Genome sequence and population declines in the critically endangered greater bamboo lemur (Prolemur simus) and implications for conservation.

BACKGROUND: The greater bamboo lemur (Prolemur simus) is a member of the Family Lemuridae that is unique in their dependency on bamboo as a primary food source. This Critically Endangered species lives in small forest patches in eastern Madagascar, occupying a fraction of its historical range. Here we sequence the genome of the greater bamboo lemur for the first time, and provide genome resources for future studies of this species that can be applied across its distribution. RESULTS: Following whole genome sequencing of five individuals we identified over 152,000 polymorphic single nucleotide variants (SNVs), and evaluated geographic structuring across nearly 19 k SNVs. We characterized a stronger signal associated with a north-south divide than across elevations for our limited samples. We also evaluated the demographic history of this species, and infer a dramatic population crash. This species had the largest effective population size (estimated between ~ 900,000 to one million individuals) between approximately 60,000-90,000 years before present (ybp), during a time in which global climate change affected terrestrial mammals worldwide. We also note the single sample from the northern portion of the extant range had the largest effective population size around 35,000 ybp. CONCLUSIONS: From our whole genome sequencing we recovered an average genomic heterozygosity of 0.0037%, comparable to other lemurs. Our demographic history reconstructions recovered a probable climate-related decline (60-90,000 ybp), followed by a second population decrease following human colonization, which has reduced the species to a census size of approximately 1000 individuals. The historical distribution was likely a vast portion of Madagascar, minimally estimated at 44,259 km2, while the contemporary distribution is only ~ 1700 km2. The decline in effective population size of 89-99.9% corresponded to a vast range retraction. Conservation management of this species is crucial to retain genetic diversity across the remaining isolated populations.

Novel opsin gene variation in large-bodied, diurnal lemurs.

Some primate populations include both trichromatic and dichromatic (red-green colour blind) individuals due to allelic variation at the X-linked opsin locus. This polymorphic trichromacy is well described in day-active New World monkeys. Less is known about colour vision in Malagasy lemurs, but, unlike New World monkeys, only some day-active lemurs are polymorphic, while others are dichromatic. The evolutionary pressures underlying these differences in lemurs are unknown, but aspects of species ecology, including variation in activity pattern, are hypothesized to play a role. Limited data on X-linked opsin variation in lemurs make such hypotheses difficult to evaluate. We provide the first detailed examination of X-linked opsin variation across a lemur clade (Indriidae). We sequenced the X-linked opsin in the most strictly diurnal and largest extant lemur, Indri indri, and nine species of smaller, generally diurnal indriids (Propithecus). Although nocturnal Avahi (sister taxon to Propithecus) lacks a polymorphism, at least eight species of diurnal indriids have two or more X-linked opsin alleles. Four rainforest-living taxa-I. indri and the three largest Propithecus species-have alleles not previously documented in lemurs. Moreover, we identified at least three opsin alleles in Indri with peak spectral sensitivities similar to some New World monkeys.

Phylogenomic Reconstruction of Sportive Lemurs (genus Lepilemur) Recovered from Mitogenomes with Inferences for Madagascar Biogeography.

The family Lepilemuridae includes 26 species of sportive lemurs, most of which were recently described. The cryptic morphological differences confounded taxonomy until recent molecular studies; however, some species' boundaries remain uncertain. To better understand the genus Lepilemur, we analyzed 35 complete mitochondrial genomes representing all recognized 26 sportive lemur taxa and estimated divergence dates. With our dataset we recovered 25 reciprocally monophyletic lineages, as well as an admixed clade containing Lepilemur mittermeieri and Lepilemur dorsalis. Using modern distribution data, an ancestral area reconstruction and an ecological vicariance analysis were performed to trace the history of diversification and to test biogeographic hypotheses. We estimated the initial split between the eastern and western Lepilemur clades to have occurred in the Miocene. Divergence of most species occurred from the Pliocene to the Pleistocene. The biogeographic patterns recovered in this study were better addressed with a combinatorial approach including climate, watersheds, and rivers. Generally, current climate and watershed hypotheses performed better for western and eastern clades, while speciation of northern clades was not adequately supported using the ecological factors incorporated in this study. Thus, multiple mechanisms likely contributed to the speciation and distribution patterns in Lepilemur.

Aye-aye population genomic analyses highlight an important center of endemism in northern Madagascar.

