<Emphasis Type="Italic">Macaca munzala</Emphasis>: A New Species from Western Arunachal Pradesh,Northeastern India<Superscript>*</Superscript>

Macaca, comprising 20 well-characterized species, represents the largest and one of the most ecologically and socially diverse of all the nonhuman primate genera. We report the discovery of a macaque that is new to science from the high altitudes of western Arunachal Pradesh, a biodiversity-rich state in northeastern India. We propose the scientific name Macaca munzala and the vernacular name Arunachal macaque for the species. It shares morphological characteristics independently with the Assamese macaque (Macaca assamensis) and with the Tibetan macaque M. thibetana; like them, it appears to belong to the sinica species-group of the genus. However, the species is distinctive in relative tail length, which is intermediate between those of Tibetan and Western Assamese macaques, the subspecies with which it is sympatric. It is also unique in its altitudinal distribution, occurring largely at altitudes between 2000 and 3500 m. We provide a morphological characterization of the species, report preliminary data on its field biology and discuss possible taxonomic identity in relation to the other closely-related species of Macaca.^*This paper is dedicated to Dr. A. J. T. Johnsingh for his immense contributions to the study and conservation of India’s wildlife and for being an inspiration to a whole generation of students.     

Preliminary study of the genetic diversity of eastern Assamese macaques (Macaca assamensis assamensis) in Thailand based on mitochondrial DNA and microsatellite markers

Human overpopulation, deforestation, invasion of agricultural areas, and livestock are the primary causes for population fragmentation of wildlife. The distribution range of species of the genus Macaca is constantly decreasing and becoming increasingly fragmented due to forest deterioration. Assamese macaques (M. assamensis) are classified as near threatened in the International Union for Conservation of Nature (IUCN) Red List of Threatened Animals (2008) and have been declared a protected wildlife animal according to Wildlife Preservation and Protection Act, B.E.2535 (1992) of Thailand. As studies of the population history and genetic diversity of Assamese macaques in Thailand are currently lacking, we aimed at a first investigation of their genetic diversity based on mitochondrial DNA [hypervariable regions 1 and 2 (HV1, HV2) and cytochrome B (CYTB) regions], as well as 15 microsatellite markers of five sampling sites distributed across Thailand. Our results indicate that Assamese macaques in Thailand are diverse, with eight maternal haplotypes and a low inbreeding coefficient in the Phu Khieo Wildlife Sanctuary (PKWS) population. Moreover, our phylogenetic and median-joining network analysis based on mitochondrial (mt)DNA suggests a population distribution in accordance with the evolutionary scenario proposed for M. sinica. Today, the population of Assamese macaques is fragmented, and conservation strategies are needed to ensure the maintenance of genetic diversity of this primate species.     

Blood-protein allele frequencies and phylogenetic relationships in Macaca: A review

Allele-frequency data have been assembled for 35 blood-protein loci in 17 of 19 recognized species of Macaca based on 29 published electrophoretic studies; studies of inbred captive colonies have been excluded. Data for 22 polymorphic loci are tabulated in detail for 43 geographic populations of these species. Calculated F_ST values provide a measure of intergroup genetic differentiation at various hierarchical levels—troop, locality, province, country or island, species, species group; polymorphism indices measure genetic variation. The greatest intraspecific genetic differentiation occurs at the level of island populations within species. The pattern of genetic variation among island populations appears to be relictual, suggesting that the reduced genetic variability of island populations of macaques is a result of postisolation genetic drift rather than founder effect. Interspecific relationships were investigated by means of a jackknifed Fitch-Margoliash algorithm, using Papio as outgroup. Phylogenetic inferences based on morphology and zoogeography. The reduced genetic variability that frequently characterizes insular macaque populations complicates phylogenetic interpretation of blood-protein evidence.     

