Social Behavior of Captive Indochinese and Insular Long-Tailed Macaques (Macaca fascicularis) Following Transfer to a New Facility

There are measurable differences in behavior, physiology, social organization, and geographic distribution within and between various species of macaques. We collected information on the social behavior of captive Macaca fascicularis from Indochina and island populations after they had been transferred to a new environment and new social groups. While some changes in behavior occurred over time, we found no decrease in high levels of agonistic behaviors. We interpret this finding in light of previous research reporting that long-tailed macaques show low levels of habitatuation to novelty and are highly aroused in comparison to other macaque species. We found predictable differences in behavior for males, females, and infants, in which infants played more, females had higher levels of contact proximity to other individuals, and males exhibited more sexual and threat behavior. A comparison of social behavior in long-tailed macaques from different origins indicate that Indochinese macaques are generally less affiliative and Indochinese males are more aggressive than their insular counterparts. Differences among macaque species, and within the fascicularis-group, should be considered in management of captive colonies and when interpreting research data.     

Radiation and phylogeography in the Japanese macaque, Macaca fuscata

The Japanese macaque (Macaca fuscata) presumably differentiated from eastern rhesus macaque (Macaca mulatta) populations during the Pleistocene and the two species are closely related. In order to analyse speciation and subspeciation events in the Japanese macaque and to describe historical and current relationships among their populations, we sequenced and analysed a fragment of 392bp of mitochondrial DNA (mtDNA) control region in 50 individuals belonging to six populations of Japanese macaque and compared these sequences with 89 eastern rhesus macaque control region sequences from GenBank/EMBL database. There were high genetic similarities between both species and only two positions were fixed within each species, which supports the inclusion of the Japanese macaque in a single species with eastern populations of rhesus macaques. Japanese macaque ancestors colonised Japan after the separation of the two species, estimated at between 0.31 and 0.88 million years ago (Mya). The star-like phylogeny, multimodal mismatch distribution, and lack of correlation between geographic and genetic distances are in accordance with a rapid dispersion of macaques throughout the archipelago after the arrival into Japan. The species shows low genetic variation within populations and high levels of genetic differentiation among populations with no mtDNA haplotype shared across populations. Genetic distances between Yakushima macaques (Macaca fuscata yakui) and any other population of Macaca fuscata fuscata subspecies are comparable to the distances between populations of Honshu, Awajishima, and Kyushu, not supporting the classification of Yakushima macaques as a different subspecies.     

Six new species of the Anopheles leucosphyrus group, reinterpretation of An. elegans and vector implications

Abstract. Among Oriental anopheline mosquitoes (Diptera: Culicidae), several major vectors of forest malaria belong to the group of Anopheles (Cellia) leucosphyrus Dönitz. We have morphologically examined representative material (> 8000 specimens from seven countries) for taxonomic revision of the Leucosphyrus Group. Six new species are here described from adult, pupal and larval stages (with illustrations of immature stages) and formally named as follows: An. latens n. sp. (= An. leucosphyrus species A of Baimai et al., 1988b), An. cracens n. sp., An. scanloni n. sp., An. baimaii n. sp. (formerly An. dirus species B, C, D, respectively), An. mirans n. sp. and An. recens n. sp. Additionally, An. elegans (James) is redescribed and placed in the complex of An. dirus Peyton & Harrison (comprising An. baimaii, An. cracens, An. dirus, An. elegans, An. nemophilous Peyton & Ramalingam, An. scanloni and An. takasagoensis Morishita) of the Leucosphyrus Subgroup, together with An. baisasi Colless and the An. leucosphyrus complex (comprising An. balabacensis Baisas, An. introlatus Baisas, An. latens and An. leucosphyrus). Hence, the former Elegans Subgroup is renamed the Hackeri Subgroup (comprising An. hackeri Edwards, An. pujutensis Colless, An. recens and An. sulawesi Waktoedi). Distribution data and bionomics of the newly defined species are given, based on new material and published records, with discussion of morphological characters for species distinction and implications for ecology and vector roles of such species. Now these and other members of the Leucosphyrus Group are identifiable, it should be possible to clarify the medical importance and distribution of each species. Those already regarded as vectors of human malaria are: An. baimaii[Bangladesh, China (Yunnan), India (Andamans, Assam, Meghalaya, West Bengal), Myanmar, Thailand]; An. latens[Borneo (where it also transmits Bancroftian filariasis), peninsular Malaysia, Thailand]; probably An. cracens (Sumatra, peninsular Malaysia, Thailand); presumably An. scanloni (Thailand); perhaps An. elegans (the Western Ghat form of An. dirus, restricted to peninsular India); but apparently not An. recens (Sumatra) nor An. mirans[Sri Lanka and south-west India (Karnataka, Kerala, Tamil Nadu)], which is a natural vector of simian malarias. Together with typical An. balabacensis, An. dirus and An. leucosphyrus, therefore, the Leucosphyrus Group includes about seven important vectors of forest malaria, plus at least a dozen species of no known medical importance, with differential specific distributions collectively spanning > 5000 km from India to the Philippines.     

