Your search keyword '"Nsabiyera V"' showing total 8 results

1. Chapter 77 - Kiwifruit

Author

Ochwo-Ssemakula, M. and Nsabiyera, V.

Published

2024

2. Contributors

Author

Abadin, Zain Ul, Abbas, Muhammad Taqqi, Abd El-Aziz, M.H., Abhishek, G.J., Abraham, Adane, Adeniyi, D.O., Ahmad, Sadia, Ahmed, Mukhtar, Ahsan, Aymen, Akinyemi, Sunday O.S., Al-Tawaha, Abdel Razzaq, Alegbejo, Matthew Dada, Alemandri, Vanina, Ali, Akhtar, Aliyu, Taiye H., Amato, Marcos, Amezquita, N.F., Angira, Aniket, Arogundade, Olawale, Arshad, Hibba, Asif, Mahrukh, Aslam, Muhammad Naveed, Asogwa, E.U., Avila, L.A., Awasthi, L.P., Back, Emma J., Bano Rizvi, Syeda Shahar, Banwo, Olalekan Oyeleke, Barbosa, Tarsiane M.C., Barros, S.C.I.M., Barrón-Contreras, J.L., Bañuelos-Hernández, B., Belen, Glenrose B., Beltran, J.H., Berkani, Salima, Bernal, Julio S., Bhardwaj, Pooja, Bhat, Alangar Ishwara, Boonham, N., Bruckner, Fernanda P., Budzanivska, I., Bukhari, Syeda Fatima, Cabrera Mederos, Dariel, Carvalho, C.M., Chalam, V. Celia, Chandra, Prem, Changadeya, Wisdom, Changaya, Albert, Chapara, V., Chapara, R., Chatterjee, Arpita, Choudhary, Nandlal, Cherian K., Anita, Chinnadurai, Chinnaraja, Chirumamilla, A., Chofong, G.N., Clover, G.R.G., Creamer, Rebecca, Cruz-Hernández, A., Cruz, Maylín, Cuevas, A., Dale, J., Das, I.K., da Silva, Marcel Fernando, Davino, Salvatore, Deepika, D.D., Delmiglio, C., Dian, V.S., Dongo, L.N., Echeverri, J., Eiras, Marcelo, Ellouze, Walid, Elçi, Eminur, Emmanuel, C.J., Enespa, Ertunç, Filiz, Faggioli, Francesco, Fall, Mamadou L., Fariña, Arnaldo Esquivel, Farooq, Tahir, Figueira, A.R., Fox, A., Gaafar, Yahya Z.A., Gates, Matthew Russell, Gazel, Mona, Ghosh, Subrata Kumar, Giolitti, Fabián, Gnanaprakash, S., Gonçalves, Marcos Cesar, Goodin, M.M., Groth-Helms, Deborah, Gupta, Taruna, Haider, Muhammad Saleem, Hallan, Vipin, Harding, R., Harish, Atheena, Haroon, Rajia, Hashmi, Muhammad Muneeb, Higuera, O.L., Ighani, Hakimeh, James, A., Jasrotia, Poonam, Javaran, Vahid J., Jevremović, Darko, Jeyaseelan, T.C., Jones, Tara-Kay L., Kalaiponmani, K., Kapoor, Promil, Karanfil, Ali, Karanja, Laura Shali, Karavina, Charles, Karthikeyan, Gandhi, Kashina, Boniface David, Kashyap, Prem Lal, Katis, N.I., Kaul, Noyonika, Kaur, Baljeet, Kaushal, Lovelin, Kawas, Houda, Keremane, Manjunath L., Khaliq, Robina, Khan, Asifa, Khanna, Megha, Khanum, Samia, Kidanemariam, D., Kil, Eui-Joon, Kim, Chang-Seok, Kingsley-Umana, E.B., Kitajima, Elliot Watanabe, Krishnan, Kathiravan, Krishna Reddy, M., Kumar, R., Kumar, Sudheer, Kumar, Surender, Kumari, Safaa G., Kumari, Pooja, Kumari, Reenu, Kyriakopoulou, P.E., Lau, Douglas, Leastro, Mikhail Oliveira, Lee, Richard F., Lee, Sukchan, Leiva, D.C., Leiva Mora, Michel, Londoño-Avendaño, M.A., Londoño, A., Lorenzo, Jaira T., Maciel, L.S., Madhumitha, B., Maheen, Nimra, Makkouk, Khaled M., Mamedova, Sabina, Manglli, Ariana, Manoranjitham, S.K., Mar, Talita Bernardon, Matić, Slavica, Matthew, Joshua O., Maurya, A.K., Mbewe, Willard, Medina, Raul F., Meena, N.K., Moosa, Anam, Mtonga, Andrew, Muhammad, Buhari, Mulholland, Vincent, Munguía, M.E.G., Mushtaq, Sehrish, Mustafayev, Eldar, Muthu, Sakthivel, Muturi, Samuel Mwangangi, Najar, Asma, Njeru, Lucyline Kajira, Njoroge, Samuel M.C., Noris, Emanuela, Nothnagel, Thomas, Nsabiyera, V., Nusayr, Tesneem, Ochoa-Corona, F.M., Ochwo-Ssemakula, M., Olson, J.D., Pangga, Ireneo B., Pant, R.P., Parrella, Giuseppe, Paunović, Svetlana, Pereira, Paulo Roberto Valle Da Silva, Perez, C.R., Pimenta, Ricardo José Gonzaga, Pinto, Luciana Rossini, Pocsai, Emil, Poojari, Sudarsana, Portal, Orelvis, Pun, K.B., Pushpanathan, Sangeetha, Raj, Chandramani, Raj, S.K., Ramalho-Bean, T.O., Randa-Zelyut, Filiz, Relevante-Belagantol, Cherry A., Riaz, Hafsa, Rishi, Narayan, Rivera-Bustamante, R., Roumi, Vahid, Sadiq, Saleha, Saeed, Sana Tabanda, Sajid, Qurat-ul Ain, Samad, Abdul, Samah, S., Shafiq, Muhammad, Shaheen, Mohamed Nasr Fathi, Shakeel, Muhammad Taimoor, Sharma, V.K., Sharma, Susheel Kumar, Sharma, Tejaswini, Sharma, Rajan, Shevchenko, O., Shevchenko, T., Silva, Fábio Nascimento da, Silveira, A.T.L., Singh, Rachana, Singh, Shweta, Singh, M.K., Singh, Gyanendra Pratap, Sinha, Soumya, Snihur, H., Sokhandan-Bashir, Nemat, Srivastava, Ashish, Srivastava, Sonal, Sta. Cruz, Filomena C., Sánchez-Navarro, Jesús Ángel, Sukal, A., Sundararaj, Deepan, Sutula, Chet, Taglienti, Anna, Çağlayan, Kadriye, Tavares Esashika, M.L., Tawaha, Abdel Rahman M., Tegg, Robert, Thangavel, Tamilarasan, Thirumalaiappan, Priyanga, Thompson, J.R., Tiberini, Antonio, İlbağı, Havva, Tomassoli, Laura, Trucco, Verónica, Çıtır, Ahmet, Ulubaş Serçe, Çiğdem, Umar, Muhammad, Valadez-Moctezuma, E., Varma, Anupam, Vazquez-Iglesias, I., Vemulapati, Bhadra Murthy, Venkataravanappa, V., Verma, H.N., Wachira, Francis Nyamu, Wilson, Calum, Xavier, C.A.D., Xavier, A.S., Yadav, Priya, Zagrai, Luminița-Antonela, Zagrai, Ioan, Zanardo, Larissa G., Zelaya-Molina, L.X., Zhang, Shulu, Zia, Amjad, and Ziebell, Heiko

