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2. Preface

Author

Bhatt, Deepesh, primary, Nath, Manoj, additional, Badoni, Saurabh, additional, and Joshi, Rohit, additional

Published
2024
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4. Pyramiding of genes for grain protein content, grain quality, and rust resistance in eleven Indian bread wheat cultivars: a multi-institutional effort

Author

Gupta, Pushpendra K., Balyan, Harindra S., Chhuneja, Parveen, Jaiswal, Jai P., Tamhankar, Shubhada, Mishra, Vinod K., Bains, Navtej S., Chand, Ramesh, Joshi, Arun K., Kaur, Satinder, Kaur, Harinderjeet, Mavi, Gurvinder S., Oak, Manoj, Sharma, Achla, Srivastava, Puja, Sohu, Virinder S., Prasad, Pramod, Agarwal, Priyanka, Akhtar, Moin, Badoni, Saurabh, Chaudhary, Reeku, Gahlaut, Vijay, Gangwar, Rishi Pal, Gautam, Tinku, Jaiswal, Vandana, Kumar, Ravi Shekhar, Kumar, Sachin, Shamshad, M., Singh, Anupama, Taygi, Sandhya, Vasistha, Neeraj Kumar, and Vishwakarma, Manish Kumar

Published
2022
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7. Systems seed biology to understand and manipulate rice grain quality and nutrition.

Author

Badoni, Saurabh, Parween, Sabiha, Henry, Robert J., and Sreenivasulu, Nese

Subjects
*SYSTEMS biology, *RICE quality, *SEED development, *NUTRITION, *RNA regulation, *RICE bran, *SEED storage
Abstract

Rice is one of the most essential crops since it meets the calorific needs of 3 billion people around the world. Rice seed development initiates upon fertilization, leading to the establishment of two distinct filial tissues, the endosperm and embryo, which accumulate distinct seed storage products, such as starch, storage proteins, and lipids. A range of systems biology tools deployed in dissecting the spatiotemporal dynamics of transcriptome data, methylation, and small RNA based regulation operative during seed development, influencing the accumulation of storage products was reviewed. Studies of other model systems are also considered due to the limited information on the rice transcriptome. This review highlights key genes identified through a holistic view of systems biology targeted to modify biochemical composition and influence rice grain quality and nutritional value with the target of improving rice as a functional food. [ABSTRACT FROM AUTHOR]

Published
2023
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8. List of Contributors

