Dietary composition and niche partitioning of sympatric carnivores in Altun Mountain National Nature Reserve

doi:10.16829/j.slxb.150941

Abstract

Abstract: Comparing the diet of sympatric carnivorous species can reveal their differences and degree of overlap in resource utilization, which is an important approach to understanding the interactions among species and the stability of ecosystems. This study analyzes the species identification, dietary composition, similarity, and niche overlap of 338 scat samples collected in the Altun Mountains Nature Reserve using DNA metabarcoding technology. Eight carnivorous species were identified, including snow leopard (Panthera uncia), Eurasian lynx (Lynx lynx), wolf (Canis lupus), dhole (Cuon alpinus), red fox (Vulpes vulpes), Tibetan fox (V. ferrilata), brown bear (Ursus arctos), and stone marten (Martes foina). A total of 11 orders and 22 prey species were identified, with Cetartiodactyla (36. 59%) and Lagomorpha (24. 39%) having higher relative frequency of occurrence in the carnivorous species diet at order level. Blue sheep (Pseudois nayaur) was the most frequently detected prey species in the Cetartiodactyla order, and woolly hares (Lepus oiostolus) were the most frequently detected prey species in the Lagomorpha order. At the species level, Kiang (Equus kiang) was the most frequently detected prey species among all food categories, accounting for 20. 12% of the carnivorous species diet. Among carnivore species, brown bear and wolf had the highest dietary overlap (O_jk= 0. 797), followed by snow leopard and dhole (O_jk= 0. 764), indicating a competitive relationship in the utilization of food resources, while Tibetan fox and red fox had relatively low dietary overlap. In this study, the dietary composition and niche partitioning of carnivores in Altun Mountain National Nature Reserve were obtained, which is helpful to better understand the relationship of competition and coexistence between different species and provide scientific basis for species conservation.

Key words: Nutritional niche, Interspecific competition, Species identification, Dietary composition, DNA metabarcoding

摘要： 比较同域食肉目动物的食性能够揭示它们在资源利用上的差异和重叠程度，是了解物种间相互作用和生态系统稳定性的重要途径。本研究利用DNA宏条形码技术，对在阿尔金山国家级自然保护区内收集的338份食肉目动物粪便样品进行物种鉴定及食性组成、相似性和营养生态位重叠分析。结果共鉴定出8种食肉目动物，分别为雪豹(Panthera uncia)、猞猁(Lynx lynx)、狼(Canis lupus)、豺(Cuon alpinus)、赤狐(Vulpes vulpes)、藏狐(V.fer-rilata)、棕熊(Ursus arctos)和石貂(Martes foina)。共鉴定出11目22种猎物，其中鲸偶蹄目(36.59%)和兔形目(24.39%)在食肉目动物食谱中出现频率最高，岩羊(Psuedois nayaur)是鲸偶蹄目中相对出现频率最高的物种，灰尾兔(Lepus oiostolus)是兔形目中相对出现频率最高的物种。藏野驴(Equus kiang)是相对出现频率最高的猎物，占食肉目动物食谱的20.12%。在不同食肉目动物物种间，棕熊与狼食性重叠最高(O_jk=0.797)，其次是雪豹与豺(O_jk=0.764)，表明这些物种间存在明显的食物资源竞争；而藏狐和赤狐等物种间的食性重叠相对较低，表明这些物种间可能形成了营养生态位分化。本研究掌握了阿尔金山国家级自然保护区食肉目动物的食性组成及其营养生态位分化，有助于更好地理解不同物种间的竞争和共存关系，并为物种保护提供科学依据。

关键词: 营养生态位, 种间竞争, 物种鉴定, 食性组成, DNA宏条形码

CLC Number:

Q346

CONG Wei, ZHANG Yi, HUANG Taifu, LI Jia, XU Junquan, ZHANG Shengfa, LI huan, XUE Yadong, ZHANG Yuguang. Dietary composition and niche partitioning of sympatric carnivores in Altun Mountain National Nature Reserve[J]. ACTA THERIOLOGICA SINICA, 2024, 44(6): 695-705.

