CSIRO Publishing

Plant sciences, sustainable farming systems and food quality

Shopping Cart: ( empty )

Articles citing this paper

Photoperiod and vernalization gene effects in southern Australian wheat

H. A. Eagles ^A ^I , Karen Cane ^B , Haydn Kuchel ^C , G. J. Hollamby ^C , Neil Vallance ^D ^E , R. F. Eastwood ^F , N. N. Gororo ^G and P. J. Martin ^H

+ Author Affiliations

- Author Affiliations

^A Molecular Plant Breeding CRC, and School of Agriculture, Food and Wine, Waite Campus, University of Adelaide, PMB1, Glen Osmond, SA 5064, Australia.

^B Molecular Plant Breeding CRC, and Department of Primary Industries, PB260, Horsham, Vic. 3401, Australia.

^C Australian Grain Technologies, Roseworthy Campus, University of Adelaide, Roseworthy, SA 5371, Australia.

^D Department of Primary Industries, Mallee Research Station, Walpeup, Vic. 3507, Australia.

^E Present address: Dodgshun Medlin, Ouyen Shire Office, Oke Street, Ouyen, Vic. 3490, Australia.

^F Australian Grain Technologies, PB260, Horsham, Vic. 3401, Australia.

^G Nuseed Pty Ltd, PB377, Horsham, Vic. 3401, Australia.

^H Industry & Investment NSW, Wagga Wagga Agricultural Institute, Wagga Wagga, NSW 2650, Australia.

^I Corresponding author. Email: Howard.Eagles@adelaide.edu.au

Crop and Pasture Science 61(9) 721-730 https://doi.org/10.1071/CP10121
Submitted: 7 April 2010 Accepted: 22 July 2010 Published: 9 September 2010

61 articles found in Crossref database.

Deciphering the genetics of flowering time by an association study on candidate genes in bread wheat (Triticum aestivum L.)

Rousset Michel, Bonnin Isabelle, Remoué Carine, Falque Matthieu, Rhoné Bénédicte, Veyrieras Jean-Baptiste, Madur Delphine, Murigneux Alain, Balfourier François, Le Gouis Jacques, Santoni Sylvain, Goldringer Isabelle

Theoretical and Applied Genetics. 2011 123(6). p.907

Determining the Genetic Architecture of Reproductive Stage Drought Tolerance in Wheat Using a Correlated Trait and Correlated Marker Effect Model

Dolferus Rudy, Thavamanikumar Saravanan, Sangma Harriet, Kleven Sue, Wallace Xiaomei, Forrest Kerrie, Rebetzke Gregory, Hayden Matthew, Borg Lauren, Smith Alison, Cullis Brian

G3 Genes|Genomes|Genetics. 2019 9(2). p.473

ALLELIC DIVERSITY OF GENES CONTROLLING RESPONSES TO VERNALIZATION AND PHOTOPERIOD AMONG SPRING BREAD WHEAT VARIETIES OF DIVERSE GEOGRAPHIC ORIGIN

Kalybekova Zh. T.

Proceedings on applied botany, genetics and breeding. 2020 180(4). p.177

An allelic based phenological model to predict phasic development of wheat (Triticum aestivum L.)

Christy Brendan, Riffkin Penny, Richards Richard, Partington Debra, Acuña Tina Botwright, Merry Angela, Zhang Heping, Trevaskis Ben, O’Leary Garry

Field Crops Research. 2020 249 p.107722

Allele frequencies in the VRN-A1, VRN-B1 and VRN-D1 vernalization response and PPD-B1 and PPD-D1 photoperiod sensitivity genes, and their effects on heading in a diverse set of wheat cultivars (Triticum aestivum L.)

Kiss Tibor, Balla Krisztina, Veisz Ottó, Láng László, Bedő Zoltán, Griffiths Simon, Isaac Peter, Karsai Ildikó

Molecular Breeding. 2014 34(2). p.297

Winter wheat cultivars in Australian farming systems: a review

Hunt James R.

