DOCSLIB.ORG

13References.Pdf

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
13References.Pdf Solving Mammalian Riddles References REFERENCES Abegg, C., and B. Thierry. 2002. Review. Macaque evolution and dispersal in insular South-east Asia. Biological Journal of the Linnean Society 75:555-576. Adams, J. M., and H. Faure. 1997. Preliminary vegetation maps of the world since the last glacial maximum: An aid to archaeological understanding. Journal of Archaeological Science 24:623- 647. Agostinelli, E., M. R. b. A. Tajuddin, E. Antonelli, and M. b. M. Aris. 1990. Miocene-Pliocene paleographic evolution of a tract of Sarawak offshore Bintulu and Miri. Bulletin of the Geological Society of Malaysia 27:117-135. Aimi, M. 1989. A mandible of Sus stremmi Koenigswald, 1933, from Cisaat, Centra Java, Indonesia. Publications of the Geological Research and Development Center:4-10. Aimi, M., and F. Aziz. 1985. Vertebrate fossils from the Sangiran Dome, Mojokerto, Trinil and Sambungmacam areas. Pages 155-198 in N. Watanabe, and D. Kadar, editors. Quaternary geology of the hominid fossil bearing formations in Java. Report of the Indonesia-Japan Joint Research Project CTA-41, 1976-1979. Geological Researdch and Development Centre, Bandung, Indonesia. Aldiss, D. T., and S. A. Ghazali. 1984. The regional geology and evolution of the Toba volcano- tectonic depression, Indonesia. Journal of the Geological Society, London 141:487-500. Aleva, G. J. J., E. H. Bon, J. J. Nossin, and W. J. Sluiter. 1973. A contribution to the geology of part of the Indonesian tin belt: The sea areas between Singkep and Bangka islands and around the Karimata islands. Bulletin of the Geological Society Malaysia 6:257-271. Amato, G., M. G. Egan, and A. Rabinowitz. 1999. A new species of muntjac, Muntiacus putaoensis (Artiodactyla: Cervidae) from northern Myanmar. Animal Conservation 2:1-7. Amato, G., M. G. Egan, and G. B. Schaller. 2000a. Chapter 19. Mitochondrial DNA variation in muntjac: Evidence for discovery, rediscovery, and phylogenetic relationships. Pages 285-295 in E. S. Vrba, and G. B. Schaller, editors. Antelopes, deer, and relatives. Fossil record, behavioral ecology, systematics, and conservation. Yale University Press, New Haven, United States of America and London, United Kingdom. Amato, G., M. G. Egan, and G. B. Schaller. 2000b. Mitochondrial DNA variation in muntjac: Evidence for discovery, rediscovery, and phylogenetic relationships. Pages 285-295 in E. S. Vrba, and G. B. Schaller, editors. Antelopes, Deer, and Relatives. Fossil Record, Behavioral Ecology, Systematics, and Conservation. Yale University Press, New Haven and London. Amato, G., D. Wharton, Z. Z. Zainuddin, and J. R. Powell. 1995. Assessment of conservation units for the Sumatran rhinoceros. Zoo biology 14:395-402. Ambu, L. N., P. M. Andua, S. Nathan, A. Tuuga, S. M. Jensen, R. Cox, R. Alfred, and J. Payne. 2003. Asian Elephant Action Plan Sabah (Malaysia). Sabah Wildlife Department. Anderson, B. L., J. Bon, and H. E. Wahono. 1993. Reassessment of the Miocene stratigraphy, paleogeography and petroleum geochemistry of the Langsa Block in the offshore north 302 Sumatra basin. Pages 169 - 189. Proceedings Indonesian Petroleum Association, 22nd Annual Convention. Andrews, P. 1995. Mammals as palaeoecological indicators. Acta Zoologica Cracoviensia 38:59-72. Andrews, P. 1996. Palaeoecology and hominoid environments. Biological Reviews 71:257-300. Anshari, G., A. P. Kershaw, and S. van der Kaars. 