丛微, 张溢, 黄太福, 李佳, 徐俊泉, 张圣发, 李欢, 薛亚东, 张于光. 阿尔金山国家级自然保护区同域食肉目动物的食性组成和营养生态位分化[J]. 兽类学报, 2024, 44(6): 695-705.

References

Akrim F, Mahmood T, Max T, Nadeem M S, Qasim S, Andleeb S. 2018. Assessment of bias in morphological identification of carnivore scats confirmed with molecular scatology in north-eastern Himalayan region of Pakistan. PeerJ, 2018 (6). DOI：10. 7717/peerj. 5262.
Andersen G E, Johnson C N, Jones M E. 2020. Space use and temporal partitioning of sympatric Tasmanian devils and spottedtailed quolls. Austral Ecology, 45 (3): 355-365.
Aryal A, Panthi S, Barraclough R K, Bencini R, Adhikari B, Ji W H, Raubenheimer D. 2015. Habitat selection and feeding ecology of dhole (Cuonalpinus) in theHimalayas. Journal of Mammalogy, 96 (1): 47-53.
Bassi E, Donaggio E, Marcon A, Scandura M, Apollonio M. 2012.Trophic niche overlap and wild ungulate consumption by red fox and wolf in a mountain area in Italy. Mammalian Biology, 77:369-376.
Castañeda I, Doherty T S, Fleming P A, Stobo-Wilson A M, Woinarski J C Z, Newsome T M. 2022. Variation in red fox Vulpes vulpes diet in five continents. Mammal Review, 52 (3): 328-342.
Costa-Pereira R, Araújo M S, Souza F L, Ingram T. 2019. Competition and resource breadth shape niche variation and overlap in multiple trophic dimensions. Proceedings of the Royal Society BBiological Sciences, 286 (1902). DOI: 10.1098/rspb.2019.0369.
Cui L Y, Liu B Y, Li H M, Zhu Y X, Zhou Y H, Su C, Tian Y P, Xu H T, Liu D, Li X P, Ma Y, Jiang G S, Liu H, Yang S H, Lan T M, Xu Y C. 2024. A simple and effectivemethod to enrich endogenous DNA from mammalian faeces. Molecular Ecology Resources, 24(4). DOI: 10. 1111/1755-0998. 13939.
Dai Y C, Hacker C E, Cao Y, Cao H N, Xue Y D, Ma X D, Liu H D, Zahoor B, Zhang Y G, Li D Q. 2021. Implementing a comprehensive approach to study the causes of human-bear (Ursus arctos pruinosus) conflicts in the Sanjiangyuan region, China. Science of the Total Environment, 772. DOI： 10. 1016/j. scitotenv. 2021. 145012.
Deagle B E, Thomas A C, McInnes J C, Clarke L J, Vesterinen E J, Clare E L, Kartzinel T R, Eveson J P. 2019. Counting with DNA in metabarcoding studies: How should we convert sequence reads to dietary data? Molecular Ecology, 28 (2): 391-406.
Donadio E, Buskirk S W. 2006. Diet, morphology, and interspecific killing in carnivora. The American Naturalist, 167 (4): 524-536.
Dong S K, Wu X Y, Liu S L, Su X K, Wu Y, Shi J B, Li X W, Zhang X, Xu D H, Weng J. 2015. Estimation of ecological carrying capacity for wild yak, kiang, and Tibetan antelope based on habitat suitability in the Aerjin Mountain Nature Reserve, China. Acta Ecologica Sinica, 35 (23): 7598-7607. (in Chinese)
Du Preez B, Purdon J, Trethowan P, Macdonald D W, Loveridge A J. 2017. Dietary niche differentiation facilitates coexistence of two large carnivores. Journal of Zoology, 302 (8): 4906-4916.
Elmeros M, Mikkelsen D M G, Nørgaard L S, Pertoldi C, Jensen T H, Chriél M. 2018. The diet of feral raccoon dog (Nyctereutes procyonoides) and native badger (Meles meles) and red fox (Vulpes vulpes) in Denmark. Mammal Research, 63: 405-413.
Gehrt S D, Clark W R. 2003. Raccoons, coyotes, and reflections on the mesopredator release hypothesis. Wildlife Society Bulletin(1973-2006), 31 (3): 836-842.