Crop and Pasture Science. 2017 68(6). p.501

Abiotic Stress Management for Resilient Agriculture (2017)

Kumar S. Naresh

Climate change enhances stability of wheat-flowering-date

He Yong, Xiong Wei, Hu Pengcheng, Huang Daiqing, Feurtado J. Allan, Zhang Tianyi, Hao Chenyang, DePauw Ron, Zheng Bangyou, Hoogenboom Gerrit, Dixon Laura E., Wang Hong, Challinor Andrew Juan

Science of The Total Environment. 2024 917 p.170305

Effects of genetic components of plant development on yield-related traits in wheat (Triticum aestivum L.) under stress-free conditions

Horváth Ádám, Kiss Tibor, Berki Zita, Horváth Ádám D., Balla Krisztina, Cseh András, Veisz Ottó, Karsai Ildikó

Frontiers in Plant Science. 2023 13

Developing Wheat for Improved Yield and Adaptation Under a Changing Climate: Optimization of a Few Key Genes

Nazim Ud Dowla M.A.N., Edwards Ian, O'Hara Graham, Islam Shahidul, Ma Wujun

Engineering. 2018 4(4). p.514

Responses to phosphorus among barley genotypes

McDonald G. K., Taylor J. D., Gong X., Bovill W.

Crop and Pasture Science. 2018 69(6). p.574

Veery wheats carry an allele of Vrn‐A1 that has implications for freezing tolerance in winter wheats

Eagles Howard A., Cane Karen, Trevaskis Ben

Plant Breeding. 2011 130(4). p.413

Flowering time control in European winter wheat

Langer Simon M., Longin C. Friedrich H., WÃ¼rschum Tobias

Frontiers in Plant Science. 2014 5

Identification of QTLs for wheat heading time across multiple-environments

Benaouda Salma, Dadshani Said, Koua Patrice, Léon Jens, Ballvora Agim

Theoretical and Applied Genetics. 2022 135(8). p.2833

The storage protein activator gene Spa-B1 and grain quality traits in southern Australian wheat breeding programs

Eagles H. A., Cane Karen, Appelbee Marie, Kuchel Haydn, Eastwood R. F., Martin P. J.

Crop and Pasture Science. 2012 63(4). p.311

Genomic selection for winter survival ability among a diverse collection of facultative and winter wheat genotypes

Beil Craig T., Anderson Victoria A., Morgounov Alexey, Haley Scott D.

Molecular Breeding. 2019 39(2).

Impact of Breeding on Free Amino Acids of Wholegrain Flour in Wheat and Role of Phenology Genes

Emebiri Livinus

Recent Progress in Nutrition. 2023 03(04). p.1

Genome-wide association study of heading and flowering dates and construction of its prediction equation in Chinese common wheat

Zhang Xiangfen, Chen Jianhui, Yan Yan, Yan Xuefang, Shi Chaonan, Zhao Lei, Chen Feng

Theoretical and Applied Genetics. 2018 131(11). p.2271

Allelic Variation in Developmental Genes and Effects on Winter Wheat Heading Date in the U.S. Great Plains

Grogan Sarah M., Brown-Guedira Gina, Haley Scott D., McMaster Gregory S., Reid Scott D., Smith Jared, Byrne Patrick F., Zhang Aimin

PLOS ONE. 2016 11(4). p.e0152852

Understanding the Effects of Growing Seasons, Genotypes, and Their Interactions on the Anthesis Date of Wheat Sown in North China

Li Ziwei, Zheng Bangyou, He Yong

Biology. 2021 10(10). p.955

Distribution of Allelic Variation for Genes of Vernalization and Photoperiod among Wheat Cultivars from 23 Countries

YANG Fang-Ping, HAN Li-Ming, YAN Jun, XIA Xian-Chun, ZHANG Yong, QU Yan-Ying, WANG Zhong-Wei, HE Zhong-Hu

ACTA AGRONOMICA SINICA. 2012 37(11). p.1917

Assessing the importance of subsoil constraints to yield of wheat and its implications for yield improvement

McDonald G. K., Taylor J. D., Verbyla A., Kuchel H.