2000. A late Pleistocene and Holocene pollen and charcoal record from peat swamp forest, Lake Sentarum Wildlife Reserve, West Kalimantan, Indonesia. Palaeogeography, Palaeoclimatology, Palaeoecology 171:213-228. Antón, S. C., S. Márquez, and K. Mowbray. 2002. Sambungmacan 3 and cranial variation in Asian Homo erectus. Journal of Human Evolution 43:555-562. Armitage, J. H., and C. Viotti. 1977. Stratigraphic nomenclature - southern end Malay Basin. Pages 69 - 94. Proceedings Indonesian Petroleum Association, Sixth Annual Convention. Arnason, U., A. Gullberg, A. Janke, and X. Xu. 1996. Pattern and timing of evolutionary divergences among hominoids based on analysis of complete mtDNAs. Journal of Molecular Evolution 43:650-661. Ashley, M. V., J. E. Norman, and L. Stross. 1996. Phylogenetic analysis of the Perissodactylan family Tapiridae using mitochondrial cytochrome c oxidase (COII) sequences. Journal of Mammalian Evolution 3:315-326. Ashton, P. 2001. Patterns of species variation in West and East Malaysia. Malayan Nature Journal 55:181-186. Atkins, H., J. Preston, and Q. C. B. Cronk. 2001. A molecular test of Huxley's line:Cyrtandra (Gesneriaceae) in Borneo and the Philippines. Biological Journal of the Linnean Society 72:143-159. Averianov, A. O. 1999. Phylogeny and classification of Leporidae (Mammalia, Lagomorpha). Vestnik Zoologii 33:41-48, 114. Ayob, M. 1970. Quaternary sediments at Sungei Besi, West Malaysia. Bulletin of the Geological Society of Malaysia No. 3:53-61. Aziz, F., and J. de Vos. 1999. The fossil faunas from the Citarum area, West Java, Indonesia. Pages 21- 32 in J. W. F. Reumer, and J. de Vos, editors. Elephants have a snorkel! Deinsea. Jaarbericht van het natuurmuseum Rotterdam Vol. 7, Rotterdam. Bacon, A.-M., and V. T. Long. 2001. The first discovery of a complete skeleton of a fossil orang-utan in a cave of the Hoa Binh Province, Vietnam. Journal of Human Evolution 41:227-241. Badoux, D. M. 1959. Fossil mammals from two fissure deposits at Punung (Java); with some remarks on migration and evolution of mammals during the Quaternary in South-East Asia. Page 151. Rijksuniversiteit Utrecht, Utrecht, the Netherlands. van Balen, B. 1994. Insular ecology of forest bird communities of Java and Bali. Journal für Ornithologie 135:210-211. van Balen, J. H. 1914. De dierenwereld van Insulinde in woord en beeld. I. De Zoogdieren. W.J. Thieme & Cie, Zutphen, the Netherlands. 303 Solving Mammalian Riddles References Bandet, Y., F. Semah, S. Sartono, and T. Djubiantono. 1989. Premier peuplement par les mammifères d'une région de Java Est, à la fin de Pliocène: âge de la faune du Gunung Butak, près de Kedungbrubus (Indonésie). Compte Rendu de l'Academie des Sciences Paris serie II. Mecanique, Physique, Chimie, Sciences de l'univers, Sciences de la Terre 308:867-870. Banks, E. 1931. A popular account of the mammals of Borneo. Journal of the Malayan Branch of the Asiatic Society 9:137. Banks, E. 1980. More mammals from Borneo. Brunei Museum Journal 4:262-273. Barkman, T. J., and B. B. Simpson. 2001. Origin of high-elevation Dendrochilum species (Orchidae) endemic to Mount Kinabalu, Sabah, Malaysia. Systematic Botany 26:658-669. Barry, J. C. 1983. Herpestes (Viverridae, Carnivora) from the Miocene of Pakistan. Journal of Paleontology 57:150-156. Barry, J. C., N. M. Johnson, S. M. Raza, and L. L. Jacobs. 