Genetic and evolutionary relationships among Asian Macaques

Published gene frequency data, checked for consistency of allele definitions across laboratories and for comparability of geographically identical samples, were pooled into a data set containing frequencies at nine loci for each of 20 populations that encompassed 10 macaque species. Genetic distances were calculated by the methods of Kidd and Cavalli-Sforza (1974). These distances were used to construct phylogenetic trees and to evaluate the relationships between divergence times and effective population sizes. Inter-and intraspecific genetic distances and the groupings defined by phenetic tree analyses support Fooden’s (1976) classification of the genus Macacainto four species groups. A paleozoogeographical model of Asia including the known times of major sea-level changes allows us to explain Macacainto four species groups. A paleozoogeographical model of Asia including the known times of major sea-level changes allows us to explain qualitatively the inferred evolutionary relationships among macaque species. Many assumptions are required in order to estimate the variables necessary in the quantitative prediction of genetic differences for a comparison between any two populations. Examination of those assumptions demonstrates the need for more accurate genetic as well as paleozoogeographic information. An erratum to this article is available at .     

Intraspecies variation in dominance style of Macaca fuscata

Knowledge of intraspecific variation is important to test the evolutionary basis of covariation in primate social systems, yet few reports have focused on it, even in the best-studied species of the Macaca genus. We conducted a comparative study of the dominance styles among three provisioned, free-ranging groups of Japanese macaques at Shodoshima Island, Takasakiyama Mountain and Shiga Heights, and collected standard data on aggressive and affiliative behavior during a period of 5 years. Our data in the Takasakiyama and Shiga groups support previous studies showing that Japanese macaques typically have despotic social relations; nevertheless, our data in the Shodoshima group are inconsistent with the norm. The social traits of Shodoshima monkeys suggested that: (1) their dominance style is neither despotic nor tolerant but is intermediate between the two traits; (2) some measures of dominance style, e.g., frequency and duration of social interactions, covary as a set of tolerant traits in Shodoshima monkeys. This study suggests broad intraspecific variation of dominance style in Japanese macaques as can be seen in some other primate species.     

Morphology of three new marine Frontonia species (Ciliophora; Peniculida) with note on the phylogeny of this genus

Members of the ciliate genus Frontonia are common colonizers of periphytic communities in aquatic biotopes. Recent studies indicate that their species diversity is higher than previously supposed. In this study the morphology and infraciliature of three new species, Frontonia sinica spec. nov., F. pusilla spec. nov., and F. elegans spec. nov., isolated from coastal waters of China, were investigated using live observation and silver impregnation methods. Frontonia sinica differs from its congeners by the following combination of characters: ellipsoidal body, about 116 somatic and five or six vestibular kineties, peniculi 1 and 2 four-rowed, peniculus 3 two-rowed, and a single contractile vacuole. Frontonia pusilla has about 72 somatic kineties, four-rowed peniculi 1 and 2, a two-rowed peniculus 3, and two contractile vacuoles. Frontonia elegans has 73 somatic kineties, four-rowed peniculi 1 and 2, a three-rowed peniculus 3, and two contractile vacuoles. In the present work, six new small-subunit rRNA gene sequences of six Frontonia species are used to construct the phylogenetic trees. Our phylogenetic analysis supports that the genus Frontonia may be paraphyletic. Meanwhile, no pattern of correlation could be found between the structures of peniculi and the phylogenetic relationships of Frontonia species in the present study.     

将安龙花转移至马蓝属(爵床科)的形态特征依据

比较了安龙花(Dyschoriste sinica H. S. Lo)的模式标本与距药花属(Dyschoriste Nees)和马蓝属(Strobilanthes Bl.)部分种类的花粉和花的特征后,支持将安龙花转移到马蓝属,组合为Strobilanthes sinica (H. S. Lo) Y. F. Deng。安龙花隶属于马蓝属黄猄草群,它与日本马蓝(Strobilanthes japonica (Thunb.) Miq.)近似,但区别在于它的匍匐习性,叶矩圆状椭圆形,近无柄,花单生叶腋。因此,距药花属(Dyschoriste Nees)在中国并没有分布。     