Crop and Pasture Science. 2012 63(12). p.1043

Ability of alleles of PPD1 and VRN1 genes to predict flowering time in diverse Australian wheat (Triticum aestivum) cultivars in controlled environments

Bloomfield Maxwell T., Hunt James R., Trevaskis Ben, Ramm Kerrie, Hyles Jessica

Crop and Pasture Science. 2018 69(11). p.1061

Artificial selection causes significant linkage disequilibrium among multiple unlinked genes in Australian wheat

Joukhadar Reem, Daetwyler Hans D., Gendall Anthony R., Hayden Matthew J.

Evolutionary Applications. 2019 12(8). p.1610

Wheat physiology: a review of recent developments

Fischer R. A.

Crop and Pasture Science. 2011 62(2). p.95

Integration of molecular and physiological models to explain time of anthesis in wheat

Brown Hamish E., Jamieson Peter D., Brooking Ian R., Moot Derrick J., Huth Neil I.

Annals of Botany. 2013 112(9). p.1683

Pulse ideotypes for abiotic constraint alleviation in Australia

Rao Shiwangni, Silva-Perez Viridiana, Armstrong Roger, Tefera Abeya Temesgen, Brand Jason, Riffkin Penny, Rosewarne Garry

Plant and Soil. 2023 492(1-2). p.1

Allelic Variations in Vernalization (Vrn) Genes in Triticum spp.

Afshari-Behbahanizadeh Sanaz, Puglisi Damiano, Esposito Salvatore, De Vita Pasquale

Genes. 2024 15(2). p.251

Effect of VRN‐1 and PPD‐D1 genes on heading time in European bread wheat cultivars

Shcherban Andrey B., Börner Andreas, Salina Elena A., Jung C.

Plant Breeding. 2015 134(1). p.49

Advancing understanding of oat phenology for crop adaptation

Trevaskis Ben, Harris Felicity A. J., Bovill William D., Rattey Allan R., Khoo Kelvin H. P., Boden Scott A., Hyles Jessica

Frontiers in Plant Science. 2022 13

Fine mapping and genetic analysis identified a C2H2-type zinc finger as a candidate gene for heading date regulation in wheat

Li Yuting, Xiong Hongchun, Guo Huijun, Zhou Chunyun, Fu Meiyu, Xie Yongdun, Zhao Linshu, Gu Jiayu, Zhao Shirong, Ding Yuping, Wang Chaojie, Irshad Ahsan, Liu Luxiang, Fang Zhengwu

Theoretical and Applied Genetics. 2023 136(6).

Photoperiod and Vernalization Effect on Anthesis Date in Winter‐Sown Spring Wheat Regions

Ottman Michael J., Anthony Hunt L., White Jeffrey W.

Agronomy Journal. 2013 105(4). p.1017

Phenology and Dwarfing Gene Interaction Effects on the Adaptation of Selected Wheat (Triticum aestivum L.) Advanced Lines across Diverse Water-Limited Environments of Western Australia

Dowla Mirza A.N.N.U., Islam Shahidul, Stefanova Katia, Hara Graham O’, Ma Wujun, Edwards Ian

Agriculture. 2020 10(10). p.470

Allelic Variation at the VRN-1 Locus of Polish Cultivars of Common Wheat (Triticum aestivum L.)

Nowak Michał, Kowalczyk Krzysztof

Acta Biologica Cracoviensia Series Botanica. 2010 52(2).

Forage and grain yield of grazed or defoliated spring and winter cereals in a winter-dominant, low-rainfall environment

Frischke Alison. J., Hunt James R., McMillan Dannielle K., Browne Claire J.

Crop and Pasture Science. 2015 66(4). p.308

High-yielding lines of wheat carrying Gpc-B1 adapted to Mediterranean-type environments of the south and west of Australia

Eagles H. A., McLean Robyn, Eastwood R. F., Appelbee M.-J., Cane Karen, Martin P. J., Wallwork H.