1985. Neogene mammalian faunal change in southern Asia: Correlations with climatic, tectonic, and eustatic events. Geology 13:637-640. Barry, J. C., M. E. Morgan, A. J. Winkler, L. J. Flynn, E. H. Lindsay, L. L. Jacobs, and D. Pilbeam. 1991. Faunal interchange and Miocene terrestrial vertebrates of southern Asia. Paleobiology 17:231-245. Barry, J. C., M. L. E. Morgan, L. J. Flynn, D. Pilbeam, A. K. Behrensmeyer, S. M. Raza, I. A. Khan, C. Badgley, J. Hicks, and J. Kelley. 2002. Faunal and environmental change in the late Miocene Siwaliks of northern Pakistan. Paleobiology 28:1-71. Baryshnikov, G. 1996. The dhole, Cuon alpinus (Carnivora, Canidae), from the Upper Pleistocene of the Caucasus. Acta Zoologica Cracoviensia 39:67-73. Batchelor, B. C. 1979. Discontinuously rising late Cainozoic eustatic sea-levels, with special reference to Sundaland, SE Asia. Geologie en Mijnbouw 58:1-20. Batchelor, D. A. F. 1993. Discussion: Late Pleistocene sedimentation and landform development in western Kalimantan (Indonesian Borneo) by M.B. Thorp et al.: Geologie en Mijnbouw 69: 133-150, 1990. Geologie en Mijnbouw 71:281-286. Baumann, P. 1982. Depositional cycles on magmatic and back arcs; an example from western Indonesia. Revue de l'Institut Français du Petrole 37:3-17. Beard, J. H., J. B. Sangree, and L. A. Smith. 1982. Quaternary chronology, paleoclimate, depositional sequences, and eustatic cycles. The American Association of Petroleum Geologists Bulletin 66:158-169. Beaufort, L. F. 1926. Zoogeographie van den Indischen Archipel. De Erven F. Bohn, Haarlem, The Netherlands. Bell, D. J., W. L. R. Oliver, and R. K. Ghose. 1990. The hispid hare Caprolagus hispidus. Pages 128- 136 in J. A. Chapman, and J. E. C. Flux, editors. Rabbits, hares and pikas. Status survey and conservation action plan. IUCN, Gland, Switzerland. van Bemmel, A. C. V. 1949. Revision of the rusine deer in the Indo-Australian archipelago. Treubia 20:191 - 262 + illustrations. 304 van Bemmelen, R. W. 1970. The geology of Indonesia. General geology of Indonesia and adjacent archipelagoes. Martinus Nijhoff, The Hague, The Netherlands. Ben-Avraham, Z., and K. O. Emery. 1973. Structural framework of the Sundashelf. The American Association of Petroleum Geologists Bulletin 57:2323-2366. Bennett, E. L. 1988. Proboscis monkeys and their swamp forests in Sarawak. Oryx 22:49-57. van den Bergh, G. D. 1999. The Late Neogene elephantoid-bearing faunas of Indonesia and their palaeozoogeographic implications. A study of the terrestrial faunal succession of Sulawesi, Flores and Java, including evidence for early hominid dispersal east of Wallace's line. National Natuuhistorisch Museum, Leiden, The Netherlands. van den Bergh, G. D., J. de Vos, and P. Y. Sondaar. 2001. The Late Quaternary palaeogeography of mammal evolution in the Indonesian archipelago. Palaeogeography, Palaeoclimatology, Palaeoecology 171:385-408. van den Bergh, G. D., J. de Vos, P. Y. Sondaar, and F. Aziz. 1996. Pleistocene zoogeographic evolution of Java (Indonesia) and glacio-eustatic sea level fluctuations: a background for the presence of Homo. Bulletin Indo-Pacific Prehistory Association 14:7-21. Bergmans, W., and P. J. H. van Bree. 1986. On a collection of bats and rats from the Kangean islands, Indonesia (Mammalia: Chiroptera and Rodentia). Zeitschrift für Säugetierkunde. International Journal of Mammalian Biology 51:329-384. Bernor, R.
