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Jelena Vukojević – Citati (1979-2018)

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Jelena Vukojević – Citati (1979-2018) Citiranost dr Jelene Vukojević bez autocitata do februara 2019. godine iznoci 2175 puta u časopisima sa Kobson i Scopus lista i drugih baza, a koji nisu referisani u WoS bazi u trenutku kada je citat publikovan, zatim u knjigama, poglavljima knjiga i inostranim tezama. Citiranost prema godištu radova i citirane publikacije: 1985 Mihaljčević, M., Muntanola‐Cvetković, M., Vukojević, J., Petrov, M. (1985): Source of infection of sunflower plants by Diaporthe helianthi in Yugoslavia. Journal of Phytopathology, 113(4): 334-342. 1. Ploetz, R.C., Shokes, F. M. (1987): Factors influencing of soybean seedlind by southern Diaporthe phaseolorum. Phytopathology, 77: 786-790 2. Bertrand, F., Tourvieille, D. (1987): Phomopsis tournesol: test de sélection. Informations Techniques du Cetiom, 98: 12-18. 3. Fayret, J., Assemat, P. (1987) : Evolution du Diaporthe helianthi (Phomopsis helianti) Munt- Cvet et al. et différenciation desorganes reproducteurs sur les plants du tournesol après la période vegetation. Inform. Techniques CETIOM, 98: 2-11. 4. Jacobs, K.A., Glawe, A., Gray, L. E. (1988): Conidial nuclei in three species of Diatrypaceae and Diaporthe vaccinii. Mycologia, 80(3): 307-311. 5. Nyvall, R.F. (1989): Diseases of sunflowers. In Field Crop Diseases Handbook, pp. 639- 659. Springer, Boston, MA. 6. Maširević, S., Gulya, T.J. (1992): Sclerotinia and Phomopsis - two devastating sunflower pathogens. Field Crops Research, 30(3-4): 271-300. 7. Linders, E.G.A. (1996): A possible role of sexuality in the population structure of Diaporthe adunca, a pathogen of Plantago lanceolata. Plant pathology, 45(4): 697-709. 8. Linders, E.G.A., Van Damme, J.M.M., Zadoks, J.C. (1996): Transmission and overseasoning of Diaporthe adunca on Plantago lanceolata. Plant Patology, 45(1): 59-69. 9. Gulya, T.J. (1997): Phomopsis stem canker resistance in USDA and commercial sunflower germplasm. Proceedings of the 19 th Sunflower Res. 10. Heller, A., Gierth, K. (2001): Cytological observations of the infection process by Phomopsis helianthi Munt.‐Cvet. in leaves of sunflower. Journal of Phytopathology, 149(6): 347-357. 11. Kövics, Gy. J., Zsombik, L. (2001): A főbb ökológiai tényezők és a napraforgó Diaporthe helianthi fertőzöttségének összefüggései. Növénytermelés, 50(4): 395- 405. 12. Vergara, M., Capasso, T., Gobbi, E., Vannacci, G. (2005): Plasmid distribution in European Diaporthe helianthi isolates. Mycopathologia, 159(4): 591-599. 13. Диденко, А.О., Андросова, В.М. (2008): Образование аскоспор Diaporthe (Phomopsis) helianthi Munt.-Cvet. et al in vitro. In Биологическая Защита Растений – Основа Стабилизации Агроэкосистем, pp. 580-583. 14. Андросова, В.М., Балахнина, И.В., Диденко, А.О. (2010): Новые аспекты диагностики фомопсиса подсолнечника. In Биологическая защита растений-основа стабилизации агроэкосистем, pp. 198-213. 15. Thompson, S., Young, A., Shivas R. (2010): Phomopsis stem canker – An emerging disease of Australian sunflowers. Proceedings of the Australian Summer Grains Conference, Gold Coast, Australia, Edited paper. 16. Mathew, F.M., Alananbeh, K.M., Jordahl, J.G., Meyer, S.M., Castlebury, L.A., Gulya, T.J., Markell, S.G. (2015): Phomopsis stem canker: a reemerging threat to sunflower (Helianthus annuus) in the United States. Phytopathology, 105(7): 990-997. 