Your search keyword '"Shattuck, Milena R."' showing total 12 results

1. Encephalization and longevity evolved in a correlated fashion in Euarchontoglires but not in other mammals

Author

DeCasien, Alex R., Thompson, Nicole A., Williams, Scott A., and Shattuck, Milena R.

Published

2018

2. Increased variation in numbers of presacral vertebrae in suspensory mammals

Author

Williams, Scott A., Spear, Jeffrey K., Petrullo, Lauren, Goldstein, Deanna M., Lee, Amanda B., Peterson, Amy L., Miano, Danielle A., Kaczmarek, Elska B., and Shattuck, Milena R.

Published

2019

3. Ecology, longevity and naked mole-rats: confounding effects of sociality?

Author

Williams, Scott A. and Shattuck, Milena R.

Published

2015

4. Arboreality has allowed for the evolution of increased longevity in mammals

Author

Shattuck, Milena R., Williams, Scott A., and Walker, Alan

Published

2010

5. Evolutionary relationships of Macaca fascicularis fascicularis (Raffles 1821) (Primates: Cercopithecidae) from Singapore revealed by Bayesian analysis of mitochondrial DNA sequences.

Author

Schillaci, Michael A., Klegarth, Amy R., Switzer, William M., Shattuck, Milena R., Lee, Benjamin P. Y-H., and Hollocher, Hope

Subjects

KRA, ANIMAL dispersal, PHYLOGENY, MOLECULAR genetics, BIOLOGICAL evolution, HAPLOTYPES

Abstract

Long-tailed macaques (Macaca fascicularis) have a wide geographic distribution across mainland and insular Southeast Asia. The evolutionary history of long-tailed macaques has been examined extensively through comparison of phenotypic variation and by phylogenetic analyses of molecular genetic data. Nonetheless, the complex evolutionary history of M. fascicularis throughout Southeast Asia is not fully understood. For the present study, we performed a Bayesian phylogenetic analysis of M. fascicularis mitochondrial 12S/tRNA-val/16S sequences to examine the evolutionary relationships of the long-tailed macaques from Singapore. More generally, we hoped to gain a better understanding of the evolutionary history of long-tailed macaques throughout Southeast Asia. We used previously archived sequences in GenBank and new sequences from Singapore (n=34) and Bali, Indonesia (n=2) in a Bayesian phylogenetic framework to co-infer evolutionary histories and divergence dates. Our results revealed two large clades, one composed of haplotypes primarily from Sundaic islands populations, and the second primarily from continental populations. These two larger clades comprise four primary regional clades. All three haplotypes from Singapore form a well-supported subclade within a larger peninsular clade. A medianjoining network of haplotypes mirrored the results from the phylogenetic analyses. We found divergence dates that were largely consistent with previous studies using complete mitochondrial genomes. Based on an assessment of phylogenetic relationships, the pattern of estimated divergence dates, and the available fossil record, we suggest that the evolutionary history of M. fascicularis likely included multiple dispersal events. [ABSTRACT FROM AUTHOR]

Published

2017

6. Vertebral numbers and human evolution.

Author

Williams, Scott A., Middleton, Emily R., Villamil, Catalina I., and Shattuck, Milena R.

Subjects

LUMBAR vertebrae, ZYGAPOPHYSEAL joint, JOINTS (Anatomy), AUSTRALOPITHECINES, FOSSIL hominids

Abstract

ABSTRACT Ever since Tyson (1699), anatomists have noted and compared differences in the regional numbers of vertebrae among humans and other hominoids. Subsequent workers interpreted these differences in phylogenetic, functional, and behavioral frameworks and speculated on the history of vertebral numbers during human evolution. Even in a modern phylogenetic framework and with greatly expanded sample sizes of hominoid species, researchers' conclusions vary drastically, positing that hominins evolved from either a 'long-backed' (numerically long lumbar column) or a 'short-backed' (numerically short lumbar column) ancestor. We show that these disparate interpretations are due in part to the use of different criteria for what defines a lumbar vertebra, but argue that, regardless of which lumbar definition is used, hominins are similar to their great ape relatives in possessing a short trunk, a rare occurrence in mammals and one that defines the clade Hominoidea. Furthermore, we address the recent claim that the early hominin thoracolumbar configuration is not distinct from that of modern humans and conclude that early hominins show evidence of 'cranial shifting,' which might explain the anomalous morphology of several early hominin fossils. Finally, we evaluate the competing hypotheses on numbers of vertebrae and argue that the current data support a hominin ancestor with an African ape-like short trunk and lower back. Am J Phys Anthropol 159:S19-S36, 2016. © 2016 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2016

7. Patterns of genetic variation and the role of selection in HTR1A and HTR1B in macaques (Macaca).

Author

Shattuck, Milena R., Satkoski-Trask, Jessica, Deinard, Amos, Tito, Raul Y., Smith, David G., Melnick, Don J., and Malhi, Ripan S.