Crop and Pasture Science. 2014 65(9). p.854

Vernalisation and photoperiod responses of diverse wheat genotypes

Bloomfield Maxwell T., Celestina Corinne, Hunt James R., Huth Neil, Zheng Bangyou, Brown Hamish, Zhao Zhigan, Wang Enli, Stefanova Katia, Hyles Jessica, Rathjen Tina, Trevaskis Ben, Park Robert

Crop & Pasture Science. 2023 74(5). p.405

Distribution of Allelic Variation for Vernalization, Photoperiod, and Dwarfing Genes and Their Effects on Growth Period and Plant Height among Cultivars from Major Wheat Producing Countries

YANG Fang-Ping, XIA Xian-Chun, ZHANG Yong, ZHANG Xiao-Ke, LIU Jian-Jun, TANG Jian-Wei, YANG Xue-Ming, ZHANG Jun-Ru, LIU Qian, LI Shi-Zhao, HE Zhong-Hu

ACTA AGRONOMICA SINICA. 2013 38(7). p.1155

Genetic dissection of wheat panicle traits using linkage analysis and a genome-wide association study

Liu Kai, Sun Xiaoxiao, Ning Tangyuan, Duan Xixian, Wang Qiaoling, Liu Tongtong, An Yuling, Guan Xin, Tian Jichun, Chen Jiansheng

Theoretical and Applied Genetics. 2018 131(5). p.1073

The effect of duration of the vegetative phase in irrigated semi-dwarf spring wheat on phenology, growth and potential yield across sowing dates at low latitude

Fischer R.A.

Field Crops Research. 2016 198 p.188

Genome-Wide Associations for Water-Soluble Carbohydrate Concentration and Relative Maturity in Wheat Using SNP and DArT Marker Arrays

Ovenden Ben, Milgate Andrew, Wade Len J, Rebetzke Greg J, Holland James B

G3 Genes|Genomes|Genetics. 2017 7(8). p.2821

A QTL on the short arm of wheat (Triticum aestivum L.) chromosome 3B affects the stability of grain weight in plants exposed to a brief heat shock early in grain filling

Shirdelmoghanloo Hamid, Taylor Julian D., Lohraseb Iman, Rabie Huwaida, Brien Chris, Timmins Andy, Martin Peter, Mather Diane E., Emebiri Livinus, Collins Nicholas C.

BMC Plant Biology. 2016 16(1).

Crop Breeding (2014)

Trethowan Richard M.

Genetics of flowering time in bread wheat Triticum aestivum: complementary interaction between vernalization-insensitive and photoperiod-insensitive mutations imparts very early flowering habit to spring wheat

KUMAR SUSHIL, SHARMA VISHAKHA, CHAUDHARY SWATI, TYAGI ANSHIKA, MISHRA POONAM, PRIYADARSHINI ANUPAMA, SINGH ANUPAM

Journal of Genetics. 2012 91(1). p.33

Ppd-B1 and Ppd-D1 and their effects in southern Australian wheat

Cane Karen, Eagles H. A., Laurie D. A., Trevaskis Ben, Vallance Neil, Eastwood R. F., Gororo N. N., Kuchel Haydn, Martin P. J.

Crop and Pasture Science. 2013 64(2). p.100

Analysis of VRN1 gene in triticale and common wheat genetic background

Nowak Michał, Leśniowska-Nowak Justyna, Zapalska Magdalena, Banaszak Zofia, Kondracka Katarzyna, Dudziak Karolina, Kowalczyk Krzysztof

Scientia Agricola. 2014 71(5). p.380

Ppd1, Vrn1, ALMT1 and Rht genes and their effects on grain yield in lower rainfall environments in southern Australia

Eagles H. A., Cane Karen, Trevaskis Ben, Vallance Neil, Eastwood R. F., Gororo N. N., Kuchel Haydn, Martin P. J.

