| Kraaijeveld, K.; Bossers, L.; Petrusevski, N.; Pieterman, S.; Bruins-van Sonsbeek, L.G.R.; Wittink, F. 2024 ONT read assembly of the black rhino genome. BMC Genomic Data 25:27: 1-2 - doi.org/10.1186/s12863-024-01214 |
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Location:
Subject:
Species:
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Captive
Genetics
Black Rhino
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| No details available yet |
|
| Seeber, P.A.; Batke, L.; Dvornikov, Yu.; Schmidt, A.; Wang, Yi; Stoof-Leichsenring, K.; Moon, K.; Vohr, S.H.; Shapiro, B.; Epp, L.S. 2024 Mitochondrial genomes of Pleistocene megafauna retrieved from recent sediment layers of two Siberian lakes. eLife - Genetics and Genomics 2023;12:RP8999: 24 pp, 3 figs, 15 tabs, DOI: https://doi.org/10.7554/eLife.89992 |
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Location:
Subject:
Species:
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Asia
Genetics
Fossil
|
| Details - Coelodonta antiquitatis (Blum.) is cited in the text. |
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| Seeber, P.A.; Palmer, Z.; Schmidt, A.; Chagas, A.; Kitagawa, K.; Marinova-Wolff, E.; Tafelmaier, Y.; Epp, L.S. 2023 The first European woolly rhinoceros mitogenomes, retrieved from cave hyena coprolites, suggest long-term phylogeographic differentiation. Biology Letters: 19: 20230343, 4 pp., 1 fig [https://doi.org/10.1098/rsbl.2023.0343] |
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Location:
Subject:
Species:
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World
Genetics
Fossil
|
| No details available yet |
|
| Sanchez-Barreiro, F.; Gopalakrishnan, S.; Ramos-Madrigal, J.; Westbury, M.V. ; Manuel, M.de; Margaryan, A.; Ciucani, M.C. ; Vieira, F.G.; Patramanis, Y.; Kalthoff, D.C.; Timmons, Z.; Sicheritz-Pontén, T.; Dalén, L.; Ryder, O.A.; Zhang, G.; Marquès-Bonet, T.; Moodley, Y.; Gilbert, M.T.P. 2023 Historical population declines prompted significant genomic erosion in the northern and southern white rhinoceros (Ceratotherium simum). Molecular Ecology 40 (9):msad180: 1-19 - https://doi.org/10.1093/molbev/msad180 |
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Location:
Subject:
Species:
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Africa
Genetics
White Rhino
|
| No details available yet |
|
| Stanbridge, D.; O'Riain, M.J.; Dreyer, C.; Le Roex, N. 2023 Genetic restoration of black rhinoceroses in South Africa: conservation implications. Conservation Genetics 24: 99-107 - https://doi.org/10.1007/s10592-022-01486-y |
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Location:
Subject:
Species:
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Africa
Genetics
Black Rhino
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| Globally, wildlife populations are becoming increasingly small and isolated. Both processes contribute to an elevated risk of extinction, notably due to genetic factors related to inbreeding depression and a loss of adaptive potential. Wildlife translocation is a valuable conservation tool to rei... |
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| Priyambodo; Putri, C.R.P.; Rustiati, E.L.; Kurniawati, Y; Zulkarnain, D.; Pratiwi, D.N.; Arsan, Z.; Giyono; Mustikawati, G.; Pertiwi, V.R.; Sukatmoko; Srihanto, E.A.; Saswiyanti, E. 2023 Amplification of the GAPDH gene from the urine eDNA of Sumatran Rhino in Sumatran Rhino Sanctuary, Way Kambas National Park. Jurnal Biologi Tropis 23 (3): 110-114 |
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Location:
Subject:
Species:
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Asia - South East Asia - Indonesia
Genetics
Sumatran Rhino
|
| No details available yet |
|
| Mellya, R.V.K.; Hopcraft, J.G.C.; Eblate, E.M.; Kariuki, L. ; Otiende, M.; Chuma, I.S.; Macha, E.S.; Wambura, D.; Kilbride, E.; Mable, B.K. 2023 Mitochondrial DNA diversity of the eastern black rhinoceros (Diceros bicornis michaeli) in Tanzania: implications for future conservation. Conservation Genetics 2023: 1-16 - https://doi.org/10.1007/s10592-023-01545-y |
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Location:
Subject:
Species:
|
Africa - Eastern Africa - Tanzania
Genetics
Black Rhino
|
| There has been a drastic decline in the number of eastern black rhinoceros (Diceros bicornis michaeli) across Africa, leaving individuals restricted to small, isolated populations that are vulnerable to extinction. Focusing on highly threatened populations in Tanzania, this study investigated the... |
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| 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 |
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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... |
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| 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 |
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Location:
Subject:
Species:
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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... |
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| 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 |
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Location:
Subject:
Species:
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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... |
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