A mobile element based phylogeny of Old World monkeys

SINEs (Short INterspersed Elements) are a class of non-autonomous mobile elements that are <500 bp in length and have no open reading frames. Individual SINE elements are essentially homoplasy free with known ancestral states, making them useful genetic systems for phylogenetic studies. Alu elements are the most successful SINE in primate genomes and have been utilized for resolving primate phylogenetic relationships and human population genetics. However, no Alu based phylogenetic analysis has yet been performed to resolve relationships among Old World monkeys. Using both a computational approach and polymerase chain reaction display methodology, we identified 285 new Alu insertions from sixteen Old World monkey taxa that were informative at various levels of catarrhine phylogeny. We have utilized these elements along with 12 previously reported loci to construct a phylogenetic tree of the selected taxa. Relationships among all major clades are in general agreement with other molecular and morphological data sets but have stronger statistical support.     

Unity in diversity: Lessons from macaque societies

The macaque radiation is as old as the hominin radiation, approximately 7 million years. After Homo, Macaca has the widest geographical range among primates, and both of these genera are present in tropical and temperate regions as well. Whereas the single extant representative of the genus Homo diverged through processes of cultural diversification, extant species of macaques emerged through processes of evolutionary diversification. Macaque societies are characterized by profound unity and great diversity, and can best be described as variations on the same theme. To understand macaque variation and adaptation, we must take into account the processes that insure the persistence of their societies across generations and environments.     

The phenetic affinities of Rungwecebus kipunji

The kipunji, a recently discovered primate endemic to Tanzania's Southern Highlands and Udzungwa Mountains, was initially referred to the mangabey genus Lophocebus (Cercopithecinae: Papionini), but subsequent molecular analyses showed it to be more closely related to Papio. Its consequent referral to a new genus, Rungwecebus, has met with skepticism among papionin researchers, who have questioned both the robustness of the phylogenetic results and the kipunji's morphological distinctiveness. This circumstance has been exacerbated by the immaturity of the single available specimen (FMNH 187122), an M1-stage juvenile. Therefore, a geometric morphometric analysis of juvenile papionin cranial shape was used to explore the kipunji's phenetic affinities and evaluate morphological support for its separation from Lophocebus. Three-dimensional craniometric landmarks and semi-landmarks were collected on a sample of 124 subadult (dp4-M2 stage) cercopithecid crania. Traditional interlandmark distances were compared and a variety of multivariate statistical shape analyses were performed for the zygomaxillary region (diagnostic in mangabeys) and the cranium as a whole. Raw and size-adjusted interlandmark distances show the kipunji to have a relatively taller, shorter neurocranium and broader face and cranial base than is seen in M1-stage Lophocebus. Principal components and cluster analyses consistently unite the two Lophocebus species but group the kipunji with Cercocebus and/or Macaca. Morphological distances (Mahalanobis D²) between the kipunji and Lophocebus species are comparable to distances between recognized papionin genera. Discriminant function analyses suggest phenetic affinities between the kipunji and Cercocebus/Macaca and do not support the kipunji's classification to Lophocebus or to any other papionin taxon. In canonical plots, the kipunji occupies a region intermediate between macaques and African papionins or groups with Cercocebus, suggesting that it retains basal papionin shape characteristics. In shape comparisons among M1-stage papionins, the kipunji cranium is distinguished from Lophocebus by its relatively unrestricted suborbital fossa, more parasagittally oriented zygomatic arches, and longer auditory tube and from all papionins by its relatively tall, short neurocranium, broad face and cranial base, short nasals, dished nasal profile, and dorsally oriented rostrum. The kipunji is thus a cranially diagnosable phenon with a unique combination of cranial traits that cannot be accommodated within Lophocebus as currently defined. Based upon these results, Rungwecebus appears to be a valid and useful nomen that accurately reflects the morphological diversity of African papionins.     