Hacker E C, Cong W, Xue Y D, Li J, Zhang Y, Wu L J, Ji Y R, Dai Y C, Li Y, Jin L X, Li D Q, Zhang J Y, Janecka J E, Zhang Y G. 2022. Dietary diversity andniche-partitioning of carnivores across the Qinghai-Tibetan Plateau of China using DNA metabarcoding. Journal of Mammalogy, 103 (5): 1005-1018.
Hacker C E, Jevit M, Hussain S, Muhammad G, Munkhtsog B, Munkhtsog B, Zhang Y G, Li D Q, Liu Y L, Farrington D J, Balbakova F, Alamanov A, Kurmanaliev A, Buyanaa C, Bayandonoi G, Ochirjav M, Liang X C, Bian X X, Weckworth B, Jackson R, Janecka J E. 2021. Regional comparison of snow leopard (Panthera uncia) diet using dna metabarcoding. Biodiversity and Conservation, 30: 797-817.
Harris R, Jiake Z, Ji Y Q, Zhang K, Yang Y C, Douglas Y D. 2014.Evidence that the Tibetan fox is an obligate predator of the plateau pika: Conservation implications. Journal of Mammalogy, 95(6): 1207-1221.
Hayward M W, Lyngdoh S, Habib B. 2014. Diet and prey preferences of dholes (Cuon alpinus): dietary competition within Asia’s apex predator guild. Journal of Zoology, 294 (4): 255-266.
Jumaba-Uulu K, Wegge P, Mishra C, Sharma K. 2014. Large carnivores and low diversity of optimal prey: a comparison of the diets of snow leopards Panthera uncia and wolves Canis lupus in Sarychat-Ertash Reserve in Kyrgyzstan. Oryx, 48 (4): 529-535.
Kamler J F, Stenkewitz U, Klare U, Jacobsen N F, Macdonald D W. 2012. Resource partitioning among cape foxes, bat-eared foxes, and black backed jackals in South Africa. Journal of Wildlife Management, 76 (6): 1241-1253.
Kamler J F, Thatdokkham K, RostroGarcía S, Bousa A, Caragiulo A, Crouthers R, In V, Pay C, Pin C, Prum S, Vongkhamheng C, Johnson A, Macdonald D W. 2020. Diet and prey selection of dholes in evergreen and deciduous forests of southeast Asia. Journal of Wildlife Management, 84 (7): 1396-1405.
Karanth K U, Srivathsa A, Vasudev D, Puri M, Parameshwaran R, Kumar N S. 2017. Spatio-temporal interactions facilitate large carnivore sympatry across a resource gradient. Proceeding of the Royal Society B: Biological Science, 284 (1848). DOI：10. 1098/rspb. 2016. 1860.
Lanszki J, Heltai M, Kövér G, Zalewski A. 2019. Non-linear relationship between body size of terrestrial carnivores and their trophic niche breadth and overlap. Basic and Applied Ecology, 38:36-46.
Li Z L, Duo L A, Li S, Wang T M. 2021. Competition and coexistence among terrestrial mammalian carnivores. Biodiversity Science, 29 (1): 81-97. (in Chinese)
Li Z L, Lu J Y, Shi X Y, Duo L A, Smith J L D, Wang T M. 2024.Competitive interactions and coexistence of sympatric flagship carnivores in Asia. Integrative Zoology, 19 (2): 183-199.
Liu Q R. 2018. Atlas of wildlife in Altun Mountain National Nature Reserve. China Environmental Publishing Group. (in Chinese)
Lu Q, Cheng C, Xiao L Y, Li J, Li X Y, Zhao X, Lu Z, Zhao J D, Yao M. 2023. Food webs reveal coexistence mechanisms and community organization in carnivores. Current Biology, 33 (4):647-659.
Lu Q, Hu Q, Shi X G, Jin S L, Li S, Yao M. 2019. Metabarcoding diet analysis of snow leopards (Panthera uncia) in Wolong National Nature Reserve, Sichuan Province. Biodiversity Science, 27 (9):960-969. (in Chinese)
Manlick P J, Pauli J N. 2020. Human disturbance increases trophic niche overlap in terrestrial carnivore communities. Proceedings of the National Academy of Sciences of the United States of America, 117 (43): 26842-26848.
Mengüllüoğlu D, Ambarli H, Berger A, Hofer H. 2018. Foraging ecology of Eurasian lynx populations in southwest Asia: conservation implications for a diet specialist. Ecology and Evolution, 8 (18):9451-9463.