Author

Raina, Aamir, primary, Banerjee, Aditya, additional, Kamal, Aisha, additional, Francini, Alessandra, additional, Trivellini, Alice, additional, Ahmad, Altaf, additional, Singh, Amarjeet, additional, Singh, Ananya, additional, Giro, Andrea, additional, Ferrante, Antonio, additional, Karumanchi, Appa Rao, additional, Frukh, Arajmand, additional, Roychoudhury, Aryadeep, additional, Talakayala, Ashwini, additional, Masood, Asim, additional, Ordog, Attila, additional, Jahan, Badar, additional, Saikia, Banashree, additional, Ahmad, Bilal, additional, Mir, BilalAhmad, additional, Surekha, Challa, additional, Puli, Chandra Obul Reddy, additional, Akila, Chandra Sekhar, additional, Chikkaputtaiah, Channakeshavaiah, additional, Pucciariello, Chiara, additional, Massa, Daniele, additional, Chakrabarty, Debasis, additional, Bhatt, Deepesh, additional, Punita, Devineni Lakshmi, additional, Srivastava, Dipali, additional, Shah, Durdana, additional, Simsek, Eray, additional, Khan, Fareed Ahmad, additional, Ahmad, Farhan, additional, Raghib, Fariha, additional, Naushin, Fauzia, additional, Jawahar, Gandra, additional, Cocetta, Giacomo, additional, Sacchi, Gian Attilio, additional, Verma, Giti, additional, Franzoni, Giulia, additional, Rajasheker, Guddimalli, additional, Boruah, H.P.D., additional, Jaleel, Hassan, additional, Ahmad, Iffat Zareen, additional, Bhatt, Indra Dutt, additional, Baruah, Indrani, additional, Debbarma, Johni, additional, Khanna, Kanika, additional, Sharma, Kapil, additional, Sharma, Kiran K., additional, Guduru, Krishna Kumar, additional, Divya, Kummari, additional, Freschi, Luciano, additional, Khan, M. Iqbal R., additional, Tiwari, Madhu, additional, Garladinne, Mallikarjuna, additional, Nath, Manoj, additional, Sharma, Mayank, additional, Bhatt, Megha D., additional, Fatma, Meher, additional, Ahanger, Mohammad Abass, additional, Ansari, Mohammad lsrail, additional, Naikoo, Mohd Irfan, additional, Dar, Mudasir Irfan, additional, Dikilitas, Murat, additional, Khan, Nafees A., additional, Neelapu, Nageswara Rao Reddy, additional, Jalaja, Naravula, additional, Anjum, Naser A., additional, Sajjad, Nasreena, additional, Velmurugan, Natarajan, additional, Nazir, Nazish, additional, Handa, Neha, additional, Sreenivasulu, Nese, additional, Negrini, Noemi, additional, Iqbal, Noushina, additional, Bakshi, Palak, additional, Reddy, Palakolanu Sudhakar, additional, Kumari, Palavalasa Hima, additional, Santisree, Parankusam, additional, Kaur, Parminder, additional, Ahmad, Parvaiz, additional, Maheshwari, Parveda, additional, Poor, Peter, additional, Kishor, Polavarapu Bilhan Kavi, additional, Rathnagiri, Polavarapu, additional, Mathur, Pooja Bhatnagar-, additional, Sharma, Pooja, additional, Saini, Poonam, additional, Tiwari, Poonam, additional, Singh, Pradyumna Kumar, additional, Arora, Priya, additional, Sharma, Priyanka, additional, Reddy, Ramesha A., additional, Ferrari, Renata Callegari, additional, Bhardwaj, Renu, additional, Marwein, Riwandahun, additional, Bulgari, Roberta, additional, Ali, Rohaya, additional, Afreen, Ruhi, additional, Khan, Samiullah, additional, Melito, Sara, additional, Badoni, Saurabh, additional, Karakas, Sema, additional, Wani, Shabir H., additional, Umar, Shahid, additional, Sareen, Shelja, additional, Nandi, Shyamal Kumar, additional, Morgutti, Silvia, additional, Shah, Snober, additional, Kumar, Somanaboina Anil, additional, Adimulam, Srivani. S, additional, Hassan, Sumaya, additional, Mellacheruvu, Sunitha, additional, Sagar, Sushma, additional, Jalil, Syed Uzma, additional, Siddiqi, Tariq Omar, additional, Chakradhar, Thammineni, additional, Chandrasekhar, Thummala, additional, Dutta, Titash, additional, Gautam, Vandana, additional, Pandey, Veena, additional, Verma, Vinod, additional, Sarki, Yogita N., additional, Czekus, Zalin, additional, Sehar, Zebus, additional, and Li, Zhong-Guang, additional

Published
2019
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13. List of contributors