Cranial adaptation to a high attrition diet in Japanese macaques

Primates with diets that require greater occlusal forces to process exhibit anteroposteriorly shorter, vertically deeper faces, more anteriorly placed masseter attachment areas, and broader, taller mandibular corpora compared to closely related species/populations. Japanese macaques (Macaca fuscata)eat different, perhaps mechanically tougher to process, foods than other macaques do. Accordingly, they should exhibit structural features of the skull related to dissipating great occlusal loads. To test this hypothesis I compared cranial variables amongst wild-caught, adult female skulls (n = 85) of M. fuscataand three other macaque species (M. mulatta, M. fascicularis,and M. nemestrina)and applied least-squares and reduced-major-axis regression analysis and principal components analysis (PCA) to 17 cranial variables reflecting facial, vault, and mandibular dimensions. When scaled for size, the Japanese macaque has a vertically deeper and anteroposteriorly shorter face,a broader but not taller mandibular corpus, and a more anteriorly placed masseter muscle than the other three macaques do. The first PCA axis isolates variation due to a suite of characters related to mechanical efficiency in dissipating occlusal loads (vertically deep face and broad corpus) and differentiates the Japanese macaques from the other species. This, coupled with reported dietary differences among species, suggests that Japanese macaques are selected for dissipating greater occlusal loads than other macaques are. The presence of a narrow mandible relative to cranial breadth and a hyperrobust mandibular corpus width suggests that axial torsion is a significant influence in the masticatory regime of M. fuscata.The lack of an increase in corpus height indicates that parasagittal bending is not as significant an influence. Geographic and climatic influences cannot account for the patterns of variation between M. fuscataand the other macaques.     

Plasmodium knowlesi infecting humans in Southeast Asia: What’s next?

Plasmodium knowlesi, a simian malaria parasite, has been in the limelight since a large focus of human P. knowlesi infection was reported from Sarawak (Malaysian Borneo) in 2004. Although this infection is transmitted across Southeast Asia, the largest number of cases has been reported from Malaysia. The increasing number of knowlesi malaria cases has been attributed to the use of molecular tools for detection, but environmental changes including deforestation likely play a major role by increasing human exposure to vector mosquitoes, which coexist with the macaque host. In addition, with the reduction in human malaria transmission in Southeast Asia, it is possible that human populations are at a greater risk of P. knowlesi infection due to diminishing cross-species immunity. Furthermore, the possibility of increasing exposure of humans to other simian Plasmodium parasites such as Plasmodium cynomolgi and Plasmodium inui should not be ignored. We here review the current status of these parasites in humans, macaques, and mosquitoes to support necessary reorientation of malaria control and elimination in the affected areas.     

