Comparative growth and static allometry in the genus Chlorocebus

Characterizing variation in growth across populations is critical to understanding multiple aspects of development in primates, including within-taxon developmental plasticity and the evolution of life history patterns. Growth in wild primates has often been reported and directly compared across larger taxonomic groups and within social groups, but comparisons are rarely investigated across widely dispersed populations of a single taxon. With the Vervet Phenome-Genome Project and the International Vervet Research Consortium, we trapped 936 vervet monkeys of all ages representing three populations (Kenyan pygerythrus, South African pygerythrus, and sabaeus from St. Kitts & Nevis). We gathered 10 different body measurements from each including mass, body breadth and length, segmental limb lengths, and chest circumference. To gain a better understanding of how ontogenetic patterns vary in these populations, we calculated bivariate allometry coefficients, derived using PCA on log-transformed and z-standardized trait values, and compared them to isometric vector coefficients. Within all population samples, around weaning age most traits showed a negative allometric relationship to body length. As each population ages, however, distinct patterns emerge, showing population differences in onset and intensity of growth among traits. In concordance with other analyses on growth in these populations, our results suggest that there exist relative differences in patterns of growth between Chlorocebus populations, further suggesting selection for unique developmental pathways in each

DNA extraction protocol for animal blood samples using the EZNA blood mini kit.

The E.Z.N.A. Blood DNA Mini Kit provides an easy and rapid method for the isolationof genomic DNA for consistent PCR and Southern analysis. Up to 250 μL fresh,frozen, or anticoagulated whole blood can be readily processed at one time. TheE.Z.N.A. Blood DNA Mini Kit can also be used for the preparation of genomic DNAfrom buffy coat, serum, plasma, saliva, buccal swabs, and other body fluids. TheE.Z.N.A. Blood DNA Kit allows for single or multiple simultaneous processing ofmultiple samples. There is no need for phenol/chloroform extractions, and timeconsuming steps are eliminated (e.g. precipitation using isopropanol or ethanol).Purified DNA obtained with the E.Z.N.A. Blood DNA Kit is ready for applications suchas PCR, restriction digestion, and Southern blotting

SNP discovery and characterisation in White Rhino (Ceratotherium simum) with application to parentage assignment

Abstract The white rhino is one of the great success stories of modern wildlife conservation, growing from as few as 50-100 animals in the 1880s, to approximately 20,000 white rhinoceros remaining today. However, illegal trade in conservational rhinoceros horns is adding constant pressure on remaining populations. Captive management of ex situ populations of endangered species using molecular methods can contribute to improving the management of the species. Here we compare for the first time the utility of 33 Single Nucleotide Polymorphisms (SNPs) and nine microsatellites (MS) in isolation and in combination for assigning parentage in captive White Rhinoceros. We found that a combined dataset of SNPs and microsatellites was most informative with the highest confidence level. This study thus provided us with a useful set of SNP and MS markers for parentage and relatedness testing. Further assessment of the utility of these markers over multiple (> three) generations and the incorporation of a larger variety of relationships among individuals (e.g. half-siblings or cousins) is strongly suggested

The static allometry of sexual and non-sexual traits in vervet monkeys

Sexual traits vary tremendously in static allometry. This variation may be explained in part by body size-related differences in the strength of selection. We tested this hypothesis in two populations of vervet monkeys, using estimates of the level of condition dependence for different morphological traits as a proxy for body size-related variation in the strength of selection. In support of the hypothesis, we found that the steepness of allometric slopes increased with the level of condition dependence. One trait of particular interest, the penis, had shallow allometric slopes and low levels of condition dependence, in agreement with one of the most consistent patterns yet detected in the study of allometry, namely that of genitalia exhibiting shallow allometries.This research was supported by NIH grant R01RR0163009

Assessment of microsatellite and SNP markers for parentage assignment in ex situ African Penguin (Spheniscus demersus) populations

Captive management of ex situ populations of endangered species is traditionally based on pedigree information derived from studbook data. However, molecular methods could provide a powerful set of complementary tools to verify studbook records and also contribute to improving the understanding of the genetic status of captive populations. Here, we compare the utility of single nucleotide polymorphisms (SNPs) and microsatellites (MS) and two analytical methods for assigning parentage in ten families of captive African penguins held in South African facilities. We found that SNPs performed better than microsatellites under both analytical frameworks, but a combination of all markers was most informative. A subset of combined SNP (n = 14) and MS loci (n = 10) provided robust assessments of parentage. Captive or supportive breeding programs will play an important role in future African penguin conservation efforts as a source of individuals for reintroduction. Cooperation among these captive facilities is essential to facilitate this process and improve management. This study provided us with a useful set of SNP and MS markers for parentage and relatedness testing among these captive populations. Further assessment of the utility of these markers over multiple (>3) generations and the incorporation of a larger variety of relationships among individuals (e.g., half‐siblings or cousins) is strongly suggested

