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163 results on '"Semiadi, Gono"'

1. Serological evidence of sarbecovirus exposure along Sunda pangolin trafficking pathways

Author

Worthington, Brian M., Wong, Portia Y.-H., Kumaree, Kishoree K., Prigge, Tracey-Leigh, Ng, Kar Hon, Liao, Yunshi, Martelli, Paolo, Churgin, Sarah, Lee, Foo K., Perkins, Chris, Bradley, Michael, Pierce, Mac P., Shum, Marcus H.-H., Miot, Elliott F., Cheung, William Y.-M., McIlroy, Shelby E., Nash, Helen C., Wirdateti, Semiadi, Gono, Tan, Chee-Wah, Wang, Lin-Fa, Ades, Gary, Baker, David M., Dingle, Caroline, Pybus, Oliver G., Holmes, Edward C., Leung, Gabriel M., Guan, Yi, Zhu, Huachen, Bonebrake, Timothy C., and Lam, Tommy T. Y.

Published
2024
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3. Water Monitor Lizard ( Varanus salvator) Skin Microstructure: Histochemical and Morphometrical Studies of Fiber Type Characteristics (Histochemistry Fiber Skin Water Monitor).

Author

Prawira, Andhika Yudha, Rischa Phadmacanty, Ni Luh Putu, Semiadi, Gono, Kurniati, Hellen, Trilaksono, Wahyu, Yulianto, Nurhidayat, and Agungpriyono, Srihadi

Subjects
STAINS & staining (Microscopy), LEATHERWORK, LIZARDS, ELASTIN, DERMIS
Abstract

Global demand for the water monitor's skin, Varanus salvator, has made it a valuable wildlife commodity. Leathercraft manufacturing must consider not only beauty but also the strength and flexibility of the leather, which is determined by its structure in the skin. Therefore, this study analyzed and evaluated the fiber type characteristic of the water monitor's skin. Skin samples were collected from 10 Sumatra water monitors with a Snout-Vent Length size of 39-89 cm and were divided into small (39-59 cm) and large (60-89 cm) groups. The skins from the dorsocervical, lumbosacral, and ventral regions were proceeded for histological sections. Histochemical approaches utilized were Hematoxylin Eosin, Picrosirius Red, and Elastin Verhoeff's Hematoxylin staining methods. Thick fibers are the main component in the skin, ranging from 69-73%, respectively, while thin fibers varied greatly and were observed predominantly in the reticular dermis. Fiber size in the reticular dermis of small lizards was lower than that of larger ones. Elastic fibers were observed abundantly at the border of the reticular dermis and subcutaneous layer in both small and large lizards. Moreover, the skin of the small-sized lizard also has a lower morphometric than that of a large-sized lizard, both in thickness and fiber type percentage. Therefore, the skin of small-sized lizards was considered less tough than that of large-sized lizards. [ABSTRACT FROM AUTHOR]

Published
2024
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4. Determination of spermatogenesis activity using lectin histochemistry in water monitor lizards (Varanus salvator) harvested from the wild.

Author

PRAWIRA, Andhika Yudha, PHADMACANTY, Ni Luh Putu Rischa, SEMIADI, Gono, KURNIATI, Hellen, TRILAKSONO, Wahyu, NURHIDAYAT, Nurhidayat, and NOVELINA, Savitri

Subjects
PEARSON correlation (Statistics), LEYDIG cells, TESTIS, CONNECTIVE tissues, HISTOCHEMISTRY
Abstract

Lectin is often used to investigate the differentiation and maturation of spermatogenic cells in the testes of several wild animals, facilitating the screening of mature individuals. Therefore, this study aimed to determine spermatogenesis activity using lectin histochemistry in water monitor lizards (Varanus salvator) harvested from the wild. Testes of 43 comprehensively examined water monitor lizards were collected from slaughterhouses in Palembang (Sumatra) and Banten (West Java), Indonesia, with snout-vent lengths (SVL) ranging from 39 to 96 cm. Additionally, histologic, histomorphometric, periodic acid-Schiff (PAS) staining, and lectin histochemistry (Con A, RCA, WGA, PNA, VVA, DBA, UEA-I) observations were performed. The results showed a positive correlation between SVL, morphometry, and histomorphometry at p < 0.05 with Pearson's correlation analysis. All specimens presented a spermatogenesis process with different activities among various SVL sizes, with larger animals having higher spermatogenic activity. Moreover, PAS-positive reactions in the testes were mainly observed in the cytoplasmic residues of spermatogenic cells, connective tissue, Leydig cells, and blood vessels. The most dominant-reacting lectin bindings were ConA, RCA, and WGA, distributed in nearly the entirety of the testes, including in spermatids and spermatozoa phases. PNA and VVA bindings were localized in Golgi and Cap stage spermatids, while UEA-I and DBA lectins showed no binding reaction. Although the larger animals had more spermatogenic cells, the lectin-binding patterns of all specimens were similar. The presence of lectin binding of PNA, VVA, and WGA in spermatids and spermatozoa in spermatogenic cells signified that male monitor lizards harvested from the wild exhibited active spermatogenic processes and were able to produce mature spermatozoa. [ABSTRACT FROM AUTHOR]

Published
2024
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5. The importance of small island populations for the long term survival of endangered large-bodied insular mammals

Author

Aninta, Sabhrina Gita, primary, Drinkwater, Rosie, additional, Carmagnini, Alberto, additional, Deere, Nicolas J., additional, Priyono, Dwi Sendi, additional, Andayani, Noviar, additional, Winarni, Nurul L., additional, Supriatna, Jatna, additional, Fumagalli, Matteo, additional, Larson, Greger, additional, Galbusera, Peter, additional, Macdonald, Alastair, additional, Greer, Deborah, additional, Mohamad, Kusdiantoro, additional, Prasetyaningtyas, Wahono Esthi, additional, Mustari, Abdul Haris, additional, Williams, John, additional, Barnett, Ross, additional, Shaw, Darren, additional, Semiadi, Gono, additional, Burton, James, additional, Seaman, David, additional, Voigt, Maria, additional, Struebig, Matthew, additional, Brace, Selina, additional, Rossiter, Stephen, additional, and Frantz, Laurent, additional

Published
2024
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7. Insights from 20 years of mammal population research in Indonesia.

Author

Ardiantiono, Pinondang, Irene M.R., Chandradewi, Desy S., Semiadi, Gono, Pattiselanno, Freddy, Supriatna, Jatna, Tasirin, Johny S., Winarni, Nurul L., Voigt, Maria, Bull, Joseph W., Humle, Tatyana, Deere, Nicolas J., and Struebig, Matthew J.

Subjects
MAMMAL populations, WILDLIFE monitoring, WILDLIFE conservation, ENVIRONMENTAL degradation, NUMBERS of species, ANIMAL populations
Abstract

Mammal populations are declining in biodiverse tropical regions. Global analyses have identified Indonesia as a hotspot of vertebrate decline, although relatively few data are available to substantiate these claims. We reviewed research articles published during 2000–2020 on 104 medium-sized to large terrestrial mammal species found in Indonesia to help inform conservation management and future research. We identified 308 peer-reviewed studies published in English or Bahasa Indonesia, with an increase in publication rate (articles published per year) over time. Studies of species distributions dominated the literature, followed by publications on abundance, species diversity and combinations of these topics. Most publications concerned single-species studies conducted at a single location and a single point in time. We identify four key issues that should be addressed by future research and conservation efforts: (1) disproportionate focus on a small number of species; (2) geographical bias towards west Indonesia (Sumatra, Kalimantan and Java–Bali), with few published studies from central (Sulawesi, Nusa Tenggara and Maluku) and east (Papua) Indonesia; (3) limitations to survey design, sampling effort and data analysis; and (4) lack of long-term wildlife population studies. We also note challenges local researchers face in publishing their studies in international journals because of language barriers and costs. Greater use of existing biodiversity data and continued capacity building for local researchers, particularly those in central and east Indonesia, are critical to effectively guide future wildlife monitoring and improve the conservation status of Indonesian mammals. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Evaluating the feasibility of pangolin farming and its potential conservation impact

Author

Challender, Daniel W.S., Sas-Rolfes, Michael't, Ades, Gary W.J., Chin, Jason S.C., Ching-Min Sun, Nick, Chong, Ju lian, Connelly, Ellen, Hywood, Lisa, Luz, Sonja, Mohapatra, Rajesh K., de Ornellas, Paul, Parker, Keri, Pietersen, Darren W., Roberton, Scott I., Semiadi, Gono, Shaw, Debbie, Shepherd, Chris R., Thomson, Paul, Wang, Yifu, Wicker, Leanne, Wu, Shi Bao, and Nash, Helen C.

