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2023 Other Outputs Core Sorghum Breeding (Crop Wild Relatives-South East QLD in 2018)Jordan, David, Cruickshank, Alan, Hunt, Colleen and Mace, Emma (2023). Core Sorghum Breeding (Crop Wild Relatives-South East QLD in 2018). The University of Queensland. (Dataset) doi: 10.48610/82ac313 |
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2023 Other Outputs Core Sorghum Breeding (DGP-Central QLD in years 2004 to 2019)Jordan, David, Cruickshank, Alan, Hunt, Colleen and Mace, Emma (2023). Core Sorghum Breeding (DGP-Central QLD in years 2004 to 2019). The University of Queensland. (Dataset) doi: 10.48610/2e8465b |
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2023 Other Outputs Core Sorghum Breeding (DGP-South West QLD in years 2006 to 2011)Jordan, David, Cruickshank, Alan, Hunt, Colleen and Mace, Emma (2023). Core Sorghum Breeding (DGP-South West QLD in years 2006 to 2011). The University of Queensland. (Dataset) doi: 10.48610/ad0ed20 |
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2023 Other Outputs Core Sorghum Breeding (Midge-South East QLD in years 2017 to 2020)Jordan, David, Cruickshank, Alan, Hunt, Colleen and Mace, Emma (2023