Primate phylogenomics uncovers multiple rapid radiations and ancient interspecific introgression

Our understanding of the evolutionary history of primates is undergoing continual revision due to ongoing genome sequencing efforts. Bolstered by growing fossil evidence, these data have led to increased acceptance of once controversial hypotheses regarding phylogenetic relationships, hybridization and introgression, and the biogeographical history of primate groups. Among these findings is a pattern of recent introgression between species within all major primate groups examined to date, though little is known about introgression deeper in time. To address this and other phylogenetic questions, here, we present new reference genome assemblies for 3 Old World monkey (OWM) species: Colobus angolensis ssp. palliatus (the black and white colobus), Macaca nemestrina (southern pig-tailed macaque), and Mandrillus leucophaeus (the drill). We combine these data with 23 additional primate genomes to estimate both the species tree and individual gene trees using thousands of loci. While our species tree is largely consistent with previous phylogenetic hypotheses, the gene trees reveal high levels of genealogical discordance associated with multiple primate radiations. We use strongly asymmetric patterns of gene tree discordance around specific branches to identify multiple instances of introgression between ancestral primate lineages. In addition, we exploit recent fossil evidence to perform fossil-calibrated molecular dating analyses across the tree. Taken together, our genome-wide data help to resolve multiple contentious sets of relationships among primates, while also providing insight into the biological processes and technical artifacts that led to the disagreements in the first place.

Combining three newly sequenced primate genomes with other published genomes, this study adapts a little-known method for detecting ancient introgression to genome-scale data, revealing multiple previously unknown examples of hybridization between primate species.     

Analysis of genetic variability and relationships among Mentha L. using the limonene synthase gene, LS

The genus Mentha comprises a group of aromatic plants with worldwide distribution. Because of frequent interspecific hybridization, the genetic relationships within the genus are not clearly understood. Limonene synthase, which catalyses the first committed step in the essential oil monoterpene biosynthetic pathway, is considered to be a possible rate limiting enzyme. With the homology-based cloning method, primers were designed according to cDNA sequence to amplify full-length DNA sequences in 13 Mentha samples from five species, using Perilla as an outgroup. Analyses of gene structure, length variation, GC-content, Ts/Tv ratio and evolutionary diversity were carried out. Consensus phylogenetic trees were obtained using maximum likelihood, neighbor-joining, and maximum parsimony, respectively, based on the full-length genomic DNA sequences, complete ORF coding sequences and predicted amino acid sequences. The results presented here based on the sequence of MhLS provide the first credibly supported genetic relationships for Mentha, which enables a basis for further mint taxonomy, cultivation and breeding.     

Development of GEBRET: a web-based analysis tool for retroelements in primate genomes

Retroelements play important roles in primate evolution. Specifically, human endogenous retroviruses (HERVs) and Alu elements are primate-specific retroelements. In addition, SVA elements belong to the youngest family of hominid non-long terminal repeat (LTR) retrotransposons. Retroelements can affect adjacent gene expression, supplying cis-regulatory elements, splice sites, and poly-A signals. We developed a database, GEnome-wide Browser for RETroelement (GEBRET, http://neobio.cs.pusan.ac.kr/~gebre/), for comparing the distribution of primate-specific retroelements and adjacent genes. GEBRET database components include 47,381 HERVs, 53,924 Alus and 4639 SVAs in five primate genomes of human, chimpanzee, orangutan, rhesus macaque, and marmoset. Host genes located upstream of a retroelement were also visualized and classified as five categories (0.0, 0.5, 1.0, 2.0, and 3.0Kb). Our results suggest that retroelements preferentially integrate into the distal promoter region relative to the core promoter region. GEBRET database is designed to investigate the distribution of retroelements (HERVs, Alus and SVAs) in the primate genomes that have been sequenced. Our software will be useful in the field to study the impact of retroelements on primate genome evolution.     