17. Harveson, R., Mathew, F., Gulya, T., Markell, S., Block, C., Thompson, S. (2018): Sunflower stalk diseases initiated through leaf infections. Plant Health Progress, 19(1): 82- 91. 18. Mathew, F., Harveson, R., Gulya, T., Thompson, S., Block, C., Markell, S. (2018): Phomopsis stem canker of sunflower. Plant Health Instructor. DOI: 10.1094/PHI-I-2018- 1103-01. Muntañola-Cvetković, M., Mihaljčević, M., Vukojević, J., Petrov, M. (1985): Comparisons of Phomopsis isolates obtained from sunflower plants and debris in Yugoslavia. Transactions of the British Mycological Society, 85(3): 477-483. 1. Bertrand, F., Tourvieille, D. (1987): Phomopsis tournesol: test de sélection. Informations Techniques du Cetiom, 98: 12-18. 2. Fayret, J., Assemat, P. (1987) : Evolution du Diaporthe helianthi (Phomopsis helianti) Munt- Cvet et al. et différenciation desorganes reproducteurs sur les plants du tournesol après la période vegetation. Inform. Techniques CETIOM, 98: 2-11. 3. Donald, P.A., Venette and, J.R. Gulya, T.J. (1987): Relationship between Phoma macdonaldii and premature death of sunflower. Plant Disease, 71: 466–468. 4. Nyvall, R.F. (1989): Diseases of sunflowers. In Field Crop Diseases Handbook, pp. 639- 659. Springer, Boston. 5. Van der Aa, H.A.; Noordeloos, M. E.; Gruyter, J. de (1990): Species concepts in some larger genera of the Coelomycetes. Studies in Mycology, 32: 3-19. 6. Carriere, J.B., Petrov, M. (1990): Diaporthe (Phomosis) sp., a new pathogen of cocklbbur (Xanthium italicum Moretti) and of sunflower (Helianthus annuus L. ), Helia, 13(13): 93- 106 7. Maširević, S., Gulya, T.J. (1992): Sclerotinia and Phomopsis — two devastating sunflower pathogens. Field Crops Research, 30(3-4): 271-300. 8. Gulya, T.J. (1997): Phomopsis stem canker resistance in USDA and commercial sunflower germplasm. Proceedings of the 19th Sunflower Research. 9. Degener, J., Melchinger, A.E., Hahn, V. (1999): Resistance in the leaf and stem of sunflower after infection with two isolates of Phomopsis. Plant Breeding, 118(5): 405-410. 10. Thompson, S.M., Tan, Y.P., Oung, A.J., Neate, S.M., Aitken, E.A.B., Shivas, R.G. (2011): Stem cankers on sunflower (Helianthus annuus) in Australia reveal a complex of pathogenic Diaporthe (Phomopsis) species. Persoonia: Molecular Phylogeny and Evolution of Fungi, 27: 80-89. 11. Bansode, S.A. (2013): Mutagenesis and regeneration of sunfiower genotypes (Doctoral dissertation, Vasantrao Naik Marathwada Krishi Vidyapeeth, Parbhani). 12. Ivancovich, A., Lavilla, M. (2016): Cancro del tallo en girasol (Helianthus annus L.) causado por el complejo Diaporthe/Phomopsis helianthi Munt.-Cvet. Estación Experimental Agropecuaria Pergamino. Muntañola-Cvetković, M., Bojović-Cvetić, D., Vukojević, J. (1985): An ultrastructural study of - and -conidia in the fungal genus Phomopsis. Cryptogamie Mycolologie, 6: 171- 184. 1. De Nooij, M.P., Van Der Aa, H.A. (1987): Phomopsia subordinaria and associated stalk disease in natural populations of Plantago lanceolate. Canadian Journal of Botany, 65(22): 2318-2325. 2. Van der Aa, H.A.; Noordeloos, M. E.; Gruyter, J. de (1990): Species concepts in some larger genera of the Coelomycetes. Studies in Mycology, 32: 3-19. 3. Linders, E.G.A., Van Damme, J.M.M., Zadoks, J.C. (1996): Transmission and overseasoning of Diaporthe adunca on Plantago lanceolata. Plant Patology, 45(1): 59-69. 