Published
2019
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12. Drivers of habitat availability for terrestrial mammals: Unravelling the role of livestock, land conversion and intrinsic traits in the past 50 years

Author

Pacifici, Michela, primary, Cristiano, Andrea, additional, Lumbierres, Maria, additional, Lucherini, Mauro, additional, Mallon, David, additional, Meijaard, Erik, additional, Solari, Sergio, additional, Tognelli, Marcelo F., additional, Belant, Jerrold L., additional, Butynski, Thomas M., additional, Cronin, Drew, additional, d'Huart, Jean‐Pierre, additional, Da Re, Daniele, additional, de Jong, Yvonne A., additional, Dheer, Arjun, additional, Fei, Li, additional, Gallina, Sonia, additional, Goodrich, John M., additional, Harihar, Abishek, additional, Lopez Gonzalez, Carlos A., additional, King, Sarah R. B., additional, Lewison, Rebecca L., additional, de Melo, Fabiano R., additional, Napolitano, Constanza, additional, Rahman, Dede Aulia, additional, Robinson, Phillip T., additional, Robinson, Timothy, additional, Rondinini, Carlo, additional, Semiadi, Gono, additional, Strier, Karen, additional, Talebi, Mauricio, additional, Taylor, William Andrew, additional, Thiel‐Bender, Christine, additional, Ting, Nelson, additional, and Wiesel, Ingrid, additional

Published
2023
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13. List of contributors

Author

Acosta-Lagrada, Levita, primary, Ades, Gary, additional, Ahlers, Nick, additional, Akrim, Faraz, additional, Alempijevic, Daniel, additional, Alvarado, Dexter, additional, Andleeb, Shaista, additional, Assovi, Brou Guy-Mathieu, additional, Ayebare, Sam, additional, Billet, Guillaume, additional, Bonebrake, Timothy C., additional, Boopal, Anbarasi, additional, Bruce, Tom, additional, Burgess, Gayle, additional, Cabana, Francis, additional, Cassidy, Rod, additional, Cassidy, Tamar, additional, Challender, Daniel W.S., additional, Chao, Jung-Tai, additional, Cheema, Shavez, additional, Chen, Tina Ting-Yu, additional, Cheng, Wenda, additional, Chin, Jason Shih-Chien, additional, Chong, Ju Lian, additional, Chung, Yi Fei, additional, Cooney, Rosie, additional, Dalton, Desire Lee, additional, Davenport, Tim R.B., additional, Di Minin, Enrico, additional, Dublin, Holly, additional, Ferreira-Cardoso, Sérgio, additional, Fletcher, Louise, additional, Fowler, Andrew, additional, Gaubert, Philippe, additional, Gaudin, Timothy J., additional, Gudehus, Maja, additional, Hai, Lam Kim, additional, Harrop, Stuart R., additional, Hart, John, additional, Hart, Terese, additional, Hausmann, Anna, additional, Hautier, Lionel, additional, Hega, Martin, additional, Heighton, Sean P., additional, Heinrich, Sarah, additional, Hoffmann, Michael, additional, Hoffmann, Rachel, additional, Ichu, Ichu Godwill, additional, Ingram, Daniel J., additional, Irshad, Nausheen, additional, Jang-Liaw, Nian-Hong, additional, Jansen, Raymond, additional, Jiang, Zhigang, additional, Jimerson, Jessica, additional, Kao, Jim, additional, Kaspal, Prativa, additional, Katsis, Lydia K.D., additional, Khatiwada, Ambika P., additional, Kotze, Antoinette, additional, Kurniawan, Ade, additional, Lapuente, Juan, additional, Lawrence, Natalie, additional, Lee, Paige B., additional, Lees, Caroline, additional, Li, Chenny, additional, Li, Hou-Feng, additional, Li, Jocy Yu-Wen, additional, Lim, Norman T-L, additional, Lin, Chung-Chi, additional, Lo, Flora Hsuan-Yi, additional, Lourens, Karin, additional, Luz, Sonja, additional, Mahmood, Tariq, additional, Maisels, Fiona, additional, Mills, David, additional, Mohapatra, Rajesh Kumar, additional, Morin, Dana J., additional, Nash, Helen C., additional, Ndjassi, Constant, additional, Nebe, Bruno, additional, Niskanen, Leo, additional, Nixon, Stuart, additional, Ogden, Rob, additional, Olmedo, Alegria, additional, Olsson, Annette, additional, O’Criodain, Colman, additional, Panaino, Wendy, additional, Panda, Sudarsan, additional, Panjang, Elisa, additional, Parker, Keri, additional, Paudel, Kumar, additional, Perera, Priyan, additional, Pietersen, Darren W., additional, Plowman, Christian, additional, Rankin, Paul, additional, Rao, Madhu, additional, Roberts, Amy, additional, Roe, Dilys, additional, Schoppe, Sabine, additional, Semiadi, Gono, additional, Sharma, Sandhya, additional, Shaw, Debbie, additional, Shepherd, Chris R., additional, Shirley, Matthew H., additional, Skinner, Diane, additional, Sodeinde, Olufemi, additional, Sodsai, Withoon, additional, Soewu, Durojaye, additional, Strange, Bee Choo Ng, additional, Sun, Nick Ching-Min, additional, Suwal, Tulshi Laxmi, additional, Swart, Jonathan, additional, Thapa, Sanjan, additional, Thomson, Paul, additional, Traylor-Holzer, Kathy, additional, ‘t Sas-Rolfes, Michael, additional, Veríssimo, Diogo, additional, Vishwanath, Akshay, additional, Walsh, Martin T., additional, Waseem, Muhammad, additional, Waterman, Carly, additional, Wible, John R., additional, Wicker, Leanne Vivian, additional, Willcox, Daniel, additional, Withers, Oliver, additional, Wright, Nicci, additional, Wright, Wendy, additional, Wu, Shibao, additional, Xing, Shuang, additional, Yu, Yishuang, additional, Zhang, Fuhua, additional, Zhang, Mingxia, additional, Zhou, Youlong, additional, and Zoltani, Tenke, additional

Published
2020
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14. Sunda pangolin Manis javanica (Desmarest, 1822)

Author

Chong, Ju Lian, primary, Panjang, Elisa, additional, Willcox, Daniel, additional, Nash, Helen C., additional, Semiadi, Gono, additional, Sodsai, Withoon, additional, Lim, Norman T-L, additional, Fletcher, Louise, additional, Kurniawan, Ade, additional, and Cheema, Shavez, additional

Published
2020
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15. Genome sequencing reveals fine scale diversification and reticulation history during speciation in Sus

Author

Frantz, Laurent AF, Schraiber, Joshua G, Madsen, Ole, Megens, Hendrik-Jan, Bosse, Mirte, Paudel, Yogesh, Semiadi, Gono, Meijaard, Erik, Li, Ning, Crooijmans, Richard PMA, Archibald, Alan L, Slatkin, Montgomery, Schook, Lawrence B, Larson, Greger, and Groenen, Martien AM

Abstract

Abstract Background Elucidating the process of speciation requires an in-depth understanding of the evolutionary history of the species in question. Studies that rely upon a limited number of genetic loci do not always reveal actual evolutionary history, and often confuse inferences related to phylogeny and speciation. Whole-genome data, however, can overcome this issue by providing a nearly unbiased window into the patterns and processes of speciation. In order to reveal the complexity of the speciation process, we sequenced and analyzed the genomes of 10 wild pigs, representing morphologically or geographically well-defined species and subspecies of the genus Sus from insular and mainland Southeast Asia, and one African common warthog. Results Our data highlight the importance of past cyclical climatic fluctuations in facilitating the dispersal and isolation of populations, thus leading to the diversification of suids in one of the most species-rich regions of the world. Moreover, admixture analyses revealed extensive, intra- and inter-specific gene-flow that explains previous conflicting results obtained from a limited number of loci. We show that these multiple episodes of gene-flow resulted from both natural and human-mediated dispersal. Conclusions Our results demonstrate the importance of past climatic fluctuations and human mediated translocations in driving and complicating the process of speciation in island Southeast Asia. This case study demonstrates that genomics is a powerful tool to decipher the evolutionary history of a genus, and reveals the complexity of the process of speciation.

Published
2013

16. Correction to: Genome-wide SNP data unveils the globalization of domesticated pigs

Author

Yang, Bin, Cui, Leilei, Perez-Enciso, Miguel, Traspov, Aleksei, Crooijmans, Richard P. M. A., Zinovieva, Natalia, Schook, Lawrence B., Archibald, Alan, Gatphayak, Kesinee, Knorr, Christophe, Triantafyllidis, Alex, Alexandri, Panoraia, Semiadi, Gono, Hanotte, Olivier, Dias, Deodália, Dovč, Peter, Uimari, Pekka, Iacolina, Laura, Scandura, Massimo, Groenen, Martien A. M., Huang, Lusheng, and Megens, Hendrik-Jan

Published
2020
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17. Insights from 20 years of mammal population research in Indonesia

Author

Ardiantiono, A., Pinondang, Irene, Chandradewi, Desy S., Semiadi, Gono, Pattiselanno, Freddy, Supriatna, Jatna, Tasirin, John, Winarni, Nurul, Voigt, Maria, Bull, Joseph, Humle, Tatyana, Deere, Nicolas J., Struebig, Matthew J., Ardiantiono, A., Pinondang, Irene, Chandradewi, Desy S., Semiadi, Gono, Pattiselanno, Freddy, Supriatna, Jatna, Tasirin, John, Winarni, Nurul, Voigt, Maria, Bull, Joseph, Humle, Tatyana, Deere, Nicolas J., and Struebig, Matthew J.