Crop and Pasture Science. 2014 65(2). p.159

Genetic Architecture of Cereal Leaf Beetle Resistance in Wheat

Würschum Tobias, Leiser Willmar L., Langer Simon M., Tucker Matthew R., Miedaner Thomas

Plants. 2020 9(9). p.1117

Commercially available wheat cultivars are broadly adapted to location and time of sowing in Australia’s grain zone

Lawes R.A., Huth N.D., Hochman Z.

European Journal of Agronomy. 2016 77 p.38

Interactive Effects of Vernalization and Photoperiod Loci on Phenological Traits and Grain Yield and Differentiation of Iranian Wheat Landraces and Cultivars

Alipour Hadi, Abdi Hossein

Journal of Plant Growth Regulation. 2021 40(5). p.2105

Short, natural, and extended photoperiod response in BC2F4 lines of bread wheat with different Photoperiod-1 (Ppd-1) alleles

Bentley A.R., Horsnell R., Werner C.P., Turner A.S., Rose G.A., Bedard C., Howell P., Wilhelm E.P., Mackay I.J., Howells R.M., Greenland A., Laurie D.A., Gosman N.

Journal of Experimental Botany. 2013 64(7). p.1783

Genetic control of grain yield and grain physical characteristics in a bread wheat population grown under a range of environmental conditions

Maphosa Lancelot, Langridge Peter, Taylor Helen, Parent Boris, Emebiri Livinus C., Kuchel Haydn, Reynolds Matthew P., Chalmers Ken J., Okada Anzu, Edwards James, Mather Diane E.

Theoretical and Applied Genetics. 2014 127(7). p.1607

Wheat Improvement, Management and Utilization (2017)

Khumalo Thobeka P., Barnard Annelie, Maphosa Lancelot, Tsilo Toi J.

Linking genetic maps and simulation to optimize breeding for wheat flowering time in current and future climates

Bogard Matthieu, Biddulph Ben, Zheng Bangyou, Hayden Matthew, Kuchel Haydn, Mullan Dan, Allard Vincent, Gouis Jacques Le, Chapman Scott C.

Crop Science. 2020 60(2). p.678

Molecular characterization of vernalization and photoperiod genes in wheat varieties from different agro-climatic zones of India

Singh S., Singh A., Jain N., Singh G., Ahlawat A., Ravi I.

Cereal Research Communications. 2013 41(3). p.376

Diagnostic Markers for Vernalization and Photoperiod Loci Improve Genomic Selection for Grain Yield and Spectral Reflectance in Wheat

Mason R. Esten, Addison Christopher K., Babar Ali, Acuna Andrea, Lozada Dennis, Subramanian Nithya, Arguello Maria Nelly, Miller Randall G., Brown‐Guedira Gina, Guedira Mohammed, Johnson Jerry

Crop Science. 2018 58(1). p.242

Quantification of the effects of VRN1 and Ppd-D1 to predict spring wheat (Triticum aestivum) heading time across diverse environments

Zheng Bangyou, Biddulph Ben, Li Dora, Kuchel Haydn, Chapman Scott

Journal of Experimental Botany. 2013 64(12). p.3747

Accounting for soil moisture improves prediction of flowering time in chickpea and wheat

Chauhan Yashvir S., Ryan Merrill, Chandra Subhash, Sadras Victor O.

Scientific Reports. 2019 9(1).

Use of different temporal scales to monitor phenology and its relationship with temporal evolution of normalized difference vegetation index in wheat

González-Gómez Laura, Campos Isidro, Calera Alfonso

Journal of Applied Remote Sensing. 2018 12(02). p.1

Effect of Ppd-A1 and Ppd-B1 Allelic Variants on Grain Number and Thousand Kernel Weight of Durum Wheat and Their Impact on Final Grain Yield

Arjona Jose M., Royo Conxita, Dreisigacker Susanne, Ammar Karim, Villegas Dolors

Frontiers in Plant Science. 2018 9

Innovation and productivity in dryland agriculture: a return-risk analysis for Australia

CARBERRY P. S., BRUCE S. E., WALCOTT J. J., KEATING B. A.

The Journal of Agricultural Science. 2011 149(S1). p.77