MHC class I characterization of Indonesian cynomolgus macaques

Cynomolgus macaques (Macaca fascicularis) are quickly becoming a useful model for infectious disease and transplantation research. Even though cynomolgus macaques from different geographic regions are used for these studies, there has been limited characterization of full-length major histocompatibility complex (MHC) class I immunogenetics of distinct geographic populations. Here, we identified 48 MHC class I cDNA nucleotide sequences in eleven Indonesian cynomolgus macaques, including 41 novel Mafa-A and Mafa-B sequences. We found seven MHC class I sequences in Indonesian macaques that were identical to MHC class I sequences identified in Malaysian or Mauritian macaques. Sharing of nucleotide sequences between these geographically distinct populations is also consistent with the hypothesis that Indonesia was a source of the Mauritian macaque population. In addition, we found that the Indonesian cDNA sequence Mafa-B7601 is identical throughout its peptide binding domain to Mamu-B03, an allele that has been associated with control of Simian immunodeficiency virus (SIV) viremia in Indian rhesus macaques. Overall, a better understanding of the MHC class I alleles present in Indonesian cynomolgus macaques improves their value as a model for disease research, and it better defines the biogeography of cynomolgus macaques throughout Southeast Asia.     

A targeted amplicon sequencing panel to simultaneously identify mosquito species and Plasmodium presence across the entire Anopheles genus

Anopheles is a diverse genus of mosquitoes comprising over 500 described species, including all known human malaria vectors. While a limited number of key vector species have been studied in detail, the goal of malaria elimination calls for surveillance of all potential vector species. Here, we develop a multilocus amplicon sequencing approach that targets 62 highly variable loci in the Anopheles genome and two conserved loci in the Plasmodium mitochondrion, simultaneously revealing both the mosquito species and whether that mosquito carries malaria parasites. We also develop a cheap, nondestructive, and high-throughput DNA extraction workflow that provides template DNA from single mosquitoes for the multiplex PCR, which means specimens producing unexpected results can be returned to for morphological examination. Over 1000 individual mosquitoes can be sequenced in a single MiSeq run, and we demonstrate the panel’s power to assign species identity using sequencing data for 40 species from Africa, Southeast Asia, and South America. We also show that the approach can be used to resolve geographic population structure within An. gambiae and An. coluzzii populations, as the population structure determined based on these 62 loci from over 1000 mosquitoes closely mirrors that revealed through whole genome sequencing. The end-to-end approach is quick, inexpensive, robust, and accurate, which makes it a promising technique for very large-scale mosquito genetic surveillance and vector control.     

NRAMP1 polymorphism in a hybrid population between Japanese and Taiwanese macaques in Wakayama, Japan

A macaque population produced by the hybridization of native Japanese macaques (Macaca fuscata) and introduced Taiwanese macaques (M. cyclopis) in Wakayama Prefecture was shown to possess three DNA haplotypes of the natural resistance-associated macrophage protein 1 (NRAMP1). Based on genotyping and comparison with M. fuscata populations, it was revealed that the introduced M. cyclopis population was polymorphic for the NRAMP1 locus. Extensive crossbreeding of the introduced species with the native species was confirmed using this genetic marker and the proportion of M. cyclopis genes was 57.4%. Results of statistical tests suggested non-random mating in the hybrid population.     

Habitat distribution and habitat preference in Barbary macaques (Macaca sylvanus)

Barbary macaques (Macaca sylvanus,L.) occur at varying densities in a number of different habitat types in Morocco and Algeria. Taub (1977) has argued that the abundance of the species in cedar forests of the Moyen Atlas, Morocco, is an indication of a habitat preference. A reexamination of available data on the distribution and abundance of Barbary macaques suggests that monkey numbers reflect the distribution of habitat size rather than habitat types. Differences between populations relative to habitat types can be seen only between forest and scrub localities. Human factors are considered more important in determining the present status of this eclectic feeder. The modern distribution of the Barbary macaque is inadequate evidence for a habitat preference.     

Characterization of 47 MHC class I sequences in Filipino cynomolgus macaques

Cynomolgus macaques (Macaca fascicularis) provide increasingly common models for infectious disease research. Several geographically distinct populations of these macaques from Southeast Asia and the Indian Ocean island of Mauritius are available for pathogenesis studies. Though host genetics may profoundly impact results of such studies, similarities and differences between populations are often overlooked. In this study we identified 47 full-length MHC class I nucleotide sequences in 16 cynomolgus macaques of Filipino origin. The majority of MHC class I sequences characterized (39 of 47) were unique to this regional population. However, we discovered eight sequences with perfect identity and six sequences with close similarity to previously defined MHC class I sequences from other macaque populations. We identified two ancestral MHC haplotypes that appear to be shared between Filipino and Mauritian cynomolgus macaques, notably a Mafa-B haplotype that has previously been shown to protect Mauritian cynomolgus macaques against challenge with a simian/human immunodeficiency virus, SHIV_89.6P. We also identified a Filipino cynomolgus macaque MHC class I sequence for which the predicted protein sequence differs from Mamu-B*17 by a single amino acid. This is important because Mamu-B*17 is strongly associated with protection against simian immunodeficiency virus (SIV) challenge in Indian rhesus macaques. These findings have implications for the evolutionary history of Filipino cynomolgus macaques as well as for the use of this model in SIV/SHIV research protocols. Kevin J. Campbell and Ann M. Detmer contributed equally to this work.     