ABI Sanger Sequencing of Avian Clock genes to elucidate markers for Migration Phenology

This protocol follows up on "PCR Amplification of Clock genes with EmeraldAmp® GT PCR Master Mix in Avian species" and is intended to provide the next steps used in the sanger sequencing of the produced amplicons. This protocol uses ABI BigDye reagents (but suitable alternatives exist). The same primers used to produce the PCR products, of the respective clock genes, are used individually in a forward and reverse sequencing reaction. Cycling conditions mimic those used for PCR. Sequencing reactions are purified and subsequently resolved on an ABI Genetic Analyzer. The sequence read data was used in a BLAST search and confirmed to be the genes and regions of interest for all tested species

Integrating Geographic Information into the Analysis of the Genetic Distribution of South African Vervet Monkeys

This project uses the program Geneland to reanalyze McAuliffe’s (2008) thesis data on genetic variability in three South African vervet monkey populations (Polokwane, Oribi and Blyde). Using information on the geographic location and genetic variability of these populations, the spatially explicit Geneland program shows that the three populations are weakly differentiated. These findings oppose the results of previous genetic studies of South African vervet monkeys as well as the results obtained by McAuliffe with the spatially implicit Structure program, which found that the 34 individuals all come from one population. Based on this historic data and the fact that other studies have found the same number of subpopulations with both Structure and Geneland, I conclude that Polokwane, Oribi and Blyde are slightly differentiated, though not distinct enough to be considered separate populations (Latch et al. 2008). These results need to be supported by an analysis of the entire sample of South African vervet monkey genetic data from up to 200 animals prior to suggesting policy changes regarding genetic structuring in South African vervet monkeys

Methylation-based markers for the estimation of age in African Cheetah, Acinonyx jubatus

Age is a key demographic in conservation biology where individual age classes show diffuse differences in terms of important population dynamics metrics such as morbidity and mortality. Furthermore, several traits including reproductive potential show clear senescence with aging. Thus, the ability to estimate the ages for the individuals of a population as part of age class assignment is critical in understanding both the current population structure as well as in modelling and predicting the future survival of species. This study explored the utility of age-related changes in methylation for six candidate genes, EDARADD, ELOVL2, FHL2, GRIA2, ITGA2B, and PENK, to create an age estimation model in captive cheetah. Gene orthologues between humans and cheetah were retrieved containing a hundred CpG’s. Target regions were assayed for differential methylation and fragmentation patterns in fifty samples using mass array technology for a total of seventy-seven CpG clusters. Correlation analyses between CpG methylation and chronological age identified six CpG’s with an age relationship, of which four were hypomethylated and two were hypermethylated. Regression models, fitted for different combinations of CpG’s, indicated that age models using four and six CpG’s were most accurate, with the six CpG model having superior correlation and predictive power (R2 = 0.70, Mean Absolute Error = 25 months). This model was more accurate than previous attempts using methylation sensitive Polymerase Chain Reaction and performed similarly to models created using a candidate gene approach in several other mammal species, making methylation a promising tool of age estimation in cheetah

PCR Amplification of Clock and Adcyap1 genes with EmeraldAmp® GT PCR Master Mix in Avian species for polymorphism elucidation

This PCR protocol is used to amplify Clock and Adcyap1 gene regions in avian species which have previously shown polymorphisms, such as poly-Q runs, that correlated to migration phenology. It was tested and optimized in Woodlands kingfisher (Halcyon senegalensis) and Diederik cuckoos (Chrysococcyx caprius). The primers were designed based on those previously used by Johnson et al. (2007) and Steinmeyer et al. (2009) by comparing the relevant gene sequences for chickens (Galus galus) with several other available avian species to select primers that would account for the most common variations in primer regions, enabling more universal amplification. Individual clock gene sequences were retrieved from Genbank and aligned in BioEdit 7.2. Primers were then selected based on the annotated regions. The assay was designed using 25 μL (half) reactions of EmeraldAmp® GT PCR Master Mix, which is premixed with loading buffer for easy gel loading following PCR and does not require a long initial denaturation step (thereby shortening the run time). Gel electrophoresis was able to confirm successful amplification of a product ±280 bp long in both species. The same primers were subsequently used for sanger sequencing. A BLAST search of the resulting sequences confirmed the identity of the amplified regions