Abstract

Mammal populations are declining in biodiverse tropical regions. Global analyses identify Indonesia as a hotspot of vertebrate decline, although relatively few data are available to substantiate these claims. We reviewed research articles from 2000 to 2020 on Indonesia’s 104 medium to large terrestrial mammal species to help inform conservation management and future research. We found 308 peer-reviewed studies published in English or Bahasa Indonesia, with an increase in publications over the years. Studies of species distributions dominated the literature, followed by publications on abundance, species diversity, and combinations of these topics. Most publications concerned single species conducted at a single location and time point. We identify four key knowledge gaps for future research and conservation efforts: 1) a disproportionate focus on a small number of species; 2) geographic bias to west Indonesia (Sumatra, Kalimantan, and Java-Bali) with few published studies from central (Sulawesi, Nusa Tenggara, and Maluku) and east (Papua) of the country; 3) limitations to survey design, sampling effort, and data analysis; and, 4) lack of long-term species population studies. We also noted challenges for local researchers to publish their studies in international journals due to language barriers and cost. Greater use of existing biodiversity data and continued capacity building of local researchers, particularly those in central and east Indonesia, are critical to effectively guide future wildlife monitoring and improve mammal conservation status.

Published
2023

19. The importance of correcting for sampling bias in MaxEnt species distribution models

Author

Kramer-Schadt, Stephanie, Niedballa, Jürgen, Pilgrim, John D., Schröder, Boris, Lindenborn, Jana, Reinfelder, Vanessa, Stillfried, Milena, Heckmann, Ilja, Scharf, Anne K., Augeri, Dave M., Cheyne, Susan M., Hearn, Andrew J., Ross, Joanna, Macdonald, David W., Mathai, John, Eaton, James, Marshall, Andrew J., Semiadi, Gono, Rustam, Rustam, Bernard, Henry, Alfred, Raymond, Samejima, Hiromitsu, Duckworth, J. W., Breitenmoser-Wuersten, Christine, Belant, Jerrold L., Hofer, Heribert, and Wilting, Andreas

Published
2013

20. Population trend and ecology of the most isolated deer in the world, Bawean deer (Axis kuhlii): conservation challenges.

Author

AULIA RAHMAN, DEDE, AULAGNIER, STÉPHANE, SUNDERLAND-GROVES, JACQUELINE L., and SEMIADI, GONO

Subjects
POPULATION ecology, DEER, DEER populations, WILD boar, COMMUNITY forests, HUMAN settlements, WHITE-tailed deer, DOGS
Abstract

Copyright of Therya is the property of Asociacion Mexicana de Mastozoologia, A. C. and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2023
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21. Genome-wide SNP data unveils the globalization of domesticated pigs

Author

Yang, Bin, Cui, Leilei, Perez-Enciso, Miguel, Traspov, Aleksei, Crooijmans, Richard P. M. A., Zinovieva, Natalia, Schook, Lawrence B., Archibald, Alan, Gatphayak, Kesinee, Knorr, Christophe, Triantafyllidis, Alex, Alexandri, Panoraia, Semiadi, Gono, Hanotte, Olivier, Dias, Deodália, Dovč, Peter, Uimari, Pekka, Iacolina, Laura, Scandura, Massimo, Groenen, Martien A. M., Huang, Lusheng, and Megens, Hendrik-Jan

Published
2017
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22. Exploring the vertebrate fauna of the Bird’s Head Peninsula (Indonesia, West Papua) through DNA barcodes

Author

Arida, Evy, Ashari, Hidayat, Dahruddin, Hadi, Fitriana, Yuli Sulistya, Hamidy, Amir, Irham, Mohammad, Kadarusman, Riyanto, Awal, Wiantoro, Sigit, Zein, Moch Syamsul Arifin, Hadiaty, Renny K., Apandi, Krey, Frengky, Kurnianingsih, Melmambessy, Edy H.p., Mulyadi, Ohee, Henderite L., Saidin, Salamuk, Ayub, Sauri, Sopian, Suparno, Supriatna, Nanang, Suruwaky, Amir M., Laksono, Wahyudi Tri, Warikar, Evie L., Wikanta, Hadi, Yohanita, Aksamina M., Slembrouck, Jacques, Legendre, Marc, Gaucher, Philippe, Cochet, Christophe, Delrieu‐trottin, Erwan, Thébaud, Christophe, Mila, Borja, Fouquet, Antoine, Borisenko, Alex, Steinke, Dirk, Hocdé, Régis, Semiadi, Gono, Pouyaud, Laurent, Hubert, Nicolas, Arida, Evy, Ashari, Hidayat, Dahruddin, Hadi, Fitriana, Yuli Sulistya, Hamidy, Amir, Irham, Mohammad, Kadarusman, Riyanto, Awal, Wiantoro, Sigit, Zein, Moch Syamsul Arifin, Hadiaty, Renny K., Apandi, Krey, Frengky, Kurnianingsih, Melmambessy, Edy H.p., Mulyadi, Ohee, Henderite L., Saidin, Salamuk, Ayub, Sauri, Sopian, Suparno, Supriatna, Nanang, Suruwaky, Amir M., Laksono, Wahyudi Tri, Warikar, Evie L., Wikanta, Hadi, Yohanita, Aksamina M., Slembrouck, Jacques, Legendre, Marc, Gaucher, Philippe, Cochet, Christophe, Delrieu‐trottin, Erwan, Thébaud, Christophe, Mila, Borja, Fouquet, Antoine, Borisenko, Alex, Steinke, Dirk, Hocdé, Régis, Semiadi, Gono, Pouyaud, Laurent, and Hubert, Nicolas

Abstract

Biodiversity knowledge is widely heterogeneous across the Earth’s biomes. Some areas, due to their remoteness and difficult access, present large taxonomic knowledge gaps. Mostly located in the tropics, these areas have frequently experienced a fast development of anthropogenic activities during the last decades and are therefore of high conservation concerns. The biodiversity hotspots of Southeast Asia exemplify the stakes faced by tropical countries. While the hotspots of Sundaland (Java, Sumatra, Borneo) and Wallacea (Sulawesi, Moluccas) have long attracted the attention of biologists and conservationists alike, extensive parts of the Sahul area, in particular the island of New Guinea, have been much less explored biologically. Here, we describe the results of a DNA‐based inventory of aquatic and terrestrial vertebrate communities, which was the objective of a multi‐disciplinary expedition to the Bird’s Head Peninsula (West Papua, Indonesia) conducted between October 17th and November 20th 2014. This expedition resulted in the assembly of 1,005 vertebrate DNA barcodes. Based on the use of multiple species‐delimitation methods (GMYC, PTP, RESL, ABGD), 264 Molecular Operational Taxonomic Units (MOTUs) were delineated, among which 75 were unidentified and an additional 48 were considered cryptic. This study suggests that the diversity of vertebrates of the Bird’s Head is severely underestimated and considerations on the evolutionary origin and taxonomic knowledge of these biotas are discussed.

Published
2021
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23. Exploring the vertebrate fauna of the Bird’s Head Peninsula (Indonesia, West Papua) through DNA barcodes

Author

Institut de Recherche pour le Développement (France), Indonesian Institute of Sciences, Institut Français Indonesia, Ambassade de France à Jakarta, Colas Group, Arida, Evy, Ashari, Hidayat, Dahruddin, Hadi, Fitriana, Yuli, Hamidy, Amir, Irham, Mohammad, Kadarusman, Riyanto, Awal, Wiantoro, Sigit, Arifin Zein, Moch Syamsul, Hadiaty, Renny K., Apandi, Krey, Frengky, Kurnianingsih, Melmambessy, Edy H.P., Mulyadi, Ohee, Henderite, Saidin, Salamuk, Ayub, Sauri, Sopian, Suparno, Supriatna, Nanang, Sruwaky, Amir M., Tri Laksono, Wahyudi, Warikar, Evie L., Wikanta, Hadi, Yohanita, Aksamina M., Slembrouck, Jacques, Legendre, Marc, Gaucher, Philippe, Cochet, Christophe, Delrieu-Trottin, Erwan, Thébaud, Christophe, Milá, Borja, Fouquet, Antoine, Borisenko, Alex, Steinke, Dirk, Hocdé, Régis, Semiadi, Gono, Pouyaud, Laurent, Hubert, Nicolas, Institut de Recherche pour le Développement (France), Indonesian Institute of Sciences, Institut Français Indonesia, Ambassade de France à Jakarta, Colas Group, Arida, Evy, Ashari, Hidayat, Dahruddin, Hadi, Fitriana, Yuli, Hamidy, Amir, Irham, Mohammad, Kadarusman, Riyanto, Awal, Wiantoro, Sigit, Arifin Zein, Moch Syamsul, Hadiaty, Renny K., Apandi, Krey, Frengky, Kurnianingsih, Melmambessy, Edy H.P., Mulyadi, Ohee, Henderite, Saidin, Salamuk, Ayub, Sauri, Sopian, Suparno, Supriatna, Nanang, Sruwaky, Amir M., Tri Laksono, Wahyudi, Warikar, Evie L., Wikanta, Hadi, Yohanita, Aksamina M., Slembrouck, Jacques, Legendre, Marc, Gaucher, Philippe, Cochet, Christophe, Delrieu-Trottin, Erwan, Thébaud, Christophe, Milá, Borja, Fouquet, Antoine, Borisenko, Alex, Steinke, Dirk, Hocdé, Régis, Semiadi, Gono, Pouyaud, Laurent, and Hubert, Nicolas