Author

Ade, Prasad, Aminedi, Raghavendra, Aung, Me Me, Aye, Myint, Badoni, Saurabh, Banik, Diptanu, Bartwal, Arti, Bharti, Mahesh Kumar, Bhat, Deepa, Bhati, Pradeep Kumar, Bhatt, Deepesh, Bhatt, Megha D., Bhattacharjee, Sougata, Bhowmick, Rakesh, Biswas, Koushik, Bohra, Abhishek, Butani, Naresh, Chakraborty, Anwesha, Chakrawarti, Neha, Chandra, Deepika, Chaudhary, Reeku, Chauhan, Harsh, Chung, Sang-Min, Dabral, Surbhi, Dagla, Manesh Chandra, Devi, Priyanka, Dey, Shipa Rani, Dhatwaliya, Deepa, Dinesh, Govindaraj Kamalam, Dwivedi, Vikas, Elakkya, M., Elangovan, Allimuthu, Gantait, Saikat, Garg, Esha, Gusain, Suman, Harkhani, Khyati, Htun, Than Myint, Islam, Tofazzal, Ismail, Abdelbagi M., Jaiswal, V.P., Jha, Rajesh Kumar, Joshi, A.B., Joshi, Arun Kumar, Joshi, Rohit, Joshi, Shubham, Kalwan, Gopal, Kapadia, Chintan, Karthika, P., Kaur, Simardeep, Kesawat, Mahipal Singh, Khan, Laiba, Khan, M. Iqbal R., Koramutla, Murali Krishna, Kumar, Gaurav, Kumar, Gunti Vinod, Kumar, Manu, Kumar, Pankaj, Kumar, Pawan, Kumar, Prasann, Kumar, Sanjeev, Kumar, Suresh, Kumari, Anita, Kumari, Khushbu, Kumari, Priya, Mehta, Chandra Mohan, Mondal, Satyen, Mukherjee, Eashan, Nath, Jhilmil, Nath, Manoj, Nazir, Faroza, Negi, Manisha, Pal, Lalita, Palanisamy, Karvembu, Pandey, Indra Deo, Pandit, Jyotsana, Pandya, Nilesh, Patel, Helina, Patel, Nafisa, Patel, Rutu, Patra, Subhashree, Paul, Krishnayan, Quddus, Md. Ruhul, Ram, Chet, Ranjan, K., Rawat, Meenakshi, Rudakiya, Darshan M., Saikia, Purabi, Salvi, Prafull, Seem, Karishma, Selvan, Tamil, Shah, Gaurav, Shankar, Rama, Sharma, Anish Kumar, Sharma, Lalan, Shilky, Shukla, S.K., Siddique, R.A., Soni, Ravindra, Subrahmanyeswari, Tsama, Suprasanna, Penna, Tiwari, Abha, Trivedi, Sneha, Umar, Shahid, Vaishnav, Pujan B., Valarmathi, Ramanathan, Vasupalli, Naresh, Zar, Thu, and Zhu, Guanglong

Published
2024
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14. Pyramiding of Genes for Grain Protein Content, Grain Quality and Rust Resistance in Eleven Indian Bread Wheat Cultivars: A Multi-Institutional Effort

Author

Gupta, Pushpendra K., primary, Balyan, Harindra S., additional, Chhuneja, Parveen, additional, Jaiswal, Jai P., additional, Tamhankar, Shubhada, additional, Mishra, Vinod K., additional, Bains, Navtej S., additional, Chand, Ramesh, additional, Joshi, Arun K., additional, Kaur, Satinder, additional, Kaur, Harinderjeet, additional, Mavi, Gurvinder S., additional, Oak, Manoj, additional, Sharma, Achla, additional, Srivast, Puja, additional, Sohu, Virinder S., additional, Prasad, Pramod, additional, Agarwal, Priyanka, additional, Akhtar, Moin, additional, Badoni, Saurabh, additional, Chaudhary, Reeku, additional, Gahlaut, Vijay, additional, Gangwar, Rishi Pal, additional, Gautam, Tinku, additional, Jaiswal, Vandana, additional, Kumar, Ravi Shankar, additional, Kumar, Sachin, additional, Shamshad, M., additional, Singh, Anupama, additional, Taygi, Sandhya, additional, Vasistha, Neeraj Kumar, additional, and Vishwakarma, Manish Kumar, additional

Published
2021
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15. The genetics underlying metabolic signatures in a brown rice diversity panel and their vital role in human nutrition