4. Linders, E.G., Hubertus, A., Vander, A. (1995): Taxonomy, sexuality and mating types of Diaporthe adunc. Mycological Research, 99(12): 1409-1416. 5. Rosskope, E.N., Charudattan, R., Shabana, Z.M., Benny, G.L. (2000): Phomopsis amaranthicola. a new specie from Amaranthus sp. Mycologia, 92(1): 114-122. 6. Sergeeva V, Nair, G, Barchia I, et al.(2003): Germination of ß conidia of Phomopsis viticola. Australasian Plant Patholohy, 32 (1): 105-107. 1988 Muntañola-Cvetković, M., Mihaljčević, M., Vukojević, J. (1988): Dosadašnji rezultati istraživanja Phomopsis/Diaporthe helianthi na suncokretu. I. Mikološki aspekti. Plant Protection, 39(4),186: 469-478. 1. Vrandecic, K., Jurkovic, D., Riccioni, L., Cosic, J., Duvnjak, T. (2010): Xanthium italicum, Xanthium strumarium and Arctium lappa as new hosts for Diaporthe helianthi. Mycopathologia, 170(1): 51-60. 2. Lesovoy, M.P., Parfenyuk, A.I., Vasilyuk, L.A. (1993): Phomopsis of sunflower in the Ukraine and the development of breeding methods for resistance. Archives of Phytopathology & Plant Protection, 28(4): 321-328. 1989 Muntañola-Cvetković, M., Vukojević, J., Mihaljčević, M. (1989): Pathohistology of sunflower stems attacked by Diaporthe helianthi. Canadian Journal of Botany, 67: 1119- 1125. 1. Carriere, J.B., Petrov, M. (1990): Diaporthe (Phomosis) sp., a new pathogen of cocklbbur (Xanthium italicum Moretti) and of sunflower (Helianthus annuus L.), Helia, 13(13): 93- 106. 2. Maširević, S., Gulya, T. J. (1992): Sclerotinia and Phomopsis—two devastating sunflower pathogens. Field Crops Research, 30(3-4): 271-300. 3. Peričin, D., Jarak, M., Antov, M., Dozet, B. (1994): Pectinase from Phomopsis helianthi - the agent of sunflower stem canker. Helia, 17(20): 21-30. 4. Gulya, T.J. (1997): Phomopsis stem canker resistance in USDA and commercial sunflower germplasm. Proceedings of the 19 th Sunflower Res. 5. Duletić-Laušević, S., Mihaljčević, M. (1998): Comparative anatomical analysis of the vascular system in selected Helianthus annuus genotypes. In Progress in Botanical Research, pp. 485-488. Springer, Dordrecht. 6. Deglene, L., Alibert, G., Lesigne, P., Delabrouhe, D.T., Sarrafi, A. (1999): Inheritance of resistance to stem canker (Phomopsis helianthi) in sunflower. Plant Pathology, 48(4): 559- 563. 7. Roustaee, A., Dechamp-Guillaume, G., Gelie, B., Savy, C., Dargent, R., Barrault, G. (2000): Ultrastructural studies of the mode of penetration by Phoma macdonaldii in sunflower seedlings. Phytopathology, 90(8): 915-920. 8. Heller, A., Gierth, K. (2001): Cytological observations of the infection process by Phomopsis helianthi Munt.‐Cvet. in leaves of sunflower. Journal of Phytopathology, 149(6): 347-357. 9. El-Sayed, W., Kang, Z., Hurle, K. (2002): Infection process of Phomopsis convolvulus as a mycoherbicide for Convolvulus arvensis L. Journal of Plant Diseases and Protection, 180- 192. 10. Debaeke, P., Estragnat,
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    Vascular flora inventory and plant diversity of the Ruvubu National Park, Burundi Tatien MASHARABU Marie Josée BIGENDAKO Université du Burundi, Faculté des Sciences, Département de Biologie, B.P. 2700 Bujumbura (Burundi) [email protected] Benoît NZIGIDAHERA Institut national pour l’Environnement et la Conservation de la Nature (INECN), B.P. 2757 Bujumbura (Burundi) Balthazar MPAWENAYO Université du Burundi, Faculté des Sciences, Département de Biologie, B.P. 2700 Bujumbura (Burundi) Jean LEJOLY Université Libre de