Abstract

Biodiversity knowledge is widely heterogeneous across the Earth's biomes. Some areas, due to their remoteness and difficult access, present large taxonomic knowledge gaps. Mostly located in the tropics, these areas have frequently experienced a fast development of anthropogenic activities during the last decades and are therefore of high conservation concerns. The biodiversity hotspots of Southeast Asia exemplify the stakes faced by tropical countries. While the hotspots of Sundaland (Java, Sumatra, Borneo) and Wallacea (Sulawesi, Moluccas) have long attracted the attention of biologists and conservationists alike, extensive parts of the Sahul area, in particular the island of New Guinea, have been much less explored biologically. Here, we describe the results of a DNA-based inventory of aquatic and terrestrial vertebratecommunities, which was the objective of a multidisciplinary expedition to the Bird's Head Peninsula (West Papua, Indonesia) conducted between 17 October and 20 November 2014. This expedition resulted in the assembly of 1005 vertebrate DNA barcodes. Based on the use of multiple species-delimitation methods (GMYC, PTP, RESL, ABGD), 264 molecular operational taxonomic units (MOTUs) were delineated, among which 75 were unidentified and an additional 48 were considered cryptic. This study suggests that the diversity of vertebrates of the Bird's Head is severely underestimated and considerations on the evolutionary origin and taxonomic knowledge of these biotas are discussed.

Published
2021

25. Correction to:Genome-wide SNP data unveils the globalization of domesticated pigs (Genet Sel Evol (2017) 49: 71 DOI: 10.1186/s12711-017-0345-y)

Author

Yang, Bin, Cui, Leilei, Perez-Enciso, Miguel, Traspov, Aleksei, Crooijmans, Richard P.M.A., Zinovieva, Natalia, Schook, Lawrence B., Archibald, Alan, Gatphayak, Kesinee, Knorr, Christophe, Triantafyllidis, Alex, Alexandri, Panoraia, Semiadi, Gono, Hanotte, Olivier, Dias, Deodália, Dovč, Peter, Uimari, Pekka, Iacolina, Laura, Scandura, Massimo, Groenen, Martien A.M., Huang, Lusheng, and Megens, Hendrik Jan

Abstract

After publication of this work [1], we noticed that information regarding the university is missing in the affiliation for Bin Yang, Leilei Cui and Lusheng Huang (affiliation 1). The correct affiliation should be: National Key Laboratory for Pig Genetic Improvement and Production Technology, Jiangxi Agricultural University, Nanchang, China.

Published
2020
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26. IdentiĮcation of conĮscated pangolin for conservation purposes through molecular approach.

Author

Wirdateti, Nugraha, R. TauĮƋ P., zulianto, and Semiadi, Gono

Subjects
WILD animal trade, ENDANGERED species, GENETIC markers, GENETIC distance, PANGOLINS
Abstract

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Published
2022
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31. Data from: Genome-wide SNP data unveils the globalization of domesticated pigs

Author

Yang, Bin, Cui, Leilei, Pérez-Enciso, Miguel, Traspov, Aleksei, Crooijmans, Richard P. M. A., Zinovieva, Natalia, Schook, Lawrence B., Archibald, Alan L., Gatphayak, Kesinee, Knorr, Christophe, Triantafyllidis, Alex, Alexandri, Panoraia, Semiadi, Gono, Hanotte, Olivier, Dias, Deodália, Dovč, Peter, Uimari, Pekka, Iacolina, Laura, Scandura, Massimo, Groenen, Martien A. M., Huang, Lusheng, Megens, Hendrik-Jan, Yang, Bin, Cui, Leilei, Pérez-Enciso, Miguel, Traspov, Aleksei, Crooijmans, Richard P. M. A., Zinovieva, Natalia, Schook, Lawrence B., Archibald, Alan L., Gatphayak, Kesinee, Knorr, Christophe, Triantafyllidis, Alex, Alexandri, Panoraia, Semiadi, Gono, Hanotte, Olivier, Dias, Deodália, Dovč, Peter, Uimari, Pekka, Iacolina, Laura, Scandura, Massimo, Groenen, Martien A. M., Huang, Lusheng, and Megens, Hendrik-Jan

Abstract

[Background]: Pigs were domesticated independently in Eastern and Western Eurasia early during the agricultural revolution, and have since been transported and traded across the globe. Here, we present a worldwide survey on 60K genome-wide single nucleotide polymorphism (SNP) data for 2093 pigs, including 1839 domestic pigs representing 122 local and commercial breeds, 215 wild boars, and 39 out-group suids, from Asia, Europe, America, Oceania and Africa. The aim of this study was to infer global patterns in pig domestication and diversity related to demography, migration, and selection., [Results]: A deep phylogeographic division reflects the dichotomy between early domestication centers. In the core Eastern and Western domestication regions, Chinese pigs show differentiation between breeds due to geographic isolation, whereas this is less pronounced in European pigs. The inferred European origin of pigs in the Americas, Africa, and Australia reflects European expansion during the sixteenth to nineteenth centuries. Human-mediated introgression, which is due, in particular, to importing Chinese pigs into the UK during the eighteenth and nineteenth centuries, played an important role in the formation of modern pig breeds. Inbreeding levels vary markedly between populations, from almost no runs of homozygosity (ROH) in a number of Asian wild boar populations, to up to 20% of the genome covered by ROH in a number of Southern European breeds. Commercial populations show moderate ROH statistics. For domesticated pigs and wild boars in Asia and Europe, we identified highly differentiated loci that include candidate genes related to muscle and body development, central nervous system, reproduction, and energy balance, which are putatively under artificial selection., [Conclusions]: Key events related to domestication, dispersal, and mixing of pigs from different regions are reflected in the 60K SNP data, including the globalization that has recently become full circle since Chinese pig breeders in the past decades started selecting Western breeds to improve local Chinese pigs. Furthermore, signatures of ongoing and past selection, acting at different times and on different genetic backgrounds, enhance our insight in the mechanism of domestication and selection. The global diversity statistics presented here highlight concerns for maintaining agrodiversity, but also provide a necessary framework for directing genetic conservation.

Published
2018

32. Melomys burtoni

Author

Fabre, Pierre-Henri, Fitriana, Yuli S., Semiadi, Gono, Pagès, Marie, Aplin, Ken, Supriatna, Nanang, and Helgen, Kristofer M.

Subjects
Muridae, Melomys, Melomys burtoni, Mammalia, Animalia, Rodentia, Biodiversity, Chordata, Taxonomy
Abstract