Load more

Recommended publications
  • O18934 Plard, F., Bonenfant, C. and Gaillard, JM 2011
    Oikos O18934 Plard, F., Bonenfant, C. and Gaillard, J. M. 2011. Re- visiting the allometry of antlers among deer species: male-male sexual competition as a driver. – Oikos 120: 601–606. Table A1. Data basis. Sexual size dimorphism (SSD) was measured by the residuals of the regression of male body mass against female body mass. Breeding group sizes (BGS) were divided into three categories: group of one or two animals (A), group of three, four and five animals (B), and groups larger than five animals (C). The different mating tactics (MT) were harem (H), territorial (T) and tending (F). Non-available mating tactics (NA) and monogamous species (M) are indicated. Sub-family Genus Species Common name Male Female SSD BGS MT Ref Antler Body Body length mass mass Cervinae Axis axis chital 845 89.5 39 0.58 C F 1,2,3 Cervinae Axis porcinus hog deer 399 41 31 0.07 C F 2,3,4,5 Cervinae Cervus albirostris white-lipped deer 1150 204 125 0.06 C H 1,6 Cervinae Cervus canadensis wapiti 1337 350 250 –0.21 C H 3,8,9 Cervinae Cervus duvaucelii barasingha 813 236 145 0.03 C H 1,3,10,11 Cervinae Cervus elaphus red deer 936 250 125 0.34 C H 1,2,3 Cervinae Cervus eldi Eld’s deer 971.5 105 67 0.12 C H 1,2,3 Cervinae Cervus nippon sika deer 480 52 37 0.1 B T 1,2,3,9,12,13 Cervinae Cervus timorensis Timor deer 675 95.5 53 0.29 C H 1,9 Cervinae Cervus unicolor sambar 1049 192 146 –0.18 B T 1,2,3,7 Cervinae Dama dama fallow deer 615 67 44 0.15 C T 1,2,3,14 Cervinae Elaphurus davidianus Père David’s deer 737 214 159 –0.17 C H 1,2,3 Muntiacinae Elaphodus cephalophus
    [Show full text]
  • An Analysis of the Phylogenetic Relationship of Thai Cervids Inferred from Nucleotide Sequences of Protein Kinase C Iota (PRKCI) Intron
    Kasetsart J. (Nat. Sci.) 43 : 709 - 719 (2009) An Analysis of the Phylogenetic Relationship of Thai Cervids Inferred from Nucleotide Sequences of Protein Kinase C Iota (PRKCI) Intron Kanita Ouithavon1, Naris Bhumpakphan2, Jessada Denduangboripant3, Boripat Siriaroonrat4 and Savitr Trakulnaleamsai5* ABSTRACT The phylogenetic relationship of five Thai cervid species (n=21) and four spotted deer (Axis axis, n=4), was determined based on nucleotide sequences of the intron region of the protein kinase C iota (PRKCI) gene. Blood samples were collected from seven captive breeding centers in Thailand from which whole genomic DNA was extracted. Intron1 sequences of the PRKCI nuclear gene were amplified by a polymerase chain reaction, using L748 and U26 primers. Approximately 552 base pairs of all amplified fragments were analyzed using the neighbor-joining distance matrix method, and 19 parsimony- informative sites were analyzed using the maximum parsimony approach. Phylogenetic analyses using the subfamily Muntiacinae as outgroups for tree rooting indicated similar topologies for both phylogenetic trees, clearly showing a separation of three distinct genera of Thai cervids: Muntiacus, Cervus, and Axis. The study also found that a phylogenetic relationship within the genus Axis would be monophyletic if both spotted deer and hog deer were included. Hog deer have been conventionally classified in the genus Cervus (Cervus porcinus), but this finding supports a recommendation to reclassify hog deer in the genus Axis. Key words: Thailand, the family Cervidae, protein kinase C iota (PRKCI) intron, phylogenetic tree, taxonomy INTRODUCTION 1987; Gentry, 1994). Cervids, or what is commonly called “deer,” are mostly characterized The family Cervidae is one of the most by antlers with a bony inner core and velvet skin specious families of artiodactyls, with an extensive cover.