Author

Brotman, Yariv, primary, Llorente‐Wiegand, Cindy, additional, Oyong, Glenn, additional, Badoni, Saurabh, additional, Misra, Gopal, additional, Anacleto, Roslen, additional, Parween, Sabiha, additional, Pasion, Erstelle, additional, Tiozon, Rhowell N., additional, Anonuevo, Joanne J., additional, deGuzman, Maria K., additional, Alseekh, Saleh, additional, Mbanjo, Edwige G. N., additional, Boyd, Lesley A., additional, Fernie, Alisdair R., additional, and Sreenivasulu, Nese, additional

Published
2021
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18. Deciphering the Genetic Architecture of Cooked Rice Texture

Author

Misra, Gopal, Badoni, Saurabh, Domingo, Cyril John, Cuevas, Rosa Paula O., Llorente, Cindy, Mbanjo, Edwige Gaby Nkouaya, and Sreenivasulu, Nese

Subjects
multi-locus GWAS, amylose content, adhesiveness, cohesiveness, rice texture, lcsh:SB1-1110, Plant Science, quantitative trait nucleotide, lcsh:Plant culture, springiness, hardness, Original Research
Abstract

The textural attributes of cooked rice determine palatability and consumer acceptance. Henceforth, understanding the underlying genetic basis is pivotal for the genetic improvement of preferred textural attributes in breeding programs. We characterized diverse set of 236 Indica accessions from 37 countries for textural attributes, which includes adhesiveness (ADH), hardness (HRD), springiness (SPR), and cohesiveness (COH) as well as amylose content (AC). A set of 147,692 high quality SNPs resulting from genotyping data of 700K high Density Rice Array (HDRA) derived from the Indica diversity panels of 218 lines were retained for marker-trait associations of textural attributes using single-locus (SL) genome wide association studies (GWAS) which resulted in identifying hotspot on chromosome 6 for AC and ADH attributes. Four independent multi-locus approaches (ML-GWAS) including FASTmrEMMA, pLARmEB, mrMLM, and ISIS_EM-BLASSO were implemented to dissect additional loci of major/minor effects influencing the rice texture and to overcome limitations of SL-based GWAS approach. In total 224 significant quantitative trait nucleotide (QTNs) were identified using ML-GWAS, of which 97 were validated with at least two out of the four multi-locus methods. The GWAS results were in accordance with the very significant negative correlation (r = −0.83) observed between AC and ADH, and the significant correlation exhibited by AC (r < 0.4) with HRD, SPR, and COH. The novel haplotypes and putative candidate genes influencing textural properties beyond AC will be a useful resource for deployment into the marker assisted program to capture consumer preferences influencing rice texture and palatability.

Published
2018

19. Genome‐wide association coupled gene to gene interaction studies unveil novel epistatic targets among major effect loci impacting rice grain chalkiness.

Author

Misra, Gopal, Badoni, Saurabh, Parween, Sabiha, Singh, Rakesh Kumar, Leung, Hei, Ladejobi, OluFunmilayo, Mott, Richard, and Sreenivasulu, Nese

Subjects
*GENOME-wide association studies, *RICE, *LOCUS (Genetics), *SINGLE nucleotide polymorphisms, *PHENOTYPES, *GENE regulatory networks, *CHROMOSOMES
Abstract

Rice varieties whose quality is graded as excellent have a lower percent grain chalkiness (PGC) of two per cent and below with higher whole grain yields upon milling, leading to higher economic returns for farmers. We have conducted a genome‐wide association study (GWAS) using a combined population panel of indica and japonica rice varieties, and identified a total of 746 single nucleotide polymorphisms (SNPs) that were strongly associated with the chalk phenotype, covered 78 Quantitative Trait Loci (QTL) regions. Among them, 21 were high‐value QTLs, as they explained at least 10 % of the phenotypic variance for PGC. A combined epistasis and GWAS was applied to dissect the genetics of the complex chalkiness trait, and its regulatory cascades were validated using gene regulatory networks. Promising novel epistatic interactions were found between the loci of chromosomes 6 (PGC6.1) and 7 (PGC7.8) that contributed to lower PGC. Based on haplotype mining only a few modern rice varieties confounded with a lower chalkiness, and they possess several PGC QTLs. The importance of PGC6.1 was validated through multi‐parent advanced generation intercrosses and several low‐chalk lines possessing superior haplotypes were identified. The results of this investigation have deciphered the underlying genetic networks that can reduce PGC to 2%, and will thus support future breeding programs to improve the grain quality of elite genetic material with high‐yielding potentials. [ABSTRACT FROM AUTHOR]