Nawaz M A, Valentini A, Khan N K, Miquel C, Taberlet P, Swenson J E. 2019. Diet of the brown bear in Himalaya: combining classical and molecular genetic techniques. PLoS ONE, 14 (12). DOI： 10. 1371/journal. pone. 0225698.
Newmaster S G, Thompson I D, Steeves R A D, Rodgers A R, Fazekas A J, Maloles J R, McMullin R T, Fryxell J M. 2013. Examination of two new technologies to assess the diet of woodland caribou:video recorders attached to collars and DNA barcoding. Canadian Journal of Forest Research, 43 (10): 897-900.
Oksanen J, Blanchet F G, Friendly M, Kindt R, Legendre P, Minchin P R, O’Hara B, Simpson G L, Solymos P, Stevens H, Wagner H H. 2019. vegan: Community Ecology Package.
Paradis E, Schliep K. 2019. Ape 5. 0: an environment for modern phylogenetics and evolutionary analyses in R. Bioinformatics, 35 (3):526-528.
Pastore A I, Barabás G, Bimler M D, Mayfield M M, Miller T E. 2021. The evolution of niche overlap and competitive differences. Nature Ecology Evolution, 5 (3): 330-337.
Pianka E R. 1971. Ecology of the Agamid Lizard Amphibolurus isolepis in Western Australia. Copeia 1971, 527.
Pokheral C P, Wegge P. 2019. Coexisting large carnivores: spatial relationships of tigers and leopards and their prey in a prey-rich area in lowland Nepal. Ecoscience, 26 (2): 1-9.
Pompanon F, Deagle B E, Symondson W O C, Brown D S, Jarman S N, Taberlet P. 2012. Who is eating what: diet assessment using next generation sequencing. Molecular Ecology, 21 (8): 1931-1950.
Riaz T, Shehzad W, Viari A, Pompanon F, Taberlet P, Coissac É. 2011.EcoPrimers: Inference of new DNA barcode markers from whole genome sequence analysis. Nucleic Acids Research, 39 (21).DOI：10. 1093/nar/gkr732.
Ripple W J, Estes J A, Beschta R L, Wilmers C C, Ritchie E G, Hebblewhite M, Berger J, Elmhagen B, Letnic M, Nelson P E, Schmitz J O, Smith D W, Wallach D A, Wirsing J A. 2014. Status and ecological effects of the world’s largest carnivores. Science, 343(6167). DOI：10. 1126/science. 1241484.
Rodríguez-Luna C R, Servín J, Valenzuela-Galván D, List R. 2021.Trophic niche overlap between coyotes and gray foxes in a temperate forest in Durango, Mexico. PLoS ONE, 16 (12). DOI： 10. 1371/journal. pone. 0260325.
Schoener T W. 1974. Resource partitioning in ecological communities. Science, 185 (4145): 27-39.
Shao X N, Lu Q, Xiong M Y, Bu H L, Shi X Y, Wang D J, Zhao J D, Li S, Yao M. 2021. Prey partitioning and livestock consumption in the world’s richest large carnivoreassemblage. Current Biology, 31 (22): 4887-4897.
Shao X N, Song D Z, Huang Q W, Li S, Yao M. 2019. Fast surveys and molecular diet analysis of carnivores based on fecal DNA and metabarcoding. Biodiversity Science, 27 (5): 543-556. (in Chinese)
Shi Y, Hoareau Y, Reese E M, Wasser S K. 2021. Prey partitioning between sympatric wild carnivores revealed by DNA metabarcoding: a case study on wolf (Canis lupus) and coyote (Canis latrans)in northeastern Washington. Conservation Genetics, 22:293-305.
Shrestha B, Aihartza J, Kindlmann P. 2018. Diet and prey selection by snow leopards in the Nepalese Himalayas. PLoS ONE, 13 (12).DOI：10. 1371/journal. pone. 0206310.
Shrotriya S, Reshamwala H, Lyngdoh S, Jhala Y, Habib B. 2022.Feeding patterns of three widespread carnivores–the wolf, snow leopard, and red fox–in the Trans-Himalayan landscape of India.Frontiers in Ecology and Evolution, 10. DOI： 10. 3389/fevo. 2022. 815996.