We performed a population genomics study of the aye-aye, a highly specialized nocturnal lemur from Madagascar. Aye-ayes have low population densities and extensive range requirements that could make this flagship species particularly susceptible to extinction. Therefore, knowledge of genetic diversity and differentiation among aye-aye populations is critical for conservation planning. Such information may also advance our general understanding of Malagasy biogeography, as aye-ayes have the largest species distribution of any lemur. We generated and analyzed whole-genome sequence data for 12 aye-ayes from three regions of Madagascar (North, West, and East). We found that the North population is genetically distinct, with strong differentiation from other aye-ayes over relatively short geographic distances. For comparison, the average FST value between the North and East aye-aye populations--separated by only 248 km--is over 2.1-times greater than that observed between human Africans and Europeans. This finding is consistent with prior watershed- and climate-based hypotheses of a center of endemism in northern Madagascar. Taken together, these results suggest a strong and long-term biogeographical barrier to gene flow. Thus, the specific attention that should be directed toward preserving large, contiguous aye-aye habitats in northern Madagascar may also benefit the conservation of other distinct taxonomic units. To help facilitate future ecological- and conservation-motivated population genomic analyses by noncomputational biologists, the analytical toolkit used in this study is available on the Galaxy Web site.

Comparative and population mitogenomic analyses of Madagascar's extinct, giant 'subfossil' lemurs.

Humans first arrived on Madagascar only a few thousand years ago. Subsequent habitat destruction and hunting activities have had significant impacts on the island's biodiversity, including the extinction of megafauna. For example, we know of 17 recently extinct 'subfossil' lemur species, all of which were substantially larger (body mass ∼11-160 kg) than any living population of the ∼100 extant lemur species (largest body mass ∼6.8 kg). We used ancient DNA and genomic methods to study subfossil lemur extinction biology and update our understanding of extant lemur conservation risk factors by i) reconstructing a comprehensive phylogeny of extinct and extant lemurs, and ii) testing whether low genetic diversity is associated with body size and extinction risk. We recovered complete or near-complete mitochondrial genomes from five subfossil lemur taxa, and generated sequence data from population samples of two extinct and eight extant lemur species. Phylogenetic comparisons resolved prior taxonomic uncertainties and confirmed that the extinct subfossil species did not comprise a single clade. Genetic diversity estimates for the two sampled extinct species were relatively low, suggesting small historical population sizes. Low genetic diversity and small population sizes are both risk factors that would have rendered giant lemurs especially susceptible to extinction. Surprisingly, among the extant lemurs, we did not observe a relationship between body size and genetic diversity. The decoupling of these variables suggests that risk factors other than body size may have as much or more meaning for establishing future lemur conservation priorities.

Defining species in an advanced technological landscape.

The answer to the proffered question, "What is a species?" is considered one of the fundamental issues of biological science, as well as one of the most polarizing and sometimes acrimonious problems. Dozens of species concepts have been defined, but none are universal for implementation across all taxa. Within the past thirty years, the ability to analyze DNA data has progressed to the point that multiple methodologies can be simultaneously applied to the same evolutionary questions. The use of restriction fragment length polymorphisms, microsatellites, and mitochondrial (mtDNA) and nuclear DNA (nucDNA) sequence data has unarguably changed how we look at diversity and intensified the concept debate through the proliferation of species descriptions. Over the past two decades, Madagascar's biodiversity has gone through a tremendous taxonomic expansion by the elevation of subspecies to species and through novel descriptions, especially within the nocturnal lemurs. With the tremendous continuous loss of habitat, exponential human population growth, and stochastic changes predicted over coming decades, elucidating the earth's biodiversity will never be more important than now. Here, we examine species concepts and their attendant criteria. We predict how technological advances will alter, improve and, we hope, fully consolidate the unity of thoughts related to this central topic of evolutionary biology and its numerous interconnected disciplines.

Detection of cytonuclear genomic dissociation in the North American captive African elephant collection.

A total of 114 captive elephants (6 Asian; 108 African) from 43 private institutions or North American zoos accredited by the Association of Zoos and Aquariums were sampled and evaluated to investigate genetic status. Because previous analyses of the captive collection indicated potential cytonuclear dissociation between mitochondrial DNA (mtDNA) sequence and microsatellite nuclear DNA genotype data, we investigated this phenomenon within the captive collection with 2 X-linked genes (BGN and PHKA2) and 1 Y-linked gene (AMELY). These data reveal that individuals with forest-derived elephant mtDNA lineages carried only savannah elephant nuclear gene haplotypes. These results are concordant with a previous study of wild populations sampled across Africa, indicating that cytonuclear genomic dissociation was captured in the founders of the North American African elephant collection. These results are important for resolving questions that can potentially impact future management and breeding programs related to the collection.

Complete sequence and gene organization of the mitochondrial genome for Hubbard's sportive lemur (Lepilemur hubbardorum).