    [Show full text]
  • Sexual Selection and Extinction in Deer Saloume Bazyan
    Sexual selection and extinction in deer Saloume Bazyan Degree project in biology, Master of science (2 years), 2013 Examensarbete i biologi 30 hp till masterexamen, 2013 Biology Education Centre and Ecology and Genetics, Uppsala University Supervisor: Jacob Höglund External opponent: Masahito Tsuboi Content Abstract..............................................................................................................................................II Introduction..........................................................................................................................................1 Sexual selection........................................................................................................................1 − Male-male competition...................................................................................................2 − Female choice.................................................................................................................2 − Sexual conflict.................................................................................................................3 Secondary sexual trait and mating system. .............................................................................3 Intensity of sexual selection......................................................................................................5 Goal and scope.....................................................................................................................................6 Methods................................................................................................................................................8
    [Show full text]
  • Phylogeny, Evolution, and Diversity of Old World Telemetacarpal Deer
    Phylogeny, evolution, and diversity of Old World telemetacarpal deer (Capreolinae, Cervidae, Mammalia) Roman CROITOR (Chișinău/Aix‐en‐Provence) introduction • Modern telemetacarpal deer (subfamily Capreolinae) are represented by few very specialized Old World forms (1, Alces alces; 2, Rangifer tarandus; 3, Capreolus capreolus; 4, Hydropotes inermis) and a diversified radiationof New World telemetacarpal deer. The known paleontological record of Capreolinae in Eurasia is rather scarce and for some genera (Procapreolus) is traced from the Late Miocene, while other lineages appear only in the Early Pleistocene and already represented by very specialized forms (Alces). Some poor Pliocene remains of Capreolus and of a form similar to Alces are reported by Vislobokova et al. (1995) from the Late Pliocene of Baikal Area. Another interesting recent finding is Rangifer sp. from the Early Pleistocene of Western Siberia that maintains the primitive orientation of pedicles (Bondarev et al., 2017). Those sparse findings suggest that Capreolines continuously were present in the middle latitudes of Eurasia, but their fossil remains apparently are misunderstood. • The Miocene record of Capreolinae is insufficiently known and many of cervid forms and species are poorly understood. This is the case of Metadicrocerus variabilis, Cervavitus tarakliensis, and Pliocervus matheroni (traditionally are placed in the tribe Pliocervini of the subfamily Cervinae) that are believed to have the intermediate phylogenetic position between modern Cervinae (plesiometacarpal
    [Show full text]
  • Karyotype Relationships Among Selected Deer Species and Cattle Revealed by Bovine FISH Probes
    RESEARCH ARTICLE Karyotype relationships among selected deer species and cattle revealed by bovine FISH probes Jan Frohlich1*, Svatava Kubickova1, Petra Musilova1, Halina Cernohorska1, Helena Muskova1, Roman Vodicka2, Jiri Rubes1 1 Central European Institute of Technology - Veterinary Research Institute, Brno, Czech Republic, 2 Zoo Prague, Prague, Czech Republic a1111111111 a1111111111 * [email protected] a1111111111 a1111111111 a1111111111 Abstract The Cervidae family comprises more than fifty species divided into three subfamilies: Capreolinae, Cervinae and Hydropotinae. A characteristic attribute for the species included in this family is the great karyotype diversity, with the chromosomal numbers ranging from OPEN ACCESS 2n = 6 observed in female Muntiacus muntjak vaginalis to 2n = 70 found in Mazama goua- Citation: Frohlich J, Kubickova S, Musilova P, Cernohorska H, Muskova H, Vodicka R, et al. zoubira as a result of numerous Robertsonian and tandem fusions. This work reports chro- (2017) Karyotype relationships among selected mosomal homologies between cattle (Bos taurus, 2n = 60) and nine cervid species using a deer species and cattle revealed by bovine FISH combination of whole chromosome and region-specific paints and BAC clones derived from probes. PLoS ONE 12(11): e0187559. https://doi. cattle. We show that despite the great diversity of karyotypes in the studied species, the org/10.1371/journal.pone.0187559 number of conserved chromosomal segments detected by 29 cattle whole chromosome Editor: Roscoe Stanyon, University of Florence, painting probes was 35 for all Cervidae samples. The detailed analysis of the X chromo- ITALY somes revealed two different morphological types within Cervidae. The first one, present in Received: August 23, 2017 the Capreolinae is a sub/metacentric X with the structure more similar to the bovine X.