Simcharoen A, Simcharoen S, Duangchantrasiri S, Bump J, Smith J L D. 2018. Tiger and leopard diets in western Thailand: evidence for overlap and potentialconsequences. Food Webs, 15: e00085.
Soyumert A, Ertürk A, Tavşanoğlu Ç. 2019. The importance of lagomorphs for the Eurasian lynx in Western Asia: results from a large scale camera-trapping survey in Turkey. Mammalian Biology, 95:18-25.
Suryawanshi K R, Redpath S M, Bhatnagar Y V, Ramakrishnan U, Chaturvedi V, Smout S C, Mishra C. 2017. Impact of wild prey availability on livestock predation by snow leopards. Royal Society Open Science, 4 (6). DOI：10. 1098/rsos. 170026.
Thapa K, Schmitt N, Pradhan N M B, Acharya H R, Rayamajhi S. 2021. No silver bullet? Snow leopard prey selection in Mt.Kangchenjunga, Nepal. Ecology and Evolution, 11 (23): 16413-16425.
Thinley P, Kamler J F, Wang S W, Lham K, Stenkewitz U, Macdonald D W. 2011. Seasonal diet of dholes (Cuon alpinus) in northwestern Bhutan. Mammalian Biology, 76 (4): 518-520.
Torretta E, Riboldi L, Costa E, Delfoco C, Frignani E, Meriggi A. 2021. Niche partitioning between sympatric wild canids: the case of the golden jackal (Canis aureus) and the red fox (Vulpes vulpes) in north-eastern Italy. BMC Ecology and Evolution, 21(1): 129.
Trevelline B K, Nuttle T, Hoenig B D, Brouwer N L, Porter B A, Latta S C. 2018. DNA metabarcoding of nestling feces reveals provisioning of aquatic prey and resource partitioning among Neotropical migratory songbirds in a riparian habitat. Oecologia, 187:85-98.
Valentini A, Pompanon F, Taberlet P. 2009. DNA barcoding for ecologists. Trends in Ecology ＆ Evolution, 24 (2): 110-117.
Wang J, Laguardia A, Damerell P J, Riordan P, Shi K. 2014. Dietary overlap of snow leopard and other carnivores in the Pamirs of northwestern China. Chinese Science Bulletin, 59: 3162-3168.
Wilmers C C, Crabtree R L, Smith D W, Murphy K M, Getz W M. 2003. Trophic facilitation by introduced top predators: grey wolf subsidies to scavengers in Yellowstone National Park. Journal of Animal Ecology, 72 (6): 909-916.
Xiong M Y, Shao X N, Long Y, Bu H L, Zhang D, Wang D J, Li S, Wang R J, Yao M. 2016. Molecular analysis of vertebrates and plants in scats of leopard cats (Prionailurus bengalensis) in southwest China. Journal of Mammalogy, 97 (4): 1054-1064.
Xiong M Y, Wang D J, Bu H L, Shao X N, Zhang D, Li S, Wang R J, Yao M. 2017. Molecular dietary analysis of two sympatric felids in the mountains of southwest China biodiversity hotspot and conservation implications. Scientific Reports, 7. DOI： 10. 1038/srep. 41909.
Zhan Z J, Zhang C, Chen M H, Wang J D, Fu A H, Fan Y W, Luan X F. 2023. DNA metabarcoding-based winter diet analysis of Eurasian otter (Lutra lutra) in the northern Greater Khingan Mountains. Biodiversity Science, 31 (6). DOI: 10. 17520/biods. 2022586. (in Chinese)
Zhang J L, Ding Q, Huang J. 2016. spaa: SPecies Association Analysis.
刘全儒. 2018. 阿尔金山国家级自然保护区野生动植物图谱. 中国环境出版集团.
李治霖, 多立安, 李晟, 王天明. 2021. 陆生食肉动物竞争与共存研究概述. 生物多样性, 29 (1): 81-97.
陆琪, 胡强, 施小刚, 金森龙, 李晟, 姚蒙. 2019. 基于分子宏条形码分析四川卧龙国家级自然保护区雪豹的食性. 生物多样性, 27(9): 960-969.
邵昕宁, 宋大昭, 黄巧雯, 李晟, 姚蒙. 2019. 基于粪便 DNA 及宏条形码技术的食肉动物快速调查及食性分析. 生物多样性, 27(5): 543-556.
董世魁, 翁晋. 2015. 阿尔金山自然保护区基于野牦牛、藏野驴、藏羚羊适宜栖息地的生态容量估测. 生态学报, 35 (23): 7598-7607.
湛振杰, 张超, 陈敏豪, 王嘉栋, 富爱华, 范雨薇, 栾晓峰. 2023. 基于DNA 宏条形码技术的大兴安岭北部欧亚水獭冬季食性分析.生物多样性, 31 (6). DOI: 10. 17520/biods. 2022586..