Published
2021
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21. Integrating a genome‐wide association study with a large‐scale transcriptome analysis to predict genetic regions influencing the glycaemic index and texture in rice

Author

Anacleto, Roslen, primary, Badoni, Saurabh, additional, Parween, Sabiha, additional, Butardo, Vito M., additional, Misra, Gopal, additional, Cuevas, Rosa Paula, additional, Kuhlmann, Markus, additional, Trinidad, Trinidad P., additional, Mallillin, Aida C., additional, Acuin, Cecilia, additional, Bird, Anthony R., additional, Morell, Matthew K., additional, and Sreenivasulu, Nese, additional

Published
2019
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28. A Genome-wide Combinatorial Strategy Dissects Complex Genetic Architecture of Seed Coat Color in Chickpea

Author

Bajaj, Deepak, primary, Das, Shouvik, additional, Upadhyaya, Hari D., additional, Ranjan, Rajeev, additional, Badoni, Saurabh, additional, Kumar, Vinod, additional, Tripathi, Shailesh, additional, Gowda, C. L. Laxmipathi, additional, Sharma, Shivali, additional, Singh, Sube, additional, Tyagi, Akhilesh K., additional, and Parida, Swarup K., additional

Published
2015
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29. Unveilingsources of stripe rust resistance in diverse wheat ( Triticum Aestivum L.) germplasm using narrow down methodology: a proof of concept.

Author

Badoni, Saurabh, Chaudhary, Reeku, Shekhar, Ravi, Badoni, Shweta, Ahmad, Ekhlaque, Gangwar, Rishi, Tiwari, Kashi, Rawat, Rajendra, Deepshikha, and Jaiswal, Jai

Abstract

Stripe rust of wheat caused by the fungal pathogen is a destructive foliar disease of wheat. Thus, it is crucial step to characterize the resistant germplasm for stripe rust in a diverse germplasm pool for their ultimate utilization in efficient crop rust resistance breeding. In the present study, we followed two pronged strategies involving integrated phenotypic and molecular characterization of 440 diverse wheat germplasm lines for rust resistance. The germplasm panel was extensively evaluated in field epiphytotic conditions during two consecutive years. After rigorous screening, 72 accessions were successfully revealed as resistant to moderately resistant to stripe rust. Subsequently, entries were then evaluated for their field agronomicperformances, considering prerequisites for serving as a donor germplasm,particularly for yield and 33 potential rust-resistant accessions were identified. Furthermore, to detect the sources of resistance, accessions were molecular characterized for potential race-specific resistance genes Yr5, Yr10,Yr15, and effective adult plant resistance (APR) gene Lr34/Yr18/pm38. We identified the 22 accessions possessing one or more single resistance genes and two accessions were observed with at least three of them. Moreover, Lr34/Yr18/pm38 was determined to confer resistance when observed along with any of the race-specific genes. Thus, the study not only provides proof of concept methodology to identify candidate resistant sources from large germplasm collections but simultaneouslyconfirmed the contribution of combining race-specific andnon-specific APR genes. The finding could further assist in the potential deployment of resistant genes directly into the stripe rust breeding program by involving marker-assisted approaches. [ABSTRACT FROM AUTHOR]

Published
2017
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31. A genome-wide SNP scan accelerates trait-regulatory genomic loci identification in chickpea