Melomys burtoni from Halmahera Referred specimens Ten specimens of Melomys burtoni from Halmahera were caught near the Gemaf and Sagea villages on June 2010 and September 2013 (MZB 33533, 33537, 33539, 33540, 33225, 36359, 36360, 36361, 36362, 36363), and eight specimens were collected on the South (MZB 33538) and North Ake Jira (Sake River; MZB 33223, 33224, 33226, 33534, 33536, 33541, 33552) in January 2010, 19 km NW of Gemaf and 26 km NW of Sagea at the GPS coordinates 00°37′23.8″N, 127°55′12.6″E (South Ake Jira) and 00°38′49.9″N, 127°56′01.2″E (North Ake Jira); Ake Sake (Sake River), 5 km NW of the village of Gemaf and 12 km NW of the village of Sagea, Central Halmahera, Halmahera Island, Indonesia, at an altitude of 22 m, at the GPS coordinates 00°29′14.6″N, 127°59′15.7″E (see Figure 1). Their current altitudinal range is 0 from 250 m. Seventeen specimens are prepared as study skins with accompanying skulls. Distribution Currently, Melomys burtoni from Halmahera is known only from the south-central region of the North Moluccan island of Halmahera (Figure 1). The species has been collected in lowland forest and forest edge habitats, at elevations between 0 and 250 m. We suspect that it may occur more broadly in other regions in the tropical lowland evergreen rain forest (Whitmore et al. 1984) in Halmahera, and on neighbouring islands such as Morotai and perhaps Bacan, but little is yet known of its biology and distribution. Previous efforts to survey the rodent fauna of Halmahera and adjacent islands (specimens deposited at AM, AMNH, MZB, USNM), which have documented two native rodent species (Rattus morotaiensis and Halmaheramys bokimekot) and several non-native rodents (Rattus exulans, R. tanezumi / R. rattus, and Mus), have not yet documented Melomys in other areas of Halmahera or on Morotai or Bacan. However, rodent collecting efforts in the North Moluccas have been very limited to date. Sampling was done at higher elevation in Halmahera by us (900– 1000 m, cf. boki mekot locality Fabre et al. 2013) and also other mammalogists (Flannery 1995a,b), but M. burtoni were never collected above 250 m. aMZB 33223-26; 33533-34; 33536-41; 33552. bBMNH .3.4.10.1; AU 24391-92. cAMNH 151204-215; 151217; 151223-227. dAMNH 105754-760; 105762-771; 105866; 105964-965; 105967-969. eAMNH 154116; 154120; 154123; 154125-126; 154128-129; 154131; 154133; 154135; 154136-138; 154140-141; 154144; 154149-153. aMZB 35961; AU 31923. bBMNH .20.7.26.26-27. cBMNH .20.7.26.21-25; BMNH.20.7.26.22. dBMNH .20.7.26.19-20. eBMNH .21.2.9.2. fBMNH .21.2.9.3. Measurements See Tables 4–6. Diagnosis Melomys burtoni from Halmahera can be distinguished from congeners by the following external characters: (1) relatively small body size, e.g. as compared to M. aerosus and M. fulgens of Seram (Helgen 2003) (Tate 1951, Menzies aMZB 33224-26; 33533-34; 33536-41; 33552. 1996, see also Figures 6 and 7; Tables 5 and 6); (2) head-body length is nearly equal to the tail length (103 % of the body length, but see also Figures 6 and 7) compared to the long-tailed M. obiensis (127 % of the body length); (3) dorsal fur dark brown or red-brown with dark gray bases; (4) ventral fur pure white along mid-ventral region of underparts and grayish on the sides; (5) dorsal surfaces of the forefeet and hindfeet pale brown with scattered rufous hairs; (6) tail usually dark above and below (some specimens have a paler underside), with three hairs per tail scale; (7) brown ears relatively long and large. Craniodental features diagnostic in combination include (1) a long rostrum, topped by broad nasals and slightly convex at the premaxillary tips (Figures 5, 8 and 9); (2) a narrow interorbital region with concave borders (Figure 8); (3) large palatine foramina (Figure 10), (4) long incisive foramina that extend posteriorly to the start of the molar rows (Figures 4, 5 and 10), (5) relatively longer incisive foramina and shorter tympanic bullae compared with all other species sampled here (Figures 4, 5 and 10). Following Menzies (1996), Melomys burtoni from Halmahera belongs within the “ cervinipes division” and more specifically is a member of the M. burtoni species group that includes M. burtoni of Australia, M. lutillus and M. frigicola of New Guinea, and four insular taxa distributed both west and east of New Guinea (M. bannisteri, M. cooperae, M. howi, M. paveli). Six species (M. aerosus, M. caurinus, M. fulgens, M. obiensis, M. fraterculus, M. talaudium) from the Moluccan region should not be included in this group due to lack of data as well as their relative morphological divergence. Description Melomys burtoni from Halmahera (Figures 6, 7, and 11) is relatively small in body size (head-body length 110–141 mm) with short, dense, and soft pelage. Dorsal fur ranges from dark-brown to red-brown; the hairs are bicolored, uniformly gray to blackish at the bases (the proximal 1/4 of the length) and brightly rufous distally. Dorsal guard hairs are soft, short, and pliable, project up to 7 mm beyond the overfur, and are glistening black for most of their length with some reddish tips. The ventral coat is pure white the length of the midventral region and grayish towards the flanks. We detect major chromatic differences between the pelage of an old adult (n = 1), and other adults (n = 15). The old individual MZB 53533 has an overall darker coat and large body size, but is molecularly identical to all other M. burtoni specimens from Halmahera. The studied juvenile (n = 1) display a finer and duller colour tone and a more greyish fur compared to the adults. The snout of Melomys burtoni from Halmahera is reddish-brown to yellowish above, and white on the sides and underside. The rhinarium and lips are unpigmented. The eyes are small (diameter about 5 mm). Vibrissae are dark gray. Mystacial and superciliary vibrissae are moderately long, extending slightly beyond the ears. The pinnae are relatively small and brown, with a sparse covering of reddish brown hairs on both the inner and outer surfaces. The tail is nearly equal in length to the combined head and body length (only exceeding HBL in the specimen MZB 33533) (Tables 4 and 6). The tail is dark brown to blackish on the entire surface, except for the proximal portion (10–25 mm), which is unpigmented in some specimens (MZB 33533, 33552). Tail scales are smooth and less raised compared to those in species of the M. rufescens Division (Menzies 1996), and moderately large (14–15 rows/cm). There are three hairs per tail scale (each 1–2 mm long), which is characteristic of the M. cervinipes Division, as described by Menzies (1996). Tail hairs are dark brown. Dorsal surfaces of the forefeet and hindfeet are pale brown or unpigmented (Figures 6) and sparsely covered with short reddish or brownish hairs on top of the metapodials and laterally on the digits. At the base of each claw, long white hairs form ungual tufts. The pollex is very short and bears a flat nail. The other front digits are longer and broader with curved, sharp, white claws. Each palmar surface is hairless, unpigmented, and displays three interdigital pads and two large metacarpal pads. The hindfeet of Melomys burtoni from Halmahera are shorter than those of M. obiensis and those of M. frigicola (Tables 4 and 5). Digits are elongated and broad, and each bears a pale claw that is short, sharp, and recurved. The hallux extends past the middle part of the medial digits. The 5th digit is slightly shorter than the medial digits and has a large associated interdigital pad. The plantar surface is naked and unpigmented, with four large interdigital pads, an elongate thenar pad, and a very small hypothenar pad. As in all Melomys species, it has only two pairs of inguinal teats (0 + 2 = 4). The skull of Melomys burtoni from Halmahera (Figure 11) is smaller than most Moluccan species of Melomys and similar to M. burtoni and allies in most dimensions (Figures 4, 8–10). In dorsal view, the rostrum is narrow and short (Figure 11). The interorbital region is moderately narrow and defined by concave borders. The postorbital region is elongate and the inflated braincase has a rounded outline. The temporal ridges that extend from the supraorbital region to the dorsolateral surfaces of the braincase are slightly developed. Robust zygomatic arches bow out from rostrum and braincase. In lateral view (Figures 9 and 11), the dorsal profile of the skull is broadly convex from the slightly depressed nasal tips to the top of the frontals, straight over the frontals and parietals to the apex of the domed braincase, and sloping abruptly downward over the length of the interparietal. Nasal bones are short with sloping sides that give an angular shape to the tip of the rostrum. The posterior portion of the nasals are flat with nearly no concavity at the junction with the proximal end of the frontal. The zygomatic plate is narrower and the zygomatic notch shallower than in other Moluccan Melomys. The dorsal root and anterior portion of the zygomatic arch are slightly broadened. The squamosal root of the arch is positioned at the medial portion of the braincase. A subsquamosal fenestra is not present. Each auditory bulla is small (Figures 4, 5, 10, and 11) and separated from the squamosal by a small postglenoid vacuity and from the alisphenoid by a narrow middle lacerate foramen. The lambdoid crest is poorly developed. The ventral view of the skull (Figures 10 and 11) shows long incisive foramina (Figures 4 and 5) that project posteriorly beyond the anterior margins of the first molars. The palate is narrow (BPPM1 and BPPM3) and short (LBP). Each palatine foramen is large, positioned between the anterior and posterior roots of the M2, and opens anteriorly into a well-defined palatal sulcus that runs forward to the posterolateral margin of the incisive foramina. The mesopterygoid fossa is moderately broad. The lateral pterygoid fossae are shallow and contain large sphenopterygoid vacuities. The skull exhibits bony landmarks consistent with the primitive pattern of cephalic arterial circulation found in most murine rodents (Musser and Heaney 1992), as in other Melomys (Menzies 1996). The upper and lower molars of Melomys burtoni from Halmahera are brachydont and broader compared to M. lutillus from Papua and M. burtoni from Australia (Figures 12 and 13; Tables 6 and 7). Each molar overlaps with its neighbour. The first upper and lower molars form nearly half of the entire toothrow, the second about onethird of the row, with the last molar much smaller than the others (Figures 12 and 13). The transverse laminae of the upper molars (rows 1 and 2 of M1 and row 2 of M2) display a posteriorly oriented, angular U-shape with a typically acuspidate chevron pattern (characteristic of Melomys, Paramelomys and Uromys). The first row is formed by a medium-sized cusp t1 slightly separated from a wide central cusp t2, which in turn is broadly fused with a smaller cusp t3. The second row is composed of a large backward-directed lingual cusp t4 that is attached to a wide and narrow central cusp t5 and a large labial cusp t6, which is smaller than t4. The third row is formed by a large, angular cusp t8 joined to a cusp t9 that projects straight to the labial side. The second molar consists of two laminae with a medium-sized cusp t1. The first lower molar has an oblong outline and three rows of cusps (Figure 13). The anterior 2/3 of the molar is formed by small anterolingual and anterolabial cusps that are slightly separated in unworn teeth from the second cusp row (metaconid, protoconid). The metaconid and protoconid are large, with a triangular shape, and fused in specimens displaying worn teeth (e.g. MZB 33533; Figure 13). A large entoconid and hypoconid comprise the third cusp row, behind which is a broad but anteroposteriorly narrow posterior cingulum. The subsquare second lower molar has two cusp rows and a posterior cingulum. The pattern and shape of the lamina are similar in cusp shape and pattern to first lower molar. There is a small anterolabial cusplet on the anterolabial margin of the second lower molar close to the protoconid. The small third lower molar displays a rounded shape and a simple occlusal surface with two laminar cusp rows and a posterior cingulum. The molars of Melomys burtoni from Halmahera have multiple roots, which were identified by a µCT scanner. Below each first upper molar, we found one large anterior root, two smaller lingual anchors, one labial root and one large posterior root. Four roots anchor each second molar, there are two anterior roots and two posterior anchor. Three roots anchor each third molar, there are two anterior roots and one posterior anchor. One anterior and posterior roots coupled with smaller labial and lingual anchors attach to each first lower molar. The second lower molars are anchored by two anterior and two posterior roots. The third lower molars are anchored by two anterior and one posterior roots. The alveoli patterns of upper and lower molar roots seen in Melomys burtoni from Halmahera are similar to the patterns found for M. lutillus from Papua and M. burtoni from Australia. Each dentary of Melomys burtoni from Halmahera is moderately long and stocky (Figure 11), with a short but stout coronoid process, robust condylar process and strong angular process. There is a concave curvature of the posterior margin of the dentary. The capsular process forms a prominent ridge parallel to the coronoid and anterior part of the condylar process. A prominent masseteric crest extends between the ventral margin and the labial part of the dentary just before the mental foramen. The mandibular foramen is located above a narrow ridge that runs caudally from the molar platform to the base of the condylar process., Published as part of Fabre, Pierre-Henri, Fitriana, Yuli S., Semiadi, Gono, Pagès, Marie, Aplin, Ken, Supriatna, Nanang & Helgen, Kristofer M., 2018, New record of Melomys burtoni (Mammalia, Rodentia, Murinae) from Halmahera (North Moluccas, Indonesia): a review of Moluccan Melomys, pp. 218-247 in Mammalia (Warsaw, Poland) (Warsaw, Poland) 82 (3) on pages 228-237, DOI: 10.1515/mammalia-2016-0137, http://zenodo.org/record/7837666, {"references":["Whitmore, T. C. 1984. Tropical rain forests of the Far East. Second edition. Oxford University Press, Oxford.","Fabre, P. - H., M. Pages, G. G. Musser, Y. S. Fitriana, J. Fjeldsa, A. Jennings, K. A. JOnsson, J. Kennedy, J. Michaux, G. Semiadi, N. Supriatna and K. M. Helgen. 2013. A new genus of rodent from Wallacea (Rodentia: Muridae: Murinae: Rattini), and its implication for biogeography and Indo-Pacific Rattini systematics. Zool. J. Linnean Soc. 169: 408 - 447.","Flannery, T. F. 1995 a. Mammals of the south-west Pacific and Moluccan Islands. Reed Books, Chatswood, New South Wales, Australia.","Helgen, K. M. 2003. A review of the rodent fauna of Seram, Moluccas, with the description of a new subspecies of mosaic-tailed rat, MelomyS rUfeScenS paVeli. J. Zool. (London) 261: 165 - 172.","Tate, G. H. H. 1951. Results of the Archbold Expeditions. No. 65. The rodents of Australia and New Guinea. Bull. Am. Mus. Nat. Hist. 97: 183 - 430.","Menzies, J. I. 1996. A systematic revision of MelomyS (Rodentia: Muridae) of New Guinea. Aust. J. Zool. 44: 367 - 426.","Musser, G. G. and L. R. Heaney. 1992. Philippine rodents: definitions of TarSomyS and LimnomyS plus a preliminary assessment of phylogenetic patterns among native Philippine murines (Murinae, Muridae). Bull. Am. Mus. Nat. Hist. 211: 1 - 138."]}

