 | Mellya, R.V.K.; Hopcraft, J.G.C.; Eblate, E.M.; Otiende, M.; Chuma, I.S.; Macha, E.S.; Wambura, D.; Kilbride, E.; Mable, B.K. 2023 Genetic diversity of the eastern black rhinoceros (Diceros bicornis michaeli) in Tanzania; implications for future conservation. Conservation Genetics 2023 - preprint: https://doi.org/10.21203/rs.3.rs-2560054/v1 |
|
Location:
Subject:
Species:
|
Africa - Eastern Africa - Tanzania
Genetics
Black Rhino
|
| In the past decade, there has been a drastic decline in the number of Eastern Black rhinoceros (Diceros bicornis michaeli), due to poaching, leaving few individuals in small, isolated populations that are vulnerable to extinction. However, the genetic consequences of the demographic decline on th... |
|
|
| Corder, M.L.; Petricoin, E.F.; Yue Li; Cleland, T.P.; DeCandia, A.L.; Aguirre, A.A.; Pukazhenthi, B.S. 2023 Metabolomic profiling implicates mitochondrial and immune dysfunction in disease syndromes of the critically endangered black rhinoceros (Diceros bicornis). Nature: Scientific Reports 13:15464: 1-13 - https://doi.org/10.1038/s41598-023-41508-4 |
|
Location:
Subject:
Species:
|
Captive
Genetics
Black Rhino
|
| The critically endangered black rhinoceros (Diceros bicornis; black rhino) experiences extinction threats from poaching in-situ. The ex-situ population, which serves as a genetic reservoir against impending extinction threats, experiences its own threats to survival related to several disease syn... |
|
|
| Ruggeri, E.; Rodriguez, J.; Fallon, L.; Orsolini, M.; Durrant, B. 2023 In vivo gene expression analysis of southern white rhinoceros (Ceratotherium simum simum) granulosa cells collected from growing, dominant, and preovulatory follicles after ovum pickup. Reproduction, Fertility and Development 36 (2): 162 - https://doi.org/10.1071/RDv36n2Ab25 |
|
Location:
Subject:
Species:
|
Africa
Genetics
White Rhino
|
| Analysis of granulosa cells (GC) can be a useful noninvasive tool to clarify aspects of ovarian physiology in the southern white rhinoceros (SWR). Gene expression profiles from different phases of follicle development may help improve ovum pickup (OPU) outcome and advance assisted reproductive te... |
|
|
| Seeber, P.A.; Batke, L.; Dvornikov, Y.; Schmidt, A.; Wang, Y.; Stoof-Leichsenring, K.R.; Moon, K.L.; Shapiro, B.; Epp, L.S. 2023 Mitochondrial genomes of Pleistocene megafauna retrieved from recent sediment layers of two Siberian lakes. eLife - Genetics and Genomics 2023 (early view): 13 pp., 1 fig, 1 tab. - doi: 10.7554/eLife.89992 |
|
Location:
Subject:
Species:
|
Asia - Palearctic Asia
Genetics - Methods
Fossil
|
| Details - Coelodonta antiquitatis (Blumenbach) is considered in this research. |
|
|
| Stejskal, J. 2023 Záchrana nosorožce tuponosých severních. Annual Report of Dvur Kralove Zoo 2023: 144-150 |
|
Location:
Subject:
Species:
|
Captive
Genetics
Nile Rhino
|
| No details available yet |
|
|
| Nabeshima, K.; Nakajima, N.; Ogata, M.; Onuma, M. 2022 Draft genome sequence data of Indian rhinoceros, Rhinoceros unicornis. Data in Brief 41 (107857): 1-5 - doi.org/10.1016/j.dib.2022.107857 |
|
Location:
Subject:
Species:
|
Asia
Genetics
Indian Rhino
|
| The Indian rhinoceros (Rhinoceros unicornis) is a large herbivore found in northern India and southern Nepal. It is a critically endangered species, with an estimated population of approximately 3,600 in the wild. Genetic factors, such as the loss of genetic diversity and the accumulation of dele... |
|
|
| Ghosh, T.; Kumar, S.; Sharma, K.; Kakati, P.; Sharma, A.; Mondol, S. 2022 Consideration of genetic variation and evolutionary history in future conservation of Indian one-horned rhinoceros (Rhinoceros unicornis). BMC Ecology and Evolution 22 (92): 1-13 - https://doi.org/10.1186/s12862-022-02045-2 |
|
Location:
Subject:
Species:
|
Asia - South Asia
Genetics
Indian Rhino
|
| NB. Typing error Rookmaker for Rookmaaker
References without URL would have been available on RRC
The extant members of the Asian rhinos have experienced severe population and range declines since Pleistocene through a combination of natural and anthropogenic factors. The one-horned rhi... |
|
|
| Pathak, A.; Hsu, Y.; Sadaula, A.; Joshi, J.; Gairhe, K.P.; Kandel, R.C.; Gilbert, M.; Paudel, P. 2022 Reduced genetic diversity in greater one-horned rhinoceros in Chitwan National Park:A new challenge and opportunity for rhino conservation in Nepal. Journal of Biological Studies 5 (4): 693-704 |
|
Location:
Subject:
Species:
|
Asia - South Asia - Nepal
Genetics
Indian Rhino
|
| No details available yet |
|
|
| Priywambodo; Rustiati, E.L.; Kurniawati, Y.; Putri, C.R.; Zulkarnain, D.; Arsan, Z.; Giyono; Widiawati, A.E.; Sukatmoko; Srihanto, E.A. 2022 Exploring environmental DNA for barcoding analysis of Sumatran rhino in Way Kambas National Park. AIP Conference Proceedings 2563, 040013: 1-6 - https://doi.org/10.1063/5.0103413 |
|
Location:
Subject:
Species:
|
Asia - South East Asia - Indonesia - Sumatra
Genetics
Sumatran Rhino
|
| The Sumatran rhino (Dicerorhinus sumatrensis) is one of five species of rhino in the world. The existence of the Sumatran rhino is also considered very vulnerable to habitat degradation, internal cross-breeding, disease, and hunting. The Sumatran rhino population will experience extinction if the... |
|
|
| Handayani; Duryadi, D.; Alikodra, H. 2022 Isolasi DNA dan amplifikasi fragmen d-loopmitokondrial pada badak sumatera (Dicerorhinus sumatrensis, Fischer 1814). Metrik Serial Teknologi Dan Sains 3 (2): 103-108 |
|
Location:
Subject:
Species:
|
Asia - South East Asia - Indonesia
Genetics
Sumatran Rhino
|
| No details available yet |
|
|
|
Notes for: Genetics
print
details