Species and geographic distribution patterns of the macaque prealbumin polymorphism

A polymorphism for thyroxine-binding prealbumin (TBPA) is investigated in regards to mode of inheritance as well as distribution within eight species of macaques from known geographic areas. It is found that an electrophoretically slow variant seems to be due to a codominant allele present in six of the species tested.While the slow form has a frequency of less than 30% in most other populations tested, it is fixed at 100% in the Japanese macaques (M. fuscata). The locus is inHardy-Weinberg equilibrium in all populations however. Since TBPA is intimately related to thyroxine levels in the blood the polymorphism may be an adaptation to cold environments.     

A Large‐Scale SNP‐Based Genomic Admixture Analysis of the Captive Rhesus Macaque Colony at the California National Primate Research Center

Some breeding facilities in the United States have crossbred Chinese and Indian rhesus macaque (Macaca mulatta) founders either purposefully or inadvertently. Genetic variation that reflects geographic origins among research subjects has the potential to influence experimental outcomes. The use of animals from different geographic regions, their hybrids, and animals of varying degrees of kinship in an experiment can obscure treatment effects under study because high interanimal genetic variance can increase phenotypic variance among the research subjects. The intent of this study, based on a broad genomic analysis of 2,808 single nucleotide polymorphisms (SNPs), is to ensure that only animals estimated to be of pure Indian or Chinese ancestry, based on both demographic and genetic information, are used as sources of infants for derivation and expansion of the California National Primate Research Center's (CNPRC) super‐Specific Pathogen Free (SSPF) rhesus macaque colony. Studies of short tandem repeats (STRs) in Indian and Chinese rhesus macaques have reported that heterozygosity of STRs is higher in Chinese rhesus macaques than in Indian rhesus macaques. The present study shows that heterozygosity of SNPs is actually higher in Indian than in Chinese rhesus macaques and that the Chinese SSPF rhesus macaque colony is far less differentiated from their founders compared to the Indian‐origin animals. The results also reveal no evidence of recent gene flow from long‐tailed and pig‐tailed macaques into the source populations of the SSPF rhesus macaques. This study indicates that many of the long‐tailed macaques held in the CNPRC are closely related individuals. Most polymorphisms shared among the captive rhesus, long‐tailed, and pig‐tailed macaques likely predate the divergence among these groups. Am. J. Primatol. 74:747‐757, 2012. © 2012 Wiley Periodicals, Inc.     

Abundance and Morphology of Japanese Mulberry Trees in Response to the Distribution of Japanese Macaques in Snowy Areas

One of the rare documented cases of an antagonistic primate–plant interaction is selective foraging by Japanese macaques (Macaca fuscata) on the bark or buds of Japanese mulberry trees (Morus bombycis) in cool-temperate forests. We examined how this selective foraging behavior influences the growth and development of mulberry trees in a large geographic space with different environmental conditions by selecting study areas in northern Japan. We found that the foraging caused potentially fatal damage to 5%–10% of the mulberry trees and led to dwarfing of the tree morphology. However, the stem density of the monitored mulberry trees was the highest in the area with a long history of occupancy by macaque groups; moreover, the foraging commonly resulted in compensatory plant growth by increasing shoot number. These findings indicate that the macaque–mulberry relationship is not always antagonistic. Sufficient snow cover could be a key environmental factor to establish this non-antagonistic interaction by suppressing the negative influence of macaques as a destructive herbivore and improving their positive influence as a skilful gardener. Finally, we performed decision tree modeling based on the J48 algorithm to investigate geographic variation in mulberry abundance and morphology in response to the distribution of macaques. We developed an explicit tree model with reasonable predictive performance that not only enables a better understanding of primate–plant interactions but also provides information regarding the time of occupancy by Japanese macaques in a given area based on the abundance and morphology of mulberry trees. This result indicated that the observation of preferred tree species could be an indirect measure that reliably indexes macaque habitat use.     