Subjects

*SEROTONIN, *MACAQUES, *MEDICAL research, *SEROTONIN receptors, *BIOLOGICAL divergence, *HUMAN genetic variation

Abstract

Background Research has increasingly highlighted the role of serotonin in behavior. However, few researchers have examined serotonin in an evolutionary context, although such research could provide insight into the evolution of important behaviors. The genus Macaca represents a useful model to address this, as this genus shows a wide range of behavioral variation. In addition, many genetic features of the macaque serotonin system are similar to those of humans, and as common models in biomedical research, knowledge of the genetic variation and evolution of serotonin functioning in macaques are particularly relevant for studies of human evolution. Here, we examine the role of selection in the macaque serotonin system by comparing patterns of genetic variation for two genes that code for two types of serotonin receptors - HTR1A and HTR1B - across five species of macaques. Results The pattern of variation is significantly different for HTR1A compared to HTR1B. Specifically, there is an increase in between-species variation compared to within-species variation for HTR1A. Phylogenetic analyses indicate that portions of HTR1A show an elevated level of nonsynonymous substitutions. Together these analyses are indicative of positive selection acting on HTR1A, but not HTR1B. Furthermore, the haplotype network for HTR1A is inconsistent with the species tree, potentially due to both deep coalescence and selection. Conclusions The results of this study indicate distinct evolutionary histories for HTR1A and HTR1B, with HTR1A showing evidence of selection and a high level of divergence among species, a factor which may have an impact on biomedical research that uses these species as models. The wide genetic variation of HTR1A may also explain some of the species differences in behavior, although further studies on the phenotypic effect of the sequenced polymorphisms are needed to confirm this. [ABSTRACT FROM AUTHOR]

Published

2014

8. Patterns of Admixture and Population Structure in Native Populations of Northwest North America.

Author

Verdu, Paul, Pemberton, Trevor J., Laurent, Romain, Kemp, Brian M., Gonzalez-Oliver, Angelica, Gorodezky, Clara, Hughes, Cris E., Shattuck, Milena R., Petzelt, Barbara, Mitchell, Joycelynn, Harry, Harold, William, Theresa, Worl, Rosita, Cybulski, Jerome S., Rosenberg, Noah A., and Malhi, Ripan S.

Subjects

POPULATION research, INDIGENOUS peoples, GENOMICS, SINGLE nucleotide polymorphisms, GENEALOGY

Abstract

The initial contact of European populations with indigenous populations of the Americas produced diverse admixture processes across North, Central, and South America. Recent studies have examined the genetic structure of indigenous populations of Latin America and the Caribbean and their admixed descendants, reporting on the genomic impact of the history of admixture with colonizing populations of European and African ancestry. However, relatively little genomic research has been conducted on admixture in indigenous North American populations. In this study, we analyze genomic data at 475,109 single-nucleotide polymorphisms sampled in indigenous peoples of the Pacific Northwest in British Columbia and Southeast Alaska, populations with a well-documented history of contact with European and Asian traders, fishermen, and contract laborers. We find that the indigenous populations of the Pacific Northwest have higher gene diversity than Latin American indigenous populations. Among the Pacific Northwest populations, interior groups provide more evidence for East Asian admixture, whereas coastal groups have higher levels of European admixture. In contrast with many Latin American indigenous populations, the variance of admixture is high in each of the Pacific Northwest indigenous populations, as expected for recent and ongoing admixture processes. The results reveal some similarities but notable differences between admixture patterns in the Pacific Northwest and those in Latin America, contributing to a more detailed understanding of the genomic consequences of European colonization events throughout the Americas. [ABSTRACT FROM AUTHOR]

Published

2014

9. The evolutionary history of SLC6A4 and the role of plasticity in macaca.

Author

Shattuck, Milena R., Satkoski‐Trask, Jessica, Deinard, Amos, Tito, Raul Y., Smith, David G., and Malhi, Ripan S.