    [Show full text]
  • Pan-American Trypanosoma (Megatrypanum) Trinaperronei N. Sp
    Garcia et al. Parasites Vectors (2020) 13:308 https://doi.org/10.1186/s13071-020-04169-0 Parasites & Vectors RESEARCH Open Access Pan-American Trypanosoma (Megatrypanum) trinaperronei n. sp. in the white-tailed deer Odocoileus virginianus Zimmermann and its deer ked Lipoptena mazamae Rondani, 1878: morphological, developmental and phylogeographical characterisation Herakles A. Garcia1,2* , Pilar A. Blanco2,3,4, Adriana C. Rodrigues1, Carla M. F. Rodrigues1,5, Carmen S. A. Takata1, Marta Campaner1, Erney P. Camargo1,5 and Marta M. G. Teixeira1,5* Abstract Background: The subgenus Megatrypanum Hoare, 1964 of Trypanosoma Gruby, 1843 comprises trypanosomes of cervids and bovids from around the world. Here, the white-tailed deer Odocoileus virginianus (Zimmermann) and its ectoparasite, the deer ked Lipoptena mazamae Rondani, 1878 (hippoboscid fy), were surveyed for trypanosomes in Venezuela. Results: Haemoculturing unveiled 20% infected WTD, while 47% (7/15) of blood samples and 38% (11/29) of ked guts tested positive for the Megatrypanum-specifc TthCATL-PCR. CATL and SSU rRNA sequences uncovered a single species of trypanosome. Phylogeny based on SSU rRNA and gGAPDH sequences tightly cluster WTD trypanosomes from Venezuela and the USA, which were strongly supported as geographical variants of the herein described Trypa- nosoma (Megatrypanum) trinaperronei n. sp. In our analyses, the new species was closest to Trypanosoma sp. D30 from fallow deer (Germany), both nested into TthII alongside other trypanosomes from cervids (North American elk and European fallow, red and sika deer), and bovids (cattle, antelopes and sheep). Insights into the life-cycle of T. trinaper- ronei n. sp. were obtained from early haemocultures of deer blood and co-culture with mammalian and insect cells showing fagellates resembling Megatrypanum trypanosomes previously reported in deer blood, and deer ked guts.
    [Show full text]
  • Deer from Late Miocene to Pleistocene of Western Palearctic: Matching Fossil Record and Molecular Phylogeny Data
    Zitteliana B 32 (2014) 115 Deer from Late Miocene to Pleistocene of Western Palearctic: matching fossil record and molecular phylogeny data Roman Croitor Zitteliana B 32, 115 – 153 München, 31.12.2014 Institute of Cultural Heritage, Academy of Sciences of Moldova, Bd. Stefan Cel Mare 1, Md-2028, Chisinau, Moldova; Manuscript received 02.06.2014; revision E-mail: [email protected] accepted 11.11.2014 ISSN 1612 - 4138 Abstract This article proposes a brief overview of opinions on cervid systematics and phylogeny, as well as some unresolved taxonomical issues, morphology and systematics of the most important or little known mainland cervid genera and species from Late Miocene and Plio-Pleistocene of Western Eurasia and from Late Pleistocene and Holocene of North Africa. The Late Miocene genera Cervavitus and Pliocervus from Western Eurasia are included in the subfamily Capreolinae. A cervid close to Cervavitus could be a direct forerunner of the modern genus Alces. The matching of results of molecular phylogeny and data from cervid paleontological record revealed the paleozoogeographical context of origin of modern cervid subfamilies. Subfamilies Capreolinae and Cervinae are regarded as two Late Miocene adaptive radiations within the Palearctic zoogeographic province and Eastern part of Oriental province respectively. The modern clade of Eurasian Capreolinae is significantly depleted due to climate shifts that repeatedly changed climate-geographic conditions of Northern Eurasia. The clade of Cervinae that evolved in stable subtropical conditions gave several later radiations (including the latest one with Cervus, Rusa, Panolia, and Hyelaphus) and remains generally intact until present days. During Plio-Pleistocene, cervines repeatedly dispersed in Palearctic part of Eurasia, however many of those lineages have become extinct.