Author

Kujur, Alice, primary, Bajaj, Deepak, additional, Upadhyaya, Hari D., additional, Das, Shouvik, additional, Ranjan, Rajeev, additional, Shree, Tanima, additional, Saxena, Maneesha S., additional, Badoni, Saurabh, additional, Kumar, Vinod, additional, Tripathi, Shailesh, additional, Gowda, C.L.L., additional, Sharma, Shivali, additional, Singh, Sube, additional, Tyagi, Akhilesh K., additional, and Parida, Swarup K., additional

Published
2015
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32. Ultra-high density intra-specific genetic linkage maps accelerate identification of functionally relevant molecular tags governing important agronomic traits in chickpea

Author

Kujur, Alice, primary, Upadhyaya, Hari D., additional, Shree, Tanima, additional, Bajaj, Deepak, additional, Das, Shouvik, additional, Saxena, Maneesha S., additional, Badoni, Saurabh, additional, Kumar, Vinod, additional, Tripathi, Shailesh, additional, Gowda, C. L. L., additional, Sharma, Shivali, additional, Singh, Sube, additional, Tyagi, Akhilesh K., additional, and Parida, Swarup K., additional

Published
2015
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33. Employing genome-wide SNP discovery and genotyping strategy to extrapolate the natural allelic diversity and domestication patterns in chickpea

Author

Kujur, Alice, primary, Bajaj, Deepak, additional, Upadhyaya, Hari D., additional, Das, Shouvik, additional, Ranjan, Rajeev, additional, Shree, Tanima, additional, Saxena, Maneesha S., additional, Badoni, Saurabh, additional, Kumar, Vinod, additional, Tripathi, Shailesh, additional, Gowda, C. L. L., additional, Sharma, Shivali, additional, Singh, Sube, additional, Tyagi, Akhilesh K., additional, and Parida, Swarup K., additional

Published
2015
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34. A combinatorial approach of comprehensive QTL-based comparative genome mapping and transcript profiling identified a seed weight-regulating candidate gene in chickpea

Author

Bajaj, Deepak, primary, Upadhyaya, Hari D., additional, Khan, Yusuf, additional, Das, Shouvik, additional, Badoni, Saurabh, additional, Shree, Tanima, additional, Kumar, Vinod, additional, Tripathi, Shailesh, additional, Gowda, C. L. L., additional, Singh, Sube, additional, Sharma, Shivali, additional, Tyagi, Akhilesh K., additional, Chattopdhyay, Debasis, additional, and Parida, Swarup K., additional

Published
2015
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35. Genome-wide conserved non-coding microsatellite (CNMS) marker-based integrative genetical genomics for quantitative dissection of seed weight in chickpea

Author

Bajaj, Deepak, primary, Saxena, Maneesha S., additional, Kujur, Alice, additional, Das, Shouvik, additional, Badoni, Saurabh, additional, Tripathi, Shailesh, additional, Upadhyaya, Hari D., additional, Gowda, C. L. L., additional, Sharma, Shivali, additional, Singh, Sube, additional, Tyagi, Akhilesh K., additional, and Parida, Swarup K., additional

Published
2014
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37. Deploying QTL-seq for rapid delineation of a potential candidate gene underlying major trait-associated QTL in chickpea.

Author

Das, Shouvik, Upadhyaya, Hari D., Bajaj, Deepak, Kujur, Alice, Badoni, Saurabh, Laxmi, Kumar, Vinod, Tripathi, Shailesh, Gowda, C. L. Laxmipathi, Sharma, Shivali, Singh, Sube, Tyagi, Akhilesh K., and Parida, Swarup K.