Published

2024

3. Susceptibility to bruchids among common beans in Uganda

Author

Ebinu, J.A., primary, Nsabiyera, V., additional, Otim, M., additional, Nkalubo, S.T., additional, Ugen, M., additional, Agona, A.J., additional, and Talwana, H.L., additional

Published

2016

4. Field Performance and Quality Traits of hot pepper Genotypes in Uganda

Author

Nsabiyera, V, Ochwo-Ssemakula, M, and Sseruwagi, P

Abstract

Hot pepper (Capsicum annuum) is increasingly an important economic crop in Uganda that requires attention for increased production. Genotypes with superior growth, quality and yield traits are crucial for use in pepper cultivar improvement efforts and use by farmers. To identify such genotypes, agronomic characteristics including growth, quality and yield traits of 26 exotic and 9 local genotypes were evaluated on-station during the growing seasons of 2009 (2009A and B) in Central Uganda. Significant differences were observed in all plant growth, and most yield and quality (P

Published

2012

5. Hot Pepper Reaction to Field Diseases

Author

Nsabiyera, V, Ochwo-Ssemakula, M, and Sseruwagi, P

Abstract

Diseases are major constraints to hot pepper (Capsicum annum L.) production in sub-Saharan Africa. The search for cultivars resistant to the major diseases of hot pepper has been limited. This study was conducted in Uganda to evaluate exotic and local hot pepper genotypes for disease resistance. Viral diseases and Cercospora leaf spot were the most predominant and severe, followed in descending order by anthracnose, Phytophthora blight and wilt diseases. Highly significant genotypic differences (P

Published

2012

6. Relocation of Sr48 to Chromosome 2D Using an Alternative Mapping Population and Development of a Closely Linked Marker Using Diverse Molecular Technologies.