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.     

Whole‐genome sequencing reveals absence of recent gene flow and separate demographic histories for Anopheles punctulatus mosquitoes in Papua New Guinea

Anopheles mosquitoes are the vectors of several human diseases including malaria. In many malaria endemic areas, several species of Anopheles coexist, sometimes in the form of related sibling species that are morphologically indistinguishable. Determining the size and organization of Anopheles populations, and possible ongoing gene flow among them is important for malaria control and, in particular, for monitoring the spread of insecticide resistance alleles. However, these parameters have been difficult to evaluate in most Anopheles species due to the paucity of genetic data available. Here, we assess the extent of contemporary gene flow and historical variations in population size by sequencing and de novo assembling the genomes of wild‐caught mosquitoes from four species of the Anopheles punctulatus group of Papua New Guinea. Our analysis of more than 50 Mb of orthologous DNA sequences revealed no evidence of contemporary gene flow among these mosquitoes. In addition, investigation of the demography of two of the An. punctulatus species revealed distinct population histories. Overall, our analyses suggest that, despite their similarities in morphology, behaviour and ecology, contemporary sympatric populations of An. punctulatus are evolving independently.     

Morphometric analysis ofMacaca arctoides andM. thibetana in relation to other macaque species

As a first step in reviewing the classification of the two stump-tailed macaque species,Macaca arctoides andM. thibetana, as compared with other species of the genusMacaca, 72 linear dental and cranial variables of 11 macaque species were examined by morphometric analyses. The results indicate that the two stump-tailed species are the largest of the macaques and although rather similar overall, they exhibit significant differences in the pattern of variation in most of the five skull regions as shown by Principal Components and Canonical Variate Analyses. Euclidean Distances based on Canonical Variate scores indicate that the females ofM. arctoides andM. thibetana are more widely separated than eight other pairs of macaque species, and that the separations of the respective males are greater than those of three other pairs of species. These findings are consistent withFooden's classification of the stump-tailed macaques as two separate species (Fooden, 1976;Fooden et al., 1985). The present results suggest, as other researchers have proposed on the basis of external features, biochemistry and genetics, that the two stump-tailed macaque species andM. assamensis are closely related. The results also tentatively imply associations withM. fuscata andM. sylvanus but these require further study. The findings have implications for the assessment of the various Chinese Pleistocene macaque fossils.     

Morphological and Body Color Variation in Thai <Emphasis Type="Italic">Macaca fascicularis fascicularis</Emphasis> North and South of the Isthmus of Kra

Long-tailed macaques (Macaca fascicularis fascicularis) are widely distributed in Southeast Asia and are morphologically and genetically (Tosi et al. in International Journal of Primatology 23:161–178, 2002) distinguishable on either side of the Isthmus of Kra (ca. 10.5°N). We compared the somatometry and body color of 15 local populations of long-tailed macaques in Thailand distributed over areas from 6.5°N to 16.3°N and also a Thai rhesus macaque population at 17.2°N. Limb proportions and body color variation follow the geographical trend. However, contrary to a previous report, body size does not decrease with latitude in the northern group and also in the southern (southerly distributed) rhesus macaque. Relative tail length (RTL) and color contrast in yellow between the back and thigh are the sole traits that distinctively separate the 2 groups: the southern group has a long relative tail length (RTL >125%) and small color contrast, whereas the northern group has a short RTL (<120%) and large color contrast. The southern rhesus macaques appear to have somatometric and body color traits that follow the geographical trend in long-tailed macaques, though they maintain their distinctive species-specific traits of shorter RTL (ca. 55%), shorter relative facial length, and a bipartite body color pattern. Researchers assume that the northern group of long-tailed macaques and the southern rhesus macaques had undergone partial introgression with each other. Montane refugia present during the glacial period are localities in which introgression occurred in long-tailed macaques.     

