Results 61 to 70 of about 16,430 (208)

Wheat breeding approaches for designing wheat to thrive in a warmer world

PLANTS, PEOPLE, PLANET, Volume 8, Issue 3, Page 754-763, May 2026.
Wheat is a vital food crop, accounting for approximately 20% of daily calories and protein consumed worldwide. However, modern‐day wheat is under pressure from global change. The improvement rate of wheat yields is not keeping up with the demand of our growing population. Furthermore, abiotic and biotic stressors are becoming more prevalent. This paper
Jake Hill, Surbhi Grewal, Stella Edwards
wiley   +1 more source

The annotated blueprint: integrated functional genomic resources for a model tetraploid wheat Triticum turgidum cv Kronos

New Phytologist, Volume 250, Issue 3, Page 1389-1410, May 2026.
Summary Triticum turgidum cv Kronos is a tetraploid wheat cultivar that underpins one of the most widely used community platforms for functional genomics. Over the past decade, researchers have generated c. 3000 exome‐capture (EC) and promoter‐capture (PC) datasets linked to mutagenized seed stocks, along with extensive transcriptomic and phenotypic ...
Kyungyong Seong, Rakesh Kumar, Daniil M. Prigozhin, China Lunde, Thales Henrique Cherubino Ribeiro, Sébastien Bélanger, Jo‐Wei Allison Hsieh, McCree Tang, Blake C. Meyers, Ksenia V. Krasileva   +9 more
wiley   +1 more source

Supporting proactive management in the context of climate change: Prioritizaing range-shifting invasive plants based on impact [PDF]

, 2020
Non-native, invasive plants are projected to shift their ranges with climate change, creating hotspots of risk where a multitude of novel species may soon establish and spread. The Northeast U.S. is one such hotspot. However, because monitoring for novel
Bradley, Bethany A, Laginhas, Brittany B., Rockwell-Postel, Mei   +2 more
core   +1 more source

Nematode susceptibility in new synthetic banana hybrids of Musa acuminata resistant against Mycosphaerella leaf spot diseases [PDF]

, 2008
Host status of Yellow Sigatoka and Black Leaf Streak disease resistant new hybrids from Cirad, (cvs 916, 918, 919, 920, 921 and 924) to the burrowing nematode Radopholus similis and to the lesion nematode Pratylenchus coffeae were assessed under ...
Marie-Luce, Serge, Quénéhervé, Patrick, Salmon, Frédéric, Topart, Patrick   +3 more
core  

Aportaciones al conocimiento florístico de la Sierra de Aracena (Huelva, España) [PDF]

, 1985
A check list of the Sierra de Aracena (Huelva, Spain) is presented. A total of 900 vascular plants have been identificated.Se ha realizado un catálogo floristico de la Sierra de Aracena (Huelva, España), en el que se citan 900 táxones de plantas ...
Cabezudo, Baltasar, Rivera, J.
core   +4 more sources

The TaMADS2‐TaTBL21 Module Enhances Wheat Resistance to Stripe Rust by Activating TaGKL‐Mediated Immunity

Plant Biotechnology Journal, Volume 24, Issue 4, Page 2153-2168, April 2026.
ABSTRACT Wheat stripe rust (Puccinia striiformis f. sp. tritici, Pst) poses a catastrophic threat to global food security. While MADS‐box transcription factors regulate development and abiotic stress, their roles in plant‐pathogen immunity remain enigmatic.
Shijia Zhao, Hao Chu, Yanan Lu, Jiaqi Chen, Xu Wang, Guangxiang Tian, Mingjing Zhang, Pengyu Song, Yanhui Zhang, Guihua Bai, Gangming Zhan, Zhensheng Kang, Wenming Zheng, ZhengQing Fu, Na Liu   +14 more
wiley   +1 more source

Addition of Aegilops biuncialis chromosomes 2M or 3M improves the salt tolerance of wheat in different way

Scientific Reports, 2020
Aegilops biuncialis is a promising gene source to improve salt tolerance of wheat via interspecific hybridization. In the present work, the salt stress responses of wheat-Ae.
Eva Darko, Radwan Khalil, Zsanett Dobi, Viktória Kovács, Gabriella Szalai, Tibor Janda, István Molnár   +6 more
doaj   +1 more source

Sequencing of 15 622 Gene-bearing BACs Clarifies the Gene-dense Regions of the Barley Genome [PDF]

, 2015
Barley (Hordeum vulgare L.) possesses a large and highly repetitive genome of 5.1 Gb that has hindered the development of a complete sequence. In 2012, the International Barley Sequencing Consortium released a resource integrating whole-genome shotgun ...
Alpert, Matthew, Altschmied, Lothar, Beccuti, Marco, Bhat, Prasanna R., Blake, Tom, Bozdag, Serdar, Bregitzer, Phil, Chao, Shiaoman, Close, Timothy J., Condamine, Pascal, Cooper, Laurel, Cordero, Francesca, Dilbirligi, Muharrem, Dolezel, Jaroslav, Duma, Denisa, Falk, Anders, Feiz, Leila, Graner, Andreas, Grimwood, Jane, Gustafson, Perry, Hayes, Patrick M., Heinen, Shane, Jiang, Tao, Kleinhofs, Andris, Kudrna, Dave, Lemaux, Peggy, Lonardi, Stefano, Luo, MingCheng, Ma, Shane, Madishetty, Kavitha, Mammadov, Jafar, Mirebrahim, Hamid, Moscou, Matthew J., Muehlbauer, Gary J., Muñoz-Amatriaín, María, Ounit, Rachid, Resnik, Josh, Rodriguez, Edmundo, Schmutz, Jeremy, Simková, Hana, Stein, Nils, Svensson, Jan T., Wanamaker, Steve, Wing, Rod, Wise, Roger P., Witt, Heather N., Wu, Yonghui, You, Frank, Zheng, Jie   +48 more
core   +2 more sources

TaRIP2 Positively Regulates Wheat Pollen Wall Formation Through MYB80‐Controlled Lipid Metabolism

Plant Biotechnology Journal, Volume 24, Issue 4, Page 2595-2606, April 2026.
ABSTRACT Male‐sterile genes and mutants are critical for hybrid seed production in monocotyledonous crops. Lipids are essential structural components of male reproductive organs, such as the anther and pollen. Here, we show that the pollen‐preferential gene TaRIP2 is essential for wheat anther development and pollen formation. RT‐qPCR analysis revealed
Ran Han, Aifeng Liu, Guang Qi, Chunhao Fang, XiaoLu Wang, Wenjing Xu, Kai Wang, Jihu Li, Qingqi Fan, Dungong Cheng, Faji Li, Haosheng Li, Jianjun Liu, Genying Li, Cheng Liu   +14 more
wiley   +1 more source

Characterization of a New Wheat- 1M(1B) Substitution Line with Good Quality-associated HMW Glutenin Subunit [PDF]

, 2016
In this study, a new substitution line, 12-5-1, with 42 chromosomes that was derived from BC3F2 descendants of the hybridization between Triticum aestivum cv. CN19 and Aegilops biuncialis was created and reported.
Cheng, Y., Deng, K. J., Liu, C., Yang, E. N., Zang, L. L., Zhang, Y., Zheng, X. L., Zhou, J. P., Zhu, Y. Q.   +8 more
core   +1 more source