Bruxelles, Laboratoire d’Écologie végétale et Biogéochimie, case postale 244, boulevard du Triomphe, B-1050 Bruxelles (Belgium) Frédéric BANGIRINAMA École normale supérieure, Département des Sciences Naturelles, B.P. 6983 Bujumbura (Burundi) Jan BOGAERT Université de Liège/Gembloux Agro-Bio Tech., Unité Biodiversité et Paysage, 2 passage des Déportés, B-5030 Gembloux (Belgium) Masharabu T., Bigendako M. J., Nzigidahera B., Mpawenayo B., Lejoly J., Bangirinama F. & Bogaert J. 2012. — Vascular flora inventory and plant diversity of the Ruvubu National Park, Burundi. Adansonia, sér. 3, 34 (1): 155-162. http://dx.doi.org/10.5252/a2012n1a17 ADANSONIA, sér. 3 • 2012 • 34 (1) © Publications Scientifiques du Muséum national d’Histoire naturelle, Paris. www.adansonia.com 155 Masharabu T. et al. ABSTRACT The Ruvubu National Park, the biggest protected area and biodiversity refuge of the country, is comparatively less studied than western Burundi near Bujum­ bura, the capital. This article reports the results of a botanical inventory of the vascular plants from the protected area, evidences species newly encountered and establishes a comparison of the floristic diversity with the Akagera National Park in Rwanda located in the same phytochorion, in the Lake Victoria regional mosaic.
  • Australia Biodiversity of Biodiversity Taxonomy and and Taxonomy Plant Pathogenic Fungi Fungi Plant Pathogenic

    Australia Biodiversity of Biodiversity Taxonomy and and Taxonomy Plant Pathogenic Fungi Fungi Plant Pathogenic

    Taxonomy and biodiversity of plant pathogenic fungi from Australia Yu Pei Tan 2019 Tan Pei Yu Australia and biodiversity of plant pathogenic fungi from Taxonomy Taxonomy and biodiversity of plant pathogenic fungi from Australia Australia Bipolaris Botryosphaeriaceae Yu Pei Tan Curvularia Diaporthe Taxonomy and biodiversity of plant pathogenic fungi from Australia Yu Pei Tan Yu Pei Tan Taxonomy and biodiversity of plant pathogenic fungi from Australia PhD thesis, Utrecht University, Utrecht, The Netherlands (2019) ISBN: 978-90-393-7126-8 Cover and invitation design: Ms Manon Verweij and Ms Yu Pei Tan Layout and design: Ms Manon Verweij Printing: Gildeprint The research described in this thesis was conducted at the Department of Agriculture and Fisheries, Ecosciences Precinct, 41 Boggo Road, Dutton Park, Queensland, 4102, Australia. Copyright © 2019 by Yu Pei Tan ([email protected]) All rights reserved. No parts of this thesis may be reproduced, stored in a retrieval system or transmitted in any other forms by any means, without the permission of the author, or when appropriate of the publisher of the represented published articles. Front and back cover: Spatial records of Bipolaris, Curvularia, Diaporthe and Botryosphaeriaceae across the continent of Australia, sourced from the Atlas of Living Australia (http://www.ala. org.au). Accessed 12 March 2019. Taxonomy and biodiversity of plant pathogenic fungi from Australia Taxonomie en biodiversiteit van plantpathogene schimmels van Australië (met een samenvatting in het Nederlands) Proefschrift ter verkrijging van de graad van doctor aan de Universiteit Utrecht op gezag van de rector magnificus, prof. dr. H.R.B.M. Kummeling, ingevolge het besluit van het college voor promoties in het openbaar te verdedigen op donderdag 9 mei 2019 des ochtends te 10.30 uur door Yu Pei Tan geboren op 16 december 1980 te Singapore, Singapore Promotor: Prof.