Published
2017
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33. Melomys Thomas 1922

Author

Fabre, Pierre-Henri, Fitriana, Yuli S., Semiadi, Gono, Pagès, Marie, Aplin, Ken, Supriatna, Nanang, and Helgen, Kristofer M.

Subjects
Muridae, Melomys, Mammalia, Animalia, Rodentia, Biodiversity, Chordata, Taxonomy
Abstract

Melomys Thomas 1922a Type species Melomys rufescens (Alston 1877), by original designation. Diagnosis p = p-value. (cp Melomys is a murid genus classified in the subfamily Murinae (sensu Musser and Carleton 2005), within the tribe Hydromyini (Aplin and Helgen 2010), in the “ Uromys Legend similar to that of Table 1. The symbol “:” indicates tested interactions between explanatory variables. (ap < 0.05, bp Paramelomys (cf. Menzies 1996), (6) narrow and deep pterygoid fossae, (7) lateral extension of the parietal bone, (8) a wide alisphenoid strut that is fused to the alisphenoid canal and foramen ovale, (9) very well-developed lambdoid crests which curl forward over the squamoso-mastoid foramen, (10) a carotid arterial circulation that is primitive for murine rodents, as opposed to the derived pattern seen in Mammelomys (11) a large M 3 compared to Paramelomys, with an antero-internal cusp always present, and (12) only two pairs of inguinal teats (mammary formula 0 + 2 = 4). The Melomys population from Halmahera is characterized by small to medium body size in the genus (Weight range = 110–141 g), and has all of the diagnostic characters listed above. Content and distribution. The genus Melomys contains 23 species (Musser and Carleton 2005). It is distributed in eastern and northern Australia, throughout New Guinea, and in adjacent archipelagos, from the Moluccas in the west to the Solomon Islands in the east (Helgen 2003, Breed and Aplin 2008)., Published as part of Fabre, Pierre-Henri, Fitriana, Yuli S., Semiadi, Gono, Pagès, Marie, Aplin, Ken, Supriatna, Nanang & Helgen, Kristofer M., 2018, New record of Melomys burtoni (Mammalia, Rodentia, Murinae) from Halmahera (North Moluccas, Indonesia): a review of Moluccan Melomys, pp. 218-247 in Mammalia (Warsaw, Poland) (Warsaw, Poland) 82 (3) on pages 227-228, DOI: 10.1515/mammalia-2016-0137, http://zenodo.org/record/7837666, {"references":["Thomas, O. 1922 a. A subdivision of the genus UromyS. Ann. Mag. Nat. Hist. (series 9) 9: 260 - 261.","Alston, E. R. 1877. On the rodents and marsupials collected by the Rev. G. Brown in Duke of York Island, New Britain and New Ireland. Proceedings of the Zoological Society of London 1877: 123 - 127.","Musser, G. G. and M. D. Carleton. 2005. Superfamily Muroidea.","Aplin, K. P., Helgen, K. M. 2010. Quaternary murid rodents of Timor. Part I: New material of CoryphomyS bUehleri Schaub, 1937, and description of a second species of the genus. Bull. Am. Mus. Nat. Hist. 341: 1 - 80.","Menzies, J. I. 1996. A systematic revision of MelomyS (Rodentia: Muridae) of New Guinea. Aust. J. Zool. 44: 367 - 426.","Helgen, K. M. 2003. A review of the rodent fauna of Seram, Moluccas, with the description of a new subspecies of mosaic-tailed rat, MelomyS rUfeScenS paVeli. J. Zool. (London) 261: 165 - 172.","Breed, W. G. and K. P. Aplin. 2008. The ' UromyS Group': Papuan"]}

Published
2017
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35. Genome-wide SNP data unveils the globalization of domesticated pigs

Author

Agriculture Research System of China, Agro-scientific Research in the Public Interest (China), Ministerio de Economía y Competitividad (España), European Commission, Yang, Bin, Cui, Leilei, Pérez-Enciso, Miguel, Traspov, Aleksei, Crooijmans, Richard P. M. A., Zinovieva, Natalia, Schook, Lawrence B., Archibald, Alan L., Gatphayak, Kesinee, Knorr, Christophe, Triantafyllidis, Alex, Alexandri, Panoraia, Semiadi, Gono, Hanotte, Olivier, Dias, Deodália, Dovč, Peter, Uimari, Pekka, Iacolina, Laura, Scandura, Massimo, Groenen, Martien A. M., Huang, Lusheng, Megens, Hendrik-Jan, Agriculture Research System of China, Agro-scientific Research in the Public Interest (China), Ministerio de Economía y Competitividad (España), European Commission, Yang, Bin, Cui, Leilei, Pérez-Enciso, Miguel, Traspov, Aleksei, Crooijmans, Richard P. M. A., Zinovieva, Natalia, Schook, Lawrence B., Archibald, Alan L., Gatphayak, Kesinee, Knorr, Christophe, Triantafyllidis, Alex, Alexandri, Panoraia, Semiadi, Gono, Hanotte, Olivier, Dias, Deodália, Dovč, Peter, Uimari, Pekka, Iacolina, Laura, Scandura, Massimo, Groenen, Martien A. M., Huang, Lusheng, and Megens, Hendrik-Jan

Abstract

[Background]: Pigs were domesticated independently in Eastern and Western Eurasia early during the agricultural revolution, and have since been transported and traded across the globe. Here, we present a worldwide survey on 60K genome-wide single nucleotide polymorphism (SNP) data for 2093 pigs, including 1839 domestic pigs representing 122 local and commercial breeds, 215 wild boars, and 39 out-group suids, from Asia, Europe, America, Oceania and Africa. The aim of this study was to infer global patterns in pig domestication and diversity related to demography, migration, and selection., [Results]: A deep phylogeographic division reflects the dichotomy between early domestication centers. In the core Eastern and Western domestication regions, Chinese pigs show differentiation between breeds due to geographic isolation, whereas this is less pronounced in European pigs. The inferred European origin of pigs in the Americas, Africa, and Australia reflects European expansion during the sixteenth to nineteenth centuries. Human-mediated introgression, which is due, in particular, to importing Chinese pigs into the UK during the eighteenth and nineteenth centuries, played an important role in the formation of modern pig breeds. Inbreeding levels vary markedly between populations, from almost no runs of homozygosity (ROH) in a number of Asian wild boar populations, to up to 20% of the genome covered by ROH in a number of Southern European breeds. Commercial populations show moderate ROH statistics. For domesticated pigs and wild boars in Asia and Europe, we identified highly differentiated loci that include candidate genes related to muscle and body development, central nervous system, reproduction, and energy balance, which are putatively under artificial selection., [Conclusions]: Key events related to domestication, dispersal, and mixing of pigs from different regions are reflected in the 60K SNP data, including the globalization that has recently become full circle since Chinese pig breeders in the past decades started selecting Western breeds to improve local Chinese pigs. Furthermore, signatures of ongoing and past selection, acting at different times and on different genetic backgrounds, enhance our insight in the mechanism of domestication and selection. The global diversity statistics presented here highlight concerns for maintaining agrodiversity, but also provide a necessary framework for directing genetic conservation.