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[4]	WANG Zhen, TIAN Jiashen, LEI Liyuan, DU Jing, LIU Weidong, HAN Jiabo, LU Zhichuang. Species identification and morphological measurements of a pregnant minke whale(Balaenoptera acutorostrata acutorostrata) [J]. ACTA THERIOLOGICA SINICA, 2020, 40(5): 532-538.
[5]	YUE Chuang, GUO Qianwei, ZHANG Zhuoran, LI Xin, MAN Duhu, YUAN Shuai, FU Heping, WU Xiaodong, JIN Guo, LIU Jianwen, LI Yongshan . Trophic niche of Brandt’s voles (Lasiopodomys brandtii) and their interspecific relationships with other common rodents in a typical steppe, Inner Mongolia [J]. ACTA THERIOLOGICA SINICA, 2020, 40(5): 424-434.
[6]	ZHU Zunyan, HUANG Tianpeng, YAO Hui, YANG Wanji, XIANG Zuofu. Chinese Babax (Babax lanceolatus) was predated by a wild Rhinopithecus roxellana in Shennongjia National Park, China [J]. ACTA THERIOLOGICA SINICA, 2019, 39(5): 585-589.
[7]	ZHOU Xuwei, SONG Jingliang, WANG Fuyou, XIA Wenjun, WU Liji, ZHANG Zhenhuan, BAO Weidong. The application of extracting DNA from noninvasive samples in feline species identification [J]. ACTA Theriologica Sinica, 2015, 35(1): 110-118.
[8]	WANG Qiong, WANG Lu, QUAN Mengyi, TANG Yanyan, WEI Haixue, FU Changkun, ZHANG Xiuyue, CHEN Guiying, CHEN Shunde, ZONG Hao. Microstructure of dorsal guard hairs of six shrews in Soricidae:implication for species identification [J]. ACTA THERIOLOGICA SINICA, 2014, 34(4): 399-.
[9]	YE Wangwei,ZHU Tong,HU Chaochao,ZHANG Chenling,WAN Xia,ZHOU Lizhi,CHANG Qing,ZHANG Baowei. A molecular genetic approach for species identification of several forensic animal sample [J]. , 2008, 28(4): 434-439.
[10]	XU Wenxuan QIAO Jianfang LIU Wei YANG Weikang. Food habits of goitered gazelles (Gazella subgutturosa sairensis)in northern Xinjiang [J]. , 2008, 28(3): 280-286.
[11]	MA Mu,ZHU Qian, LI Xiang, SUN Yumiao, LIU Yingying, LIU Yanan, TAO Cuihua. Identification of Balaenoptera omurai from an unknown whale vertebra based on Cyt b gene sequence [J]. , 2007, 27(3): 288-292.
[12]	ZHANGWei XU Yanchun. A Review and Prospects of the Research on Hair Microstructure [J]. , 2003, 23(4): 339-345.