Abstract

A rapid high-resolution genome-wide strategy for molecular mapping of major QTL(s)/gene(s) regulating important agronomic traits is vital for in-depth dissection of complex quantitative traits and genetic enhancement in chickpea. The present study for the first time employed a NGS-based whole-genome QTL-seq strategy to identify one major genomic region harbouring a robust 100-seed weight QTL using an intra-specific 221 chickpea mapping population (desi cv. ICC 7184 × desi cv. ICC 15061). The QTL-seq-derived major SW QTL (CaqSW1.1) was further validated by single-nucleotide polymorphism (SNP) and simple sequence repeat (SSR) marker-based traditional QTL mapping (47.6% R2 at higher LOD >19). This reflects the reliability and efficacy of QTL-seq as a strategy for rapid genome-wide scanning and fine mapping of major trait regulatory QTLs in chickpea. The use of QTL-seq and classical QTL mapping in combination narrowed down the 1.37 Mb (comprising 177 genes) major SW QTL (CaqSW1.1) region into a 35 kb genomic interval on desi chickpea chromosome 1 containing six genes. One coding SNP (G/A)-carrying constitutive photomorphogenic9 (COP9) signalosome complex subunit 8 (CSN8) gene of these exhibited seed-specific expression, including pronounced differential up-/down-regulation in low and high seed weight mapping parents and homozygous individuals during seed development. The coding SNP mined in this potential seed weight-governing candidate CSN8 gene was found to be present exclusively in all cultivated species/ genotypes, but not in any wild species/genotypes of primary, secondary and tertiary gene pools. This indicates the effect of strong artificial and/or natural selection pressure on target SW locus during chickpea domestication. The proposed QTL-seq-driven integrated genome-wide strategy has potential to delineate major candidate gene(s) harbouring a robust trait regulatory QTL rapidly with optimal use of resources. This will further assist us to extrapolate the molecular mechanism underlying complex quantitative traits at a genome-wide scale leading to fast-paced marker-assisted genetic improvement in diverse crop plants, including chickpea. [ABSTRACT FROM AUTHOR]

Published
2015
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38. Multiomics of a rice population identifies genes and genomic regions that bestow low glycemic index and high protein content.

Author

Badoni S, Pasion-Uy EA, Kor S, Kim SR, Tiozon RN Jr, Misra G, Buenafe RJQ, Labarga LM, Ramos-Castrosanto AR, Pratap V, Slamet-Loedin I, Steimker JV, Alseekh S, Fernie AR, Kohli A, Khush GS, and Sreenivasulu N

Subjects
Plant Proteins genetics, Plant Proteins metabolism, Polymorphism, Single Nucleotide, Genome, Plant, 1,4-alpha-Glucan Branching Enzyme genetics, 1,4-alpha-Glucan Branching Enzyme metabolism, Phenotype, Genomics methods, Multiomics, Oryza genetics, Oryza metabolism, Quantitative Trait Loci, Glycemic Index, Amylose metabolism, Amylose genetics
Abstract

To counter the rising incidence of diabetes and to meet the daily protein needs, we created low glycemic index (GI) rice varieties with protein content (PC) surpassing 14%. In the development of recombinant inbred lines using Samba Mahsuri and IR36 amylose extender (IR36ae) as parental lines, we identified quantitative trait loci and genes associated with low GI, high amylose content (AC), and high PC. By integrating genetic techniques with classification models, this comprehensive approach identified candidate genes on chromosome 2 ( qGI2.1/qAC2.1 spanning the region from 18.62 Mb to 19.95 Mb), exerting influence on low GI and high amylose. Notably, the phenotypic variant with high value was associated with the recessive allele of the starch branching enzyme 2b ( sbeIIb ). The genome-edited sbeIIb line confirmed low GI phenotype in milled rice grains. Further, combinations of alleles created by the highly significant SNPs from the targeted associations and epistatically interacting genes showed ultralow GI phenotypes with high amylose and high protein. Metabolomics analysis of rice with varying AC, PC, and GI revealed that the superior lines of high AC and PC, and low GI were preferentially enriched in glycolytic and amino acid metabolisms, whereas the inferior lines of low AC and PC and high GI were enriched with fatty acid metabolism. The high amylose high protein recombinant inbred line (HAHP&#95;101) was enriched in essential amino acids like lysine. Such lines may be highly relevant for food product development to address diabetes and malnutrition., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published
2024
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