Published
2017

36. Data from: Genome-wide SNP data unveils the globalization of domesticated pigs

Author

Yang, Bin, Cui, Leilei, Pérez-Enciso, M., Traspov, Aleksei, Crooijmans, R.P.M.A., Zinovieva, Natalia, Schook, Lawrence B., Gatphayak, Kesinee, Knorr, Christophe, Triantafyllidis, Alex, Alexandri, Panoraia, Semiadi, Gono, Hanotte, Olivier, Dias, Deodália, Dovč, Peter, Uimari, Pekka, Iacolina, Laura, Scandura, Massimo, Groenen, M., Huang, L., Megens, H.J.W.C., Yang, Bin, Cui, Leilei, Pérez-Enciso, M., Traspov, Aleksei, Crooijmans, R.P.M.A., Zinovieva, Natalia, Schook, Lawrence B., Gatphayak, Kesinee, Knorr, Christophe, Triantafyllidis, Alex, Alexandri, Panoraia, Semiadi, Gono, Hanotte, Olivier, Dias, Deodália, Dovč, Peter, Uimari, Pekka, Iacolina, Laura, Scandura, Massimo, Groenen, M., Huang, L., and Megens, H.J.W.C.

Abstract

Background: Pigs were domesticated independently in Eastern and Western Eurasia early during the agricultural revolution, and have since been transported and traded across the globe. Here, we present a worldwide survey on 60K genome-wide single nucleotide polymorphism (SNP) data for 2093 pigs, including 1839 domestic pigs representing 122 local and commercial breeds, 215 wild boars, and 39 out-group suids, from Asia, Europe, America, Oceania and Africa. The aim of this study was to infer global patterns in pig domestication and diversity related to demography, migration, and selection. Results: A deep phylogeographic division reflects the dichotomy between early domestication centers. In the core Eastern and Western domestication regions, Chinese pigs show differentiation between breeds due to geographic isolation, whereas this is less pronounced in European pigs. The inferred European origin of pigs in the Americas, Africa, and Australia reflects European expansion during the sixteenth to nineteenth centuries. Human-mediated introgression, which is due, in particular, to importing Chinese pigs into the UK during the eighteenth and nineteenth centuries, played an important role in the formation of modern pig breeds. Inbreeding levels vary markedly between populations, from almost no runs of homozygosity (ROH) in a number of Asian wild boar populations, to up to 20% of the genome covered by ROH in a number of Southern European breeds. Commercial populations show moderate ROH statistics. For domesticated pigs and wild boars in Asia and Europe, we identified highly differentiated loci that include candidate genes related to muscle and body development, central nervous system, reproduction, and energy balance, which are putatively under artificial selection. Conclusions: Key events related to domestication, dispersal, and mixing of pigs from different regions are reflected in the 60K SNP data, including the globalization that has recently become full circle since Chines

Published
2017

37. Targeted Conservation to Safeguard a Biodiversity Hotspot from Climate and Land-Cover Change

Author

Abdullah, Tajuddin, Abram, Nicola, Alfred, Raymond, Ancrenaz, Marc, Augeri, Dave M., Belant, Jerrold L., Bernard, Henry, Bezuijen, Mark, Boonman, Arjan, Boonratana, Ramesh, Boorsma, Tjalle, Breitenmoser-Würsten, Christine, Brodie, Jedediah, Cheyne, Susan M., Devens, Carolyn, Duckworth, J. Will, Duplaix, Nicole, Eaton, James, Francis, Charles, Fredriksson, Gabriella, Giordano, Anthony J., Gonner, Catherine, Hall, Jon, Harrison, Mark E., Hearn, Andrew J., Heckmann, Ilja, Heydon, Matt, Hofer, Heribert, Hon, Jason, Husson, Simon, Anwarali Khan, Faisal Ali, Kingston, Tigga, Kreb, Danielle, Lammertink, Martjan, Lane, David, Lasmana, Felicia, Liat, Lim Boo, Lim, Norman T-L., Lindenborn, Jana, Loken, Brent, Macdonald, David W., Marshall, Andrew J., Maryanto, Ibnu, Mathai, John, McShea, William J., Mohamed, Azlan, Nakabayashi, Miyabi, Nakashima, Yoshihiro, Niedballa, Jürgen, Noerfahmy, Sephy, Persey, Sophie, Peter, Amanda, Pieterse, Sander, Pilgrim, John D., Pollard, Edward, Purnama, Surya, Rafiastanto, Andjar, Reinfelder, Vanessa, Reusch, Christine, Robson, Craig, Ross, Joanna, Rustam, Rustam, Sadikin, Lili, Samejima, Hiromitsu, Santosa, Eddy, Sapari, Iman, Sasaki, Hiroshi, Scharf, Anne K., Semiadi, Gono, Shepherd, Chris R., Sykes, Rachel, van Berkel, Tim, Wells, Konstans, Wielstra, Ben, Wong, Anna, Struebig, Matthew J., Wilting, Andreas, Gaveau, David L.A., Meijaard, Erik, Smith, Robert J., Fischer, Manuela, Metcalfe, Kristian, and Kramer-Schadt, Stephanie

Published
2015
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42. Endogenous Gibbon Ape Leukemia Virus Identified in a Rodent (Melomys burtoni subsp.) from Wallacea (Indonesia)

Author

Alfano, Niccolò, primary, Michaux, Johan, additional, Morand, Serge, additional, Aplin, Ken, additional, Tsangaras, Kyriakos, additional, Löber, Ulrike, additional, Fabre, Pierre-Henri, additional, Fitriana, Yuli, additional, Semiadi, Gono, additional, Ishida, Yasuko, additional, Helgen, Kristofer M., additional, Roca, Alfred L., additional, Eiden, Maribeth V., additional, and Greenwood, Alex D., additional

Published
2016
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45. SKELETOCHRONOLOGY OF ASIAN GRASS FROG Fejervarya limnocharis (GRAVENHORST, 1829) FROM JAVA TO SUPPORT MANAGEMENT CONSERVATION.

Author

Phadmacanty, Ni Luh Putu Rischa, Hamidy, Amir, and Semiadi, Gono

Subjects
FROGS, SKELETOCHRONOLOGY, AMPHIBIANS, BIODIVERSITY, SPECIES distribution
Abstract

Asian grass frog Fejervarya limnocharis is being utilized as pets, for laboratory experiments, for a mixture of traditional medicine and for cuisine. The harvest of F. limnocharis in high volume can threat its population. Biological data such as the age when the specimens are harvested is valuable information to manage the harvesting system in sustainable way. We conducted the skeletochronology technique using paraffin methods and hematoxylin staining from 69 samples (46 males, 21 females, 2 juveniles). The results showed that the age harvested male ranged from 1 to 3 years old, while the female ranged from 2 to 3 years old. The snout-vent length (SVL) of harvested specimens ranges between 39.84-52.37 mm for both sexes. We propose an intervention in the harvesting system by limitation of the size for harvested specimens to at least 46 mm. In this minimum size, individuals of F. limnocharis have reproduced several times and have contributed to the population in the wild. [ABSTRACT FROM AUTHOR]

Published
2018

46. A new genus of rodent from Wallacea (Rodentia: Muridae: Murinae: Rattini), and its implication for biogeography and Indo-Pacific Rattini systematics

Author

Fabre, Pierre-Henri, Pages, Marie, Musser, Guy G., Fitriana, Yuli S., Fjeldså, Jon, Jennings, Andy, Jonsson, Knud A., Kennedy, Jonathan, Michaux, Johan, Semiadi, Gono, Supriatna, Nanang, Helgen, Kristofer M., University of Copenhagen = Københavns Universitet (KU), Centre de Biologie pour la Gestion des Populations (UMR CBGP), Centre de Coopération Internationale en Recherche Agronomique pour le Développement (Cirad)-Institut National de la Recherche Agronomique (INRA)-Centre international d'études supérieures en sciences agronomiques (Montpellier SupAgro)-Université de Montpellier (UM)-Institut de Recherche pour le Développement (IRD [France-Sud])-Institut national d’études supérieures agronomiques de Montpellier (Montpellier SupAgro), Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro)-Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro), Université de Liège, American Museum of Natural History (AMNH), Indonesian Inst Sci LIPI, Partenaires INRAE, Muséum national d'Histoire naturelle (MNHN), Smithsonian National Museum of Natural History (NMNH), Danish National Research Foundation, National Geographic Society Research and Exploration Grant [8853-10], National Geographic Society, Dybron Hoffs Foundation, FRS-FNRS fellowship (Belgian Fund for Scientific Research), SYNTHESYS Foundation [GB-TAF-2735], Celebes Fund, Archbold Expeditions, American Museum of Natural History, Lembaga Ilmu Pengetahuan Indonesia (LIPI), Museum Zoologicum Bogoriense (MZB) in Indonesia, network 'Bibliotheque du Vivant', CNRS, Museum National d'Histoire Naturelle, INRA, and CEA (Centre National de Sequencage)