  • 2. Medicinal Plants: Threats and Conservation Reactions 8 3

    2. Medicinal Plants: Threats and Conservation Reactions 8 3

    23104_MedicinalPlants:cov 7/11/08 15:12 Page 1 Contact information Applied Environmental Research Kunming Institute of Botany Tooro Botanical Gardens, Foundation (AERF), C-10 Natya Chitra (Applied Ethnobotany Research P.O. Box 840, Fort Portal, Uganda Co-op Society (Kalagram), Bhusari Colony, Group), Chinese Academy of Sciences, Pune 411029, India. Heilongtan, Kunming 650204, Yunnan, Uganda Group of the African www.aerfindia.org. People’s Republic of China. Network of Ethnobiology Email: [email protected] www.kib.ac.cn (UGANEB), P.O. Box 16453 Wandegeya, Uganda Ashoka Trust for Research in Ladakh Society for Traditional Ecology and the Environment Medicines (LSTM), P.O Box 97, Leh, World Wide Fund for Nature (ATREE), Eastern Himalayas Programme, Ladakh, Jamu and Kashmir, India, (WWF-Pakistan), Ferozepur Road, E2, Golden Heights, Gandhi Road, Tel +91 1982251 537. Lahore- 54600, P.O. Box 5180, Pakistan. Darjeeling 734 101, West Bengal, India. Email: [email protected] Tel: +92 42 111 993725. www.atree.org www.wwfpak.org National Museums of Kenya, Ethnobotanical Society of Nepal P.O. Box 40658-00100, Nairobi, Kenya Yangzhou University (College of (ESON), 107 Guchcha Marg, New Road, Tel +254 20 3742131. Bioscience and Biotechnology), GPO 5220, Kathmandu, Nepal. Fax + 254 20 3741424 . Yangzhou 225009, Jiang Su Province, Tel +977 16213406. www.museums.or.ke. People’s Republic of China www.eson.org.np Email: [email protected] Foundation for Revitalisation of NOMAD Recherche et Soutien Further information on the case studies is Local Health Traditions (FRLHT), Internatonal, 11 rue Lantiez, 75017 available on Plantlife’s website: 74/2 Jarakabande Kaval, Post Attur, Paris , France.
  • Plant Biosecurity Report 2019-2020

    Plant Biosecurity Report 2019-2020

    Plant Biosecurity Report 2019-2020 Bhutan Agriculture and Food Regulatory Authority (BAFRA) Ministry of Agriculture and Forests (MoAF) Thimphu i Introduction The plant biosecurity is gaining significance with expansion of global trade of agricultural commodities and transboundary movement of plant genetic resources. The catastrophic impact through intrusion of pest and disease like historical Irish famine caused by potato late blight introduced from Central America and Golden nematode of potato introduced to India in 1960s from the UK furnished vivid evident that introduction and establishment of quarantine pest affects the crop production and economy of the country (Khetarpal, R.K. and Gupta, K. 2007). Currently, International Plant Protection Convention (IPPC) requires all contracting parties to establish National Plant Protection Organization (NPPO) and develop international cooperation in prevention of introduction and spread of regulated pest. In Australia, several area of major biosecurity concerns are new race of wheat stem rust, loss of pollination European honey bee services from parasite Varroa mite and disease, incursion of exotic fruit fly. Wheat stem rust epidemic in 1973 in Australia caused about $200-300 million and expected yield loss of more than 70 percent. Wheat stem rust, Ug99 is now only found in African countries and Middle East, although Ug99 is under control in Australia for more than 30 years, there is a potential threat to wheat industry as eradication and containment become difficult due to high mobility of the disease. The disease spread to larger distance by wind, movement of goods and people. Loss of European honey bees will severely impact fruits and vegetables as loss of pollination services can impact economy of the country which has annual contribution of $4-6 billion.