Author

Nsabiyera V, Qureshi N, Li J, Randhawa M, Zhang P, Forrest K, Bansal U, and Bariana H

Abstract

The Ug99-effective stem rust resistance gene Sr48 was mapped to chromosome 2A based on its repulsion linkage with Yr1 in an Arina/Forno recombinant inbred line (RIL) population. Attempts to identify markers closely linked to Sr48 using available genomic resources were futile. This study used an Arina/Cezanne F 5:7 RIL population to identify markers closely linked with Sr48 . Using the Arina/Cezanne DArTseq map, Sr48 was mapped on the short arm of chromosome 2D and it co-segregated with 12 markers. These DArTseq marker sequences were used for BlastN search to identify corresponding wheat chromosome survey sequence (CSS) contigs, and PCR-based markers were developed. Two simple sequence repeat (SSR) markers, sun590 and sun592 , and two Kompetitive Allele-Specific PCR (KASP) markers were derived from the contig 2DS_5324961 that mapped distal to Sr48 . Molecular cytogenetic analysis using sequential fluorescent in situ hybridization (FISH) and genomic in situ hybridization (GISH) identified a terminal translocation of chromosome 2A in chromosome 2DL of Forno. This translocation would have led to the formation of a quadrivalent involving chromosomes 2A and 2D in the Arina/Forno population, which would have exhibited pseudo-linkage between Sr48 and Yr1 in chromosome 2AL. Polymorphism of the closet marker sunKASP_239 among a set of 178 wheat genotypes suggested that this marker can be used for marker-assisted selection of Sr48 .

Published

2023

7. Fine Mapping of Lr49 Using 90K SNP Chip Array and Flow-Sorted Chromosome Sequencing in Wheat.

Author

Nsabiyera V, Baranwal D, Qureshi N, Kay P, Forrest K, Valárik M, Doležel J, Hayden MJ, Bariana HS, and Bansal UK

Abstract

Leaf rust, caused by Puccinia triticina , threatens global wheat production due to the constant evolution of virulent pathotypes that defeat commercially deployed all stage-resistance (ASR) genes in modern cultivars. Hence, the deployment of combinations of adult plant resistance (APR) and ASR genes in new wheat cultivars is desirable. Adult plant resistance gene Lr49 was previously mapped on the long arm of chromosome 4B of cultivar VL404 and flanked by microsatellite markers barc163 (8.1 cM) and wmc349 (10.1 cM), neither of which was sufficiently closely linked for efficient marker assisted selection. This study used high-density SNP genotyping and flow sorted chromosome sequencing to fine-map the Lr49 locus as a starting point to develop a diagnostic marker for use in breeding and to clone this gene. Marker sunKASP_21 was mapped 0.4 cM proximal to Lr49 , whereas a group of markers including sunKASP_24 were placed 0.6 cM distal to this gene. Testing of the linked markers on 75 Australian and 90 European cultivars with diverse genetic backgrounds showed that sunKASP _ 21 was most strongly associated with Lr49 . Our results also show that the Lr49 genomic region contains structural variation relative to the reference stock Chinese Spring, possibly an inverted genomic duplication, which introduces a new set of challenges for the Lr49 cloning., (Copyright © 2020 Nsabiyera, Baranwal, Qureshi, Kay, Forrest, Valárik, Doležel, Hayden, Bariana and Bansal.)

Published

2020

8. Characterisation and mapping of adult plant stripe rust resistance in wheat accession Aus27284.

Author

Nsabiyera V, Bariana HS, Qureshi N, Wong D, Hayden MJ, and Bansal UK

Subjects

Alleles, Basidiomycota, Chromosome Mapping, DNA Primers, Genetic Markers, Genotype, Microsatellite Repeats, Plant Diseases microbiology, Polymorphism, Single Nucleotide, Triticum metabolism, Disease Resistance genetics, Genes, Plant, Plant Diseases genetics, Triticum genetics

Abstract

Key Message: A new adult plant stripe rust resistance gene, Yr80, was identified in a common wheat landrace Aus27284. Linked markers were developed and validated for their utility in marker-assisted selection. Stripe rust, caused by Puccinia striiformis f. sp. tritici (Pst), is among the most important constraints to global wheat production. The identification and characterisation of new sources of host plant resistance enrich the gene pool and underpin deployment of resistance gene pyramids in new cultivars. Aus27284 exhibited resistance at the adult plant stage against predominant Pst pathotypes and was crossed with a susceptible genotype Avocet S. A recombinant inbred line (RIL) population comprising 121 lines was developed and tested in the field at three locations in 2016 and two in 2017 crop seasons. Monogenic segregation for adult plant stripe rust response was observed among the Aus27284/Avocet S RIL population and the underlying locus was temporarily designated YrAW11. Bulked-segregant analysis using the Infinium iSelect 90K SNP wheat array placed YrAW11 in chromosome 3B. Kompetitive allele specific PCR (KASP) primers were designed for the linked SNPs and YrAW11 was flanked by KASP_65624 and KASP_53292 (3 cM) proximally and KASP_53113 (4.9 cM) distally. A partial linkage map of the genomic region carrying YrAW11 comprised nine KASP and two SSR markers. The physical position of KASP markers in the pseudomolecule of chromosome 3B placed YrAW11 in the long arm and the location of markers gwm108 and gwm376 in the deletion bin 3BL2-0.22 supported this conclusion. As no other stripe rust resistance locus has been reported in chromosome 3BL, YrAW11 was formally designated Yr80. Marker KASP_ 53113 was polymorphic among 94% of 81 Australian wheat cultivars used for validation.

Published

2018