    [Show full text]
  • Genomic Conservation of Cattle Microsatellite Loci in Wild Gaur (Bos Gaurus) and Current Genetic Status of This Species in Vietnam
    Genomic conservation of cattle microsatellite loci in wild gaur (Bos gaurus) and current genetic status of this species in Vietnam. Trung Thanh Nguyen, Sem Genini, Linh Chi Bui, Peter Voegeli, Gerald Stranzinger, Jean Paul Renard, Jean-Charles Maillard, Bui Xuan Nguyen To cite this version: Trung Thanh Nguyen, Sem Genini, Linh Chi Bui, Peter Voegeli, Gerald Stranzinger, et al.. Genomic conservation of cattle microsatellite loci in wild gaur (Bos gaurus) and current genetic status of this species in Vietnam.. BMC Genetics, BioMed Central, 2007, 8 (77), 8p. hal-02655358 HAL Id: hal-02655358 https://hal.inrae.fr/hal-02655358 Submitted on 29 May 2020 HAL is a multi-disciplinary open access L’archive ouverte pluridisciplinaire HAL, est archive for the deposit and dissemination of sci- destinée au dépôt et à la diffusion de documents entific research documents, whether they are pub- scientifiques de niveau recherche, publiés ou non, lished or not. The documents may come from émanant des établissements d’enseignement et de teaching and research institutions in France or recherche français ou étrangers, des laboratoires abroad, or from public or private research centers. publics ou privés. BMC Genetics BioMed Central Research article Open Access Genomic conservation of cattle microsatellite loci in wild gaur (Bos gaurus) and current genetic status of this species in Vietnam Trung Thanh Nguyen†1, Sem Genini†2, Linh Chi Bui1, Peter Voegeli3, Gerald Stranzinger3, Jean-Paul Renard4, Jean-Charles Maillard5 and Bui Xuan Nguyen*1 Address: 1Vietnamese Academy of Sciences and Technology, Hanoi, Vietnam, 2Parco Tecnologico Padano (PTP), CERSA, Via Einstein, 26900 Lodi, Italy, 3Institute of Animal Sciences, Breeding Biology, Swiss Federal Institute of Technology, 8092 Zurich, Switzerland, 4UMR Biologie du Développement et de la Reproduction.
    [Show full text]
  • A Comprehensive Approach Towards the Systematics of Cervidae
    A peer-reviewed version of this preprint was published in PeerJ on 18 February 2020. View the peer-reviewed version (peerj.com/articles/8114), which is the preferred citable publication unless you specifically need to cite this preprint. Heckeberg NS. 2020. The systematics of the Cervidae: a total evidence approach. PeerJ 8:e8114 https://doi.org/10.7717/peerj.8114 A comprehensive approach towards the systematics of Cervidae Nicola S Heckeberg Corresp., 1, 2, 3 , Gert Wörheide 1, 2, 4 1 Department of Earth and Environmental Sciences, Palaeontology & Geobiology, Ludwig-Maximilians-Universität München, Munich, Germany 2 SNSB-Bayerische Staatssammlung für Paläontologie und Geologie, Munich, Germany 3 Leibniz Institute for Evolution and Biodiversity Science, Museum für Naturkunde, Berlin, Germany 4 Geobio-CenterLMU, Munich, Germany Corresponding Author: Nicola S Heckeberg Email address: [email protected] Systematic relationships of cervids have been controversial for decades. Despite new input from molecular systematics, consensus could only be partially reached. The initial, gross (sub)classification based on morphology and comparative anatomy was mostly supported by molecular data. The rich fossil record of cervids has never been extensively tested in phylogenetic frameworks concerning potential systematic relationships of fossil cervids to extant cervids. The aim of this work was to investigate the systematic relationships of extant and fossil cervids using molecular and morphological characters and make implications about their evolutionary history based on the phylogenetic reconstructions. To achieve these objectives, molecular data were compiled consisting of five nuclear markers and the complete mitochondrial genome of 50 extant and one fossil cervid species. Several analyses using different data partitions, taxon sampling, partitioning schemes, and optimality criteria were undertaken.
    [Show full text]
  • PERE DAVID's DEER 2007 Class: Mammalia Order
    PERE DAVID’S DEER 2007 Class: Mammalia Order: Artiodactyla Family: Cervidae Male: buck, stag, hart Subfamily: Cervinae Female: doe, hind, roe Species: Elaphurus Young: fawn, calf, kid Genus: davidianus Group: herd Description: The Père David’s deer has a reddish-tawny colored summer coat with a dark dorsal stripe and a dark gray winter coat. It has a long tail that ends with a tuft of hair. They have large eyes and short pointed ears. The male deer have branched antlers with the longest branches near the base. They can have 2 sets of antlers in the same year! They have long legs and also long hooves that are spread apart to provide better support on soft soil. Size: The adults weigh between 330 and 440 pounds. They can reach about 5 feet in length, but the tail can add an additional 20 inches. They can stand between 4 feet and 5.5 feet at the shoulder. Life Span: Père David’s deer usually live between 18-22 years. Diet: In the Wild: They graze on a mixture of grass and water plants. At the Zoo: They are fed grain, corn, oats, and hay. They have been observed eating duckweed in the Safariland ponds. Geographic These animals were originally native to central and northern China. Range: Habitat: Marshy lowlands Reproduction: The males gather a harem during the breeding season from June to August. The males fight, or rut, for the right to mate. This includes using their antlers and teeth to chase off competitors. They also rear up on their hind legs to “box” with each other.