Subjects

*SEROTONIN, *NEUROPLASTICITY, *BIOMARKERS, *MACAQUES, *GENETIC polymorphisms

Abstract

ABSTRACT Serotonin has been repeatedly indicated as a biological marker of behavior. In particular, the serotonin transporter gene, SLC6A4, has been the focus of a large body of research. Interestingly, both rhesus macaques ( Macaca mulatta) and humans have independently evolved a number of shared polymorphisms for this gene, which is indicative of parallel evolution between the two species. However, little is known about the evolution of this gene, particularly within macaques. Although there are several hypotheses as to the adaptive values of various polymorphisms, few authors have gone beyond theoretical discussion. Here, we examined the genetic variation in SLC6A4 within and between several species of macaques and investigate whether selection has played a significant role in its evolutionary history. In addition, we assayed the promoter region polymorphism, 5-HTTLPR, which is known to play a significant role in regulating both serotonin turnover and behavior. In examining the distribution of the 5-HTTLPR polymorphism, we identified significant differences between Indian and Chinese populations of Macaca mulatta; furthermore, we discovered its presence in Macaca cyclopis, which has not been described before. In regard to the evolutionary history of SLC6A4, we found little evidence for selection and conclude that SLC6A4 largely evolved through neutral processes, possibly due to its potential role in regulating behavioral plasticity. However, we also found very low levels of linkage between the coding regions and 5-HTTLPR. Because we limited evolutionary analyses to the coding regions, it is possible that the promoter region shows a distinct evolutionary history from SLC6A4. Am J Phys Anthropol 153:605-616, 2014. © 2013 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2014

10. Sexual conflict in primates.

Author

Stumpf, Rebecca M., Martinez-Mota, Rodolfo, Milich, Krista M., Righini, Nicoletta, and Shattuck, Milena R.

Published

2011

11. Research in a Non‐Research Position.

Author

Shattuck, Milena R.

Subjects

*ANTHROPOLOGY, *RESEARCH, *FACULTY advisors, *SCIENTISTS, *SOCIAL sciences

Abstract

The article discusses conducting research in anthropology in a non-research position such as non-tenure-track (NTT) faculty. Topics include how NTT jobs severely limit research ability, drawbacks of conducting research in a non-research position and the need to acknowledge NTT faculty in training the next generation of scientists.

Published

2019

12. Evolution of vertebral numbers in primates, with a focus on hominoids and the last common ancestor of hominins and panins.

Author

Spear, Jeffrey K., Grabowski, Mark, Sekhavati, Yeganeh, Costa, Christina E., Goldstein, Deanna M., Petrullo, Lauren A., Peterson, Amy L., Lee, Amanda B., Shattuck, Milena R., Gómez-Olivencia, Asier, and Williams, Scott A.

Subjects

*APES, *SACRUM, *SPINE, *PRIMATES, *HOMINIDS, *LUMBAR vertebrae, *VERTEBRAE

Abstract

The primate vertebral column has been extensively studied, with a particular focus on hominoid primates and the last common ancestor of humans and chimpanzees. The number of vertebrae in hominoids—up to and including the last common ancestor of humans and chimpanzees—is subject to considerable debate. However, few formal ancestral state reconstructions exist, and none include a broad sample of primates or account for the correlated evolution of the vertebral column. Here, we conduct an ancestral state reconstruction using a model of evolution that accounts for both homeotic (changes of one type of vertebra to another) and meristic (addition or loss of a vertebra) changes. Our results suggest that ancestral primates were characterized by 29 precaudal vertebrae, with the most common formula being seven cervical, 13 thoracic, six lumbar, and three sacral vertebrae. Extant hominoids evolved tail loss and a reduced lumbar column via sacralization (homeotic transition at the last lumbar vertebra). Our results also indicate that the ancestral hylobatid had seven cervical, 13 thoracic, five lumbar, and four sacral vertebrae, and the ancestral hominid had seven cervical, 13 thoracic, four lumbar, and five sacral vertebrae. The last common ancestor of humans and chimpanzees likely either retained this ancestral hominid formula or was characterized by an additional sacral vertebra, possibly acquired through a homeotic shift at the sacrococcygeal border. Our results support the 'short-back' model of hominin vertebral evolution, which postulates that hominins evolved from an ancestor with an African ape–like numerical composition of the vertebral column. [ABSTRACT FROM AUTHOR]

Published

2023