur seals and other pinnipeds while also providing a clear example of how high throughput sequencing can generate diverse biological insights at multiple levels of organization. [ABSTRACT FROM AUTHOR]

Published

2018

12. Genomic Methods Take the Plunge: Recent Advances in High-Throughput Sequencing of Marine Mammals.

Author

Cammen, Kristina M., Andrews, Kimberly R., Carroll, Emma L., Foote, Andrew D., Humble, Emily, Khudyakov, Jane I., Louis, Marie, McGowen, Michael R., Olsen, Morten Tange, and Van Cise, Amy M.

Subjects

MARINE mammals, AQUATIC mammals, GENOMICS, SINGLE nucleotide polymorphisms, NUCLEOTIDE sequencing

Abstract

The dramatic increase in the application of genomic techniques to non-model organisms (NMOs) over the past decade has yielded numerous valuable contributions to evolutionary biology and ecology, many of which would not have been possible with traditional genetic markers. We review this recent progression with a particular focus on genomic studies of marine mammals, a group of taxa that represent key macroevolutionary transitions from terrestrial to marine environments and for which available genomic resources have recently undergone notable rapid growth. Genomic studies of NMOs utilize an expanding range of approaches, including whole genome sequencing, restriction site-associated DNA sequencing, array-based sequencing of single nucleotide polymorphisms and target sequence probes (e.g., exomes), and transcriptome sequencing. These approaches generate different types and quantities of data, and many can be applied with limited or no prior genomic resources, thus overcoming one traditional limitation of research on NMOs. Within marine mammals, such studies have thus far yielded significant contributions to the fields of phylogenomics and comparative genomics, as well as enabled investigations of fitness, demography, and population structure. Here we review the primary options for generating genomic data, introduce several emerging techniques, and discuss the suitability of each approach for different applications in the study of NMOs. [ABSTRACT FROM AUTHOR]

Published

2016

13. inbreedR: an R package for the analysis of inbreeding based on genetic markers.

Author

Stoffel, Martin A., Esser, Mareike, Kardos, Marty, Humble, Emily, Nichols, Hazel, David, Patrice, Hoffman, Joseph I., and Poisot, Timothée

Subjects

INBREEDING, GENETIC markers, HETEROZYGOSITY, MICROSATELLITE repeats, NUCLEOTIDE sequencing

Abstract

Heterozygosity-fitness correlations (HFCs) have been widely used to explore the impact of inbreeding on individual fitness. Initially, most studies used small panels of microsatellites, but more recently with the advent of next-generation sequencing, large SNP datasets are becoming increasingly available and these provide greater power and precision to quantify the impact of inbreeding on fitness., Despite the popularity of HFC studies, effect sizes tend to be rather small. One reason for this may be low variation in inbreeding levels among individuals. Using genetic markers, it is possible to measure variance in inbreeding through the strength of correlation in heterozygosity across marker loci, termed identity disequilibrium (ID)., ID can be quantified using the measure [ABSTRACT FROM AUTHOR]

Published

2016

14. Substitutions in the Glycogenin-1 Gene Are Associated with the Evolution of Endothermy in Sharks and Tunas.

Author

Ciezarek, Adam G., Dunning, Luke T., Jones, Catherine S., Noble, Leslie R., Humble, Emily, Stefanni, Sergio S., and Savolainen, Vincent

Subjects

PHENOTYPIC plasticity, PHYLOGENY, BIOLOGICAL evolution, GENETIC distance, BIOLOGICAL divergence, FISHES

Abstract

Despite 400-450 million years of independent evolution, a strong phenotypic convergence has occurred between two groups of fish: tunas and lamnid sharks. This convergence is characterized by centralization of red muscle, a distinctive swimming style (stiffened body powered through tail movements) and elevated body temperature (endothermy). Furthermore, both groups demonstrate elevated white muscle metabolic capacities. All these traits are unusual in fish and more likely evolved to support their fast-swimming, pelagic, predatory behavior. Here, we tested the hypothesis that their convergent evolution was driven by selection on a set of metabolic genes. We sequenced white muscle transcriptomes of six tuna, one mackerel, and three shark species, and supplemented this data set with previously published RN A-seq data. Using 26 species in total (including 7,032 tuna genes plus 1,719 shark genes), we constructed phylogenetic trees and carried out maximum-likelihood analyses of gene selection. We inferred several genes relating to metabolism to be under selection. We also found that the same one gene, glycogenin-1, evolved under positive selection independently in tunas and lamnid sharks, providing evidence of convergent selective pressures at gene level possibly underlying shared physiology. [ABSTRACT FROM AUTHOR]

Published

2016

15. Transcriptomic SNP discovery for custom genotyping arrays: impacts of sequence data, SNP calling method and genotyping technology on the probability of validation success.

Author

Humble, Emily, Thorne, Michael A. S., Forcada, Jaume, and Hoffman, Joseph I.