    [Show full text]
  • City of Wyoming City Code
    Chapter 8 ANIMALS* __________ *Cross references: Environment, Ch. 16; RR rural residential district, § 40-136 et seq. State law references: Authority to regulate the keeping of animals, Minnesota Statutes § 412.221, subd. 21. __________ ARTICLE I. IN GENERAL Sec. 8 – 1. Definitions. Sec. 8 – 2. Running at large prohibited. Sec. 8 – 3. Seizure of an animal running at large. Sec. 8 – 4. Muzzling proclamation. Sec. 8 – 5. Specific Prohibitions. Sec. 8 – 6. Premises entry right. Sec. 8 – 7. Number of animals permitted. ARTICLE II. POUND Sec. 8 – 41. Authorized. Sec. 8 – 42. Impoundment of animals. Sec. 8 – 43. Redemption. Sec. 8 – 44. Selling of impounded animals. Sec. 8 – 45. Disposition of proceeds of sale. Sec. 8 – 46. Breaking pound. ARTICLE III. URBAN FOWL Sec. 8 – 71. Authorized. Sec. 8 – 72. Facilities. 35 ARTICLE I. IN GENERAL Sec. 8 – 1. Definitions. The following words, terms and phrases, when used in this chapter, shall have the meanings ascribed to them in this section, except where the context clearly indicates a different meaning: (1) Agricultural Purposes: Means animals that are raised, kept, or bred as commodities and are sold, or their offspring sold, whole or in part for meat, food, fur, skin, fiber, or egg production. (2) Buildable: Means an area of land excluding surface waters, wetlands or floodplains. (3) Domestic Animal: Domestic animal means, animal species that have been selectively bred for hundreds of generations to accept humans or live with humans, and are commonly considered to be domesticated in the United States. Domestic animals include companion animals and livestock. (4) Companion Animal: Means any animal that is commonly kept by persons as a pet or for companionship.
    [Show full text]
  • 1 Risk Assessment Template Developed Under
    Risk assessment template developed under the "Study on Invasive Alien Species – Development of risk assessments to tackle priority species and enhance prevention" Contract No 07.0202/2018/788519/ETU/ENV.D.21 Name of organism: Axis axis (Erxleben, 1777) Author(s) of the assessment: Riccardo Scalera, IUCN SSC Invasive Species Specialist Group, Rome, Italy Wolfgang Rabitsch, Umweltbundesamt, Vienna, Austria Piero Genovesi, ISPRA and IUCN SSC Invasive Species Specialist Group, Rome, Italy Sven Bacher, University of Fribourg, Department of Biology, Fribourg, Switzerland Tim Adriaens, Research Institute for Nature and Forest (INBO), Brussels, Belgium Yasmine Verzelen, Research Institute for Nature and Forest (INBO), Brussels, Belgium Peter Robertson, Newcastle University, Newcastle, Great Britain Björn Beckmann, Centre for Ecology and Hydrology (CEH), Wallingford, United Kingdom Risk Assessment Area: The risk assessment area is the territory of the European Union 27 and the United Kingdom, excluding the EU-outermost regions. Peer review 1: Wojciech Solarz, Institute of Nature Conservation, Polish Academy of Sciences, Kraków, Poland Peer review 2: anonymous Date of completion: 6 February 2020 Date of revision: 4 March 2021 Positive opinion by the Scientific Forum: 13 April 2021 1 This template is based on the Great Britain non-native species risk assessment scheme (GBNNRA). A number of amendments have been introduced to ensure compliance with Regulation (EU) 1143/2014 on IAS and relevant legislation, including the Delegated Regulation (EU) 2018/968 of 30 April 2018, supplementing Regulation (EU) No 1143/2014 of the European Parliament and of the Council with regard to risk assessments in relation to invasive alien species (see https://eur- lex.europa.eu/legal-content/en/TXT/?uri=CELEX%3A32018R0968 ).
    [Show full text]