The complete mitochondrial DNA (mtDNA) genome of Hubbard's or Zombitse sportive lemur (Lepilemur hubbardorum) was generated by polymerase chain reaction (PCR) amplification, primer-walking sequencing and fragment cloning. Comparative analyses of Hubbard's sportive lemur were conducted with available complete mitochondrial genome sequences from eight other lemur species. The mitochondrial genome of Hubbard's sportive lemur is 16,854 base pairs (bp) and contains 13 protein-coding genes, 22 transfer RNA (tRNA) genes, two ribosomal RNA (rRNA) genes and one control region. Three rare start codons were found, in which GTG is the start codon for the ATPase 6 subunit gene (ATP), ATC for the NADH dehydrogenase (ND) 2 subunit gene, and ATT for the ND5 subunit gene. In the control region, sequence analysis found one repetitive unit between conserved sequence blocks (CSB)-1 and CSB-2 for L. hubbardorum. Comparative analysis of eight other lemur species showed different repetitive units between and outside of these two blocks. According to the phylogenetic analysis of the 12 heavy-strand encoded protein-coding genes, all nine lemur species representative of four lemuriformes families were monophyletic. This template and the newly designed primers described in this study will allow scientists to generate comparative sequences for all sportive lemurs to validate phylogenetic discrepancies in the genus Lepilemur and to evaluate evolutionary and biogeographic models.

Characterization of 21 microsatellites developed from Propithecus deckeni deckeni.

Decken's sifaka (Propithecus deckeni deckeni) is found between the Mahavavy and Manambolo Rivers, in western Madagascar. Twenty-one polymorphic nuclear microsatellite loci were isolated from genomic DNA derived from a P. d. deckeni, from Tsingy de Bemaraha National Park. Population genetic parameters were estimated on 10 individuals each, sampled from Tsingy de Bemaraha National Park and Tsiombikibo Classified Forests. Significant null alleles were detected in seven loci which were dropped before population genetic parameters were re-estimated and compared to the full marker suite.

Does Eulemur cinereiceps exist? Preliminary evidence from genetics and ground surveys in southeastern Madagascar.

Although appearing in the literature as early as 1890, the brown lemur form Eulemur cinereiceps has recently resurfaced as a potentially valid taxon, distinct from neighboring, presumably closely related species such as white-collared lemurs (Eulemur albocollaris). We propose two scenarios for the potential separation of E. cinereiceps and E. albocollaris: (1) coastal and interior populations represent two distinct taxa and (2) the coastal population north of the Manampatrana River (the locality for purported museum specimens of E. cinereiceps) represents a distinct species from E. albocollaris found south of the river and in the interior escarpment forests. We tested these hypotheses using data from ground surveys and genetic sampling. Surveys were conducted in coastal forest fragments both north and south of the Manampatrana River in July-August 2006. Genetic samples were collected at two coastal sites and one interior forest. We used maximum parsimony, maximum likelihood, and neighbor-joining analyses on mitochondrial DNA regions to determine if populations from different sites clustered into diagnosable clades. Results from field surveys confirmed the presence of forms commonly referred to as E. albocollaris at the two southern coastal forests; no consistent phenotypic differences across sites were observed. All genetic analyses yielded identical results: coastal and interior populations do not cluster into separate groups, thus rejecting the first hypothesis. Eulemur species and all other day-active lemurs have apparently been extirpated from coastal forests north of the Manampatrana. Owing to the absence of lemurs from the northern coastal localities, we could not conclusively support or reject the second scenario. However, based on examination of the original plates and museum specimens, as well as the biogeographic patterns typical of this region, we strongly suspect that all populations from this area belong to a single species. We conclude with remarks regarding the apparent priority of E. cinereiceps for this taxon.

[Cooperative effect of Spodoptera litura nuclear polyhedrosis virus with parasite wasp, Microplitis sp. on the S. litura larvae].

The relationship between the survival rate, developmental duration of Microplitis sp. in Spodoptera litura larvae and time of exposure of the host larvae to virus, the inoculation virus concentration were investigated to determined if parasites which emerged from virus-infected S. litura larvae had normal survive, and if the parasites could sever as the vector for S. litura nuclear polyhedrosis virus (SINPV). There was no significant difference in time that parasites spent in virus-infected larvae and healthy one, indicating the SINPV did not affect the developmental period of Microplitis sp. Parasite larvae in hosts exposed to virus after parasitization compmeted their development before their hosts died of virus infection. The proportion of parasites survived varied with the inoculation virus concentration and the time of exposure of the host larvae to virus, the percent of parasites survived increased as the time between host parasitization and host virus exposure increased, and decreased as the inoculation virus concentrations increased. The female parasites which developed or oviposited in virus-infected hosts, and manually contaminated the ovipositor of the females with virus suspension could all carry infective doses of the virus, and transmit virus from infected larvae to healthy one through ovipositor. A female parasite which developed or oviposited in virus-infected hosts transmitted infective doses of the virus to an average of 2.14, 2.45 healthy host larvae exposed to it respectively. A female parasite from the cocoon contaminated with SINPV of different virus concentration could transfer infective doses of the virus to an average of 1.45 healthy host larvae. A female parasite exposed to the mixture different virus concentration and 10% honey-water solution could also transmit virus to an average of 0.94 larva.