Subjects

*SINGLE nucleotide polymorphisms, *GENOTYPE-environment interaction, *NORTHERN fur seal, *TRANSCRIPTION factors, *PRIMITIVE technology

Abstract

Background: Single nucleotide polymorphism (SNP) discovery is an important goal of many studies. However, the number of 'putative' SNPs discovered from a sequence resource may not provide a reliable indication of the number that will successfully validate with a given genotyping technology. For this it may be necessary to account for factors such as the method used for SNP discovery and the type of sequence data from which it originates, suitability of the SNP flanking sequences for probe design, and genomic context. To explore the relative importance of these and other factors, we used Illumina sequencing to augment an existing Roche 454 transcriptome assembly for the Antarctic fur seal (Arctocephalus gazella). We then mapped the raw Illumina reads to the new hybrid transcriptome using BWA and BOWTIE2 before calling SNPs with GATK. The resulting markers were pooled with two existing sets of SNPs called from the original 454 assembly using NEWBLER and SWAP454. Finally, we explored the extent to which SNPs discovered using these four methods overlapped and predicted the corresponding validation outcomes for both Illumina Infinium iSelect HD and Affymetrix Axiom arrays. Results: Collating markers across all discovery methods resulted in a global list of 34,718 SNPs. However, concordance between the methods was surprisingly poor, with only 51.0 % of SNPs being discovered by more than one method and 13.5 % being called from both the 454 and Illumina datasets. Using a predictive modeling approach, we could also show that SNPs called from the Illumina data were on average more likely to successfully validate, as were SNPs called by more than one method. Above and beyond this pattern, predicted validation outcomes were also consistently better for Affymetrix Axiom arrays. Conclusions: Our results suggest that focusing on SNPs called by more than one method could potentially improve validation outcomes. They also highlight possible differences between alternative genotyping technologies that could be explored in future studies of non-model organisms. [ABSTRACT FROM AUTHOR]

Published

2016

16. Born blonde: a recessive loss-of-function mutation in the melanocortin 1 receptor is associated with cream coat coloration in Antarctic fur seals.

Author

Peters, Lucy, Humble, Emily, Kröcker, Nicole, Fuchs, Birgit, Forcada, Jaume, and Hoffman, Joseph I.

Subjects

*ARCTOCEPHALUS gazella, *MELANOCORTIN receptors, *ANIMAL coloration, *ANIMAL mutation, *GENETIC polymorphisms

Abstract

Although the genetic basis of color variation has been extensively studied in humans and domestic animals, the genetic polymorphisms responsible for different color morphs remain to be elucidated in many wild vertebrate species. For example, hypopigmentation has been observed in numerous marine mammal species but the underlying mutations have not been identified. A particularly compelling candidate gene for explaining color polymorphism is the melanocortin 1 receptor ( MC1 R), which plays a key role in the regulation of pigment production. We therefore used Antarctic fur seals ( Arctocephalus gazella) as a highly tractable marine mammal system with which to test for an association between nucleotide variation at the MC1 R and melanin-based coat color phenotypes. By sequencing 70 wild-type individuals with dark-colored coats and 26 hypopigmented individuals with cream-colored coats, we identified a nonsynonymous mutation that results in the substitution of serine with phenylalanine at an evolutionarily highly conserved structural domain. All of the hypopigmented individuals were homozygous for the allele coding for phenylalanine, consistent with a recessive loss-of-function allele. In order to test for cryptic population structure, which can generate artefactual associations, and to evaluate whether homozygosity at the MC1 R could be indicative of low genome-wide heterozygosity, we also genotyped all of the individuals at 50 polymorphic microsatellite loci. We were unable to detect any population structure and also found that wild-type and hypopigmented individuals did not differ significantly in their standardized multilocus heterozygosity. Such a lack of association implies that hypopigmented individuals are unlikely to suffer disproportionately from inbreeding depression, and hence, we have no reason to believe that they are at a selective disadvantage in the wider population. [ABSTRACT FROM AUTHOR]

Published

2016

17. Evidence of positive selection associated with placental loss in tiger sharks.

Author

Swift, Dominic G., Dunning, Luke T., Igea, Javier, Brooks, Edward J., Jones, Catherine S., Noble, Leslie R., Ciezarek, Adam, Humble, Emily, and Savolainen, Vincent

Subjects

TIGER shark, VIVIPARITY, ANIMAL feeding behavior, AQUATIC animals -- Food, ANIMAL reproduction, ANIMAL behavior

Abstract

Background: All vertebrates initially feed their offspring using yolk reserves. In some live-bearing species these yolk reserves may be supplemented with extra nutrition via a placenta. Sharks belonging to the Carcharhinidae family are all live-bearing, and with the exception of the tiger shark (Galeocerdo cuvier), develop placental connections after exhausting yolk reserves. Phylogenetic relationships suggest the lack of placenta in tiger sharks is due to secondary loss. This represents a dramatic shift in reproductive strategy, and is likely to have left a molecular footprint of positive selection within the genome. Results: We sequenced the transcriptome of the tiger shark and eight other live-bearing shark species. From this data we constructed a time-calibrated phylogenetic tree estimating the tiger shark lineage diverged from the placental carcharhinids approximately 94 million years ago. Along the tiger shark lineage, we identified five genes exhibiting a signature of positive selection. Four of these genes have functions likely associated with brain development (YWHAE and ARL6IP5) and sexual reproduction (VAMP4 and TCTEX1D2). Conclusions: Our results indicate the loss of placenta in tiger sharks may be associated with subsequent adaptive changes in brain development and sperm production. [ABSTRACT FROM AUTHOR]

Published

2016