Subjects
MITOCHONDRIAL-DNA, [SDV]Life Sciences [q-bio], GEOGRAPHIC RANGE, NUCLEAR GENES, Wallacea, SOFTWARE PACKAGE, DIVERGENCE TIMES, ENDEMIC RODENTS, EVOLUTIONARY HISTORY, PHYLOGENETIC-RELATIONSHIPS, morphology, MURORODENTS, Indo-Pacific, MAXIMUM-LIKELIHOOD, Rattini, biogeography, molecular systematics, biodiversity
Abstract

International audience; We describe Halmaheramys bokimekot Fabre, Pages, Musser, Fitriana, Semiadi & Helgengen.etsp.nov., a new genus and species of murine rodent from the North Moluccas, and study its phylogenetic placement using both molecular and morphological data. We generated a densely sampled mitochondrial and nuclear DNA data set that included most genera of Indo-Pacific Murinae, and used probabilistic methodologies to infer their phylogenetic relationships. To reconstruct their biogeographical history, we first dated the topology and then used a Lagrange analysis to infer ancestral geographic areas. Finally, we combined the ancestral area reconstructions with temporal information to compare patterns of murine colonization among Indo-Pacific archipelagos. We provide a new and comprehensive molecular phylogenetic reconstruction for Indo-Pacific Murinae, with a focus on the Rattus division. Using previous results and those presented in this study, we define a new Indo-Pacific group within the Rattus division, composed of Bullimus, Bunomys, Paruromys, Halmaheramys, Sundamys, and Taeromys. Our phylogenetic reconstructions revealed a relatively recent diversification from the Middle Miocene to Plio-Pleistocene associated with several major dispersal events. We identified two independent Indo-Pacific dispersal events from both western and eastern Indo-Pacific archipelagos to the isolated island of Halmahera, which led to the speciations of H.bokimekotgen.etsp.nov. and Rattus morotaiensis Kellogg, 1945. We propose that a Middle Miocene collision between the Halmahera and Sangihe arcs may have been responsible for the arrival of the ancestor of Halmaheramys to eastern Wallacea. Halmaheramys bokimekotgen. et sp.nov. is described in detail, and its systematics and biogeography are documented and illustrated.(c) 2013 The Linnean Society of London

Published
2013
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47. Conservation genomics reveals possible illegal trade routes and admixture across pangolin lineages in Southeast Asia.

Author

Nash, Helen C., Wirdateti, Low, Gabriel W., Choo, Siew Woh, Chong, Ju Lian, Semiadi, Gono, Hari, Ranjeev, Sulaiman, Muhammad Hafiz, Turvey, Samuel T., Evans, Theodore A., and Rheindt, Frank E.

Subjects
GENOMICS, GENOMES, GENETIC markers, PANGOLINS, WILDLIFE conservation
Abstract

The use of genome-wide genetic markers is an emerging approach for informing evidence-based management decisions for highly threatened species. Pangolins are the most heavily trafficked mammals across illegal wildlife trade globally, but critically endangered Sunda pangolins (Manis javanica) have not been widely studied in insular Southeast Asia. We used > 12,000 single nucleotide polymorphic markers (SNPs) to assign pangolin seizures from illegal trade of unknown origin to possible geographic sources via genetic clustering with pangolins of known origin. Our SNPs reveal three previously unrecognized genetic lineages of Sunda pangolins, possibly from Borneo, Java and Singapore/Sumatra. The seizure assignments suggest the majority of pangolins were traded from Borneo to Java. Using mitochondrial markers did not provide the same resolution of pangolin lineages, and to explore if admixture might explain these differences, we applied sophisticated tests of introgression using > 2000 SNPs to investigate secondary gene flow between each of the three Sunda pangolin lineages. It is possible the admixture which we discovered is due to human-mediated movements of pangolins. Our findings impact a range of conservation actions, including tracing patterns of trade, repatriation of rescue animals, and conservation breeding. In order to conserve genetic diversity, we suggest that, pending further research, each pangolin lineage should as a precaution be protected and managed as an evolutionarily distinct conservation unit. [ABSTRACT FROM AUTHOR]

Published
2018
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48. New record of <italic>Melomys burtoni</italic> (Mammalia, Rodentia, Murinae) from Halmahera (North Moluccas, Indonesia): a review of Moluccan <italic>Melomys</italic>.

Author

Fabre, Pierre-Henri, Fitriana, Yuli S., Semiadi, Gono, Pagès, Marie, Aplin, Ken, Supriatna, Nanang, and Helgen, Kristofer M.

Subjects
BIODIVERSITY, MELOMYS, VASCULAR plants, MAMMALS, ASTATOTILAPIA burtoni
Abstract

Mosaic-tailed rodents of the genus Melomys belong to the Australasian old endemic murine radiation and exhibit a rat-like morphology with arboreal or scansorial specializations. Here we report a new population of Melomys burtoni from the island of Halmahera (in the North Moluccas, Indonesia). Our molecular phylogenetic results highlight close relationships and recent evolutionary divergences among M. burtoni from Halmahera and the Australo-Papuan taxa M. burtoni and M. lutillus and other Moluccan taxa, including M. paveli. Multivariate as well as geometric morphometric analyses of cranial, and dental features support the recognition of M. burtoni from Halmahera as a slightly distinctive insular population, preventing us from elevating it as a new taxa. This population is recorded from lowland secondary forest and forest edge habitats in south-central Halmahera. As with other Moluccan endemic murines, colonization by an Australo-Papuan ancestor and subsequent isolation is the probable mode of diversification for M. burtoni in Halmahera. The discovery of Melomys in Halmahera fills a previously puzzling gap in knowledge of the murine fauna of the Moluccas and the biogeography of the Wallacean region. [ABSTRACT FROM AUTHOR]

Published
2018
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50. Targeted Conservation to Safeguard a Biodiversity Hotspot from Climate and Land-Cover Change

Author

Struebig, Matthew J., primary, Wilting, Andreas, additional, Gaveau, David L.A., additional, Meijaard, Erik, additional, Smith, Robert J., additional, Fischer, Manuela, additional, Metcalfe, Kristian, additional, Kramer-Schadt, Stephanie, additional, Abdullah, Tajuddin, additional, Abram, Nicola, additional, Alfred, Raymond, additional, Ancrenaz, Marc, additional, Augeri, Dave M., additional, Belant, Jerrold L., additional, Bernard, Henry, additional, Bezuijen, Mark, additional, Boonman, Arjan, additional, Boonratana, Ramesh, additional, Boorsma, Tjalle, additional, Breitenmoser-Würsten, Christine, additional, Brodie, Jedediah, additional, Cheyne, Susan M., additional, Devens, Carolyn, additional, Duckworth, J. Will, additional, Duplaix, Nicole, additional, Eaton, James, additional, Francis, Charles, additional, Fredriksson, Gabriella, additional, Giordano, Anthony J., additional, Gonner, Catherine, additional, Hall, Jon, additional, Harrison, Mark E., additional, Hearn, Andrew J., additional, Heckmann, Ilja, additional, Heydon, Matt, additional, Hofer, Heribert, additional, Hon, Jason, additional, Husson, Simon, additional, Anwarali Khan, Faisal Ali, additional, Kingston, Tigga, additional, Kreb, Danielle, additional, Lammertink, Martjan, additional, Lane, David, additional, Lasmana, Felicia, additional, Liat, Lim Boo, additional, Lim, Norman T-L., additional, Lindenborn, Jana, additional, Loken, Brent, additional, Macdonald, David W., additional, Marshall, Andrew J., additional, Maryanto, Ibnu, additional, Mathai, John, additional, McShea, William J., additional, Mohamed, Azlan, additional, Nakabayashi, Miyabi, additional, Nakashima, Yoshihiro, additional, Niedballa, Jürgen, additional, Noerfahmy, Sephy, additional, Persey, Sophie, additional, Peter, Amanda, additional, Pieterse, Sander, additional, Pilgrim, John D., additional, Pollard, Edward, additional, Purnama, Surya, additional, Rafiastanto, Andjar, additional, Reinfelder, Vanessa, additional, Reusch, Christine, additional, Robson, Craig, additional, Ross, Joanna, additional, Rustam, Rustam, additional, Sadikin, Lili, additional, Samejima, Hiromitsu, additional, Santosa, Eddy, additional, Sapari, Iman, additional, Sasaki, Hiroshi, additional, Scharf, Anne K., additional, Semiadi, Gono, additional, Shepherd, Chris R., additional, Sykes, Rachel, additional, van Berkel, Tim, additional, Wells, Konstans, additional, Wielstra, Ben, additional, and Wong, Anna, additional

Published
2015
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