Secondary contact and genomic admixture between rhesus and long‐tailed macaques in the Indochina Peninsula

Understanding the process and consequences of hybridization is one of the major challenges in evolutionary biology. A growing body of literature has reported evidence of ancient hybridization events or natural hybrid zones in primates, including humans; however, we still have relatively limited knowledge about the pattern and history of admixture because there have been little studies that simultaneously achieved genome‐scale analysis and a geographically wide sampling of wild populations. Our study applied double‐digest restriction site‐associated DNA sequencing to samples from the six localities in and around the provisional hybrid zone of rhesus and long‐tailed macaques and evaluated population structure, phylogenetic relationships, demographic history, and geographic clines of morphology and allele frequencies. A latitudinal gradient of genetic components was observed, highlighting the transition from rhesus (north) to long‐tailed macaque distribution (south) as well as the presence of one northern population of long‐tailed macaques exhibiting unique genetic structure. Interspecific gene flow was estimated to have recently occurred after an isolation period, and the migration rate from rhesus to long‐tailed macaques was slightly greater than in the opposite direction. Although some rhesus macaque‐biased alleles have widely introgressed into long‐tailed macaque populations, the inflection points of allele frequencies have been observed as concentrated around the traditionally recognized interspecific boundary where morphology discontinuously changed; this pattern was more pronounced in the X chromosome than in autosomes. Thus, due to geographic separation before secondary contact, reproductive isolation could have evolved, contributing to the maintenance of an interspecific boundary and species‐specific morphological characteristics.     

Male–Male Relationships in Lion-tailed Macaques (<Emphasis Type="Italic">Macaca silenus</Emphasis>) and Bonnet Macaques (<Emphasis Type="Italic">Macaca radiata</Emphasis>)

Socioecology suggests that female distribution in space is determined by the distribution of food resources and the male distribution is influenced by female distribution. Though studies have traditionally focused on females, males have received increasing attention in recent years. We compared male–male relationships in lion-tailed macaques and bonnet macaques. Because bonnet macaques have a high adult male:female sex ratio and are seasonal breeders whereas lion-tailed macaques have a low adult male:female sex ratio and are largely aseasonal breeders, we predicted that bonnet macaque males would be spatially and socially more tolerant of each other and would have less linear dominance relationships than lion-tailed macaques. We recorded male–male and male–female relationships in 1 group of wild macaques of each species via scan sampling and 1–0 sampling. The results revealed that lion-tailed macaque males largely remained at a distance from each other whereas bonnet macaque males remained in close proximity to one another. Lion-tailed macaque males were more agonistic toward each other whereas bonnet macaque males showed more affiliative interactions. The dominance hierarchy among lion-tailed macaque males was more linear than among bonnet macaque males. Our data support the hypothesis that the study of spatial structuring, temporality of interactions, and linearity of social relationships may contribute to a better understanding of macaque social systems.     

Distribution and Abundance of Primates in Rain Forests of the Western Ghats,Karnataka, India and the Conservation of Macaca silenus

We assessed the distribution and abundance of 4 species of diurnal primates viz. lion-tailed macaque, bonnet macaque, Nilgiri langur and Hanuman langur, in 2 areas—Brahmagiri-Makut and Sirsi-Honnavara—in rain forests of the Western Ghats in the state of Karnataka, India. The Nilgiri langurs in Brahmagiri-Makut and the lion-tailed macaques in Sirsi-Honnavara are the northernmost populations of the 2 species in the Western Ghats. The 2 regions represent changes in ecological zones in the Western Ghats. In Brahmagiri-Makut, Hanuman langurs and bonnet macaques occupy lower elevations whereas Nilgiri langurs live in relatively higher altitudes. Only one group of lion-tailed macaques was in Brahmagiri-Makut. In the forests of Sirsi-Honnavara, 3 species of primates viz. lion-tailed macaque, bonnet macaque and Hanuman langur were in larger numbers throughout the forest. A self-sustainable single population of 32 groups of lion-tailed macaques occurred in Sirsi-Honnavara. Few subspecies of Hanuman langurs exist in the study regions. Due to local hunting practices, the relative abundance of primates in Brahmagiri-Makut is lower than that in Sirsi-Honnavara.