Molecular Evidence for Distinct Genotypes of Monkey B Virus (Herpesvirus Simiae) Which Are Related to the Macaque Host Species

Although monkey B virus (herpesvirus simiae; BV) is common in all macaque species, fatal human infections appear to be associated with exposure to rhesus macaques (Macaca mulatta), suggesting that BV isolates from rhesus monkeys may be more lethal to nonmacaques than are BV strains indigenous to other macaque species. To determine if significant differences that would support this supposition exist among BV isolates, we compared multiple BV strains isolated from rhesus, cynomolgus, pigtail, and Japanese macaques. Antigenic analyses indicated that while the isolates were very closely related to one another, there are some antigenic determinants that are specific to BV isolates from different macaque species. Restriction enzyme digest patterns of viral DNA revealed marked similarities between rhesus and Japanese macaque isolates, while pigtail and cynomolgus macaque isolates had distinctive cleavage patterns. To further compare genetic diversity among BV isolates, DNA sequences from two regions of the viral genome containing genes that are conserved (UL27 and US6) and variable (US4 and US5) among primate alphaherpesviruses, as well as from two noncoding intergenic regions, were determined. From these sequence data and a phylogenetic analysis of them it was evident that while all isolates were closely related strains of BV, there were three distinct genotypes. The three BV genotypes were directly related to the macaque species of origin and were composed of (i) isolates from rhesus and Japanese macaques, (ii) cynomolgus monkey isolates, and (iii) isolates from pigtail macaques. This study demonstrates the existence of different BV genotypes which are related to the macaque host species and thus provides a molecular basis for the possible existence of BV isolates which vary in their levels of pathogenicity for nonmacaque species.     

Macaques as Seed Dispersal Agents in Asian Forests: A Review

The role of primates in seed dispersal is well recognized. Macaques (Macaca spp.) are major primate seed dispersers in Asia, and recent studies have revealed their role as seed dispersal agents in this region. Here, we review present knowledge of the traits that define the role of macaques as seed dispersers. The size of seeds in fruit influences whether macaques swallow (0.5–17.1 mm; median: 3.0), spit (1–37 mm; median: 7.6), or drop (8.2–57.7 mm; median: 20.5) them. Dispersal distances via defecation are several hundreds of meters (median: 259 m, range: 0–1300 m), shorter than those achieved by some mammals and birds in tropical and temperate regions. However, macaques disperse seeds by defecation at comparable distances to omnivorous carnivores, and further than passerines. Seed dispersal distance by spitting is much shorter (median: 20 m, range: 0–405 m) than by defecation. Among Asian primates, seed dispersal distances resulting from macaque defecation are shorter than those for gibbons and longer than those for langurs. The effects of seed ingestion on the percentage and speed of germination vary among both plant and macaque species. The degree of frugivory, fruit/seed handling methods, seed dispersal distance, microhabitats of dispersed seeds, and effects of dispersal on seed germination vary seasonally and interannually, and long-term studies of the ecological role of macaques are needed. Researchers have begun to assess the effectiveness of seed dispersal by macaques, secondary dispersal of seeds originally dispersed by macaques, and the effects of provisioning on seed dispersal. Future studies should also test the effects of social factors (such as age and rank), which have received little attention in studies of seed dispersal.     

Comparison of Y chromosome and mtDNA phylogenies leads to unique inferences of macaque evolutionary history

We report here the results of one of the first analyses to use male-specific nuclear markers in elucidating primate phylogenetic relationships at the intrageneric level. Two closely linked Y chromosome markers, TSPY and SRY, were sequenced for a total of 3100 bases. Forty-four macaques, representing 18 of the 19 recognized species, were sequenced for the full 3.1 kb, as was 1 individual from each of the following outgroup genera: Papio, Theropithecus, Mandrillus, Allenopithecus,Cercopithecus, Trachypithecus, Presbytis, and Homo. In contrast to recent mtDNA phylogenies, Y chromosome loci support four monophyletic species groups, including a sinica group containing M. arctoides-a classification largely congruent with those of Fooden and Delson. Comparison of mtDNA and Y chromosome phylogenies highlight (1) a potential hybrid origin of Macaca arctoides from M. fascicularis and proto-M. assamensis/thibetana and (2) cases of mitochondrial paraphyly in macaque species whose Y chromosome lineages are monophyletic-a probable evolutionary consequence of philopatric females vs dispersing males. These results raise the question of whether a phylogenetic tree should be a topology of species origins or a depiction of more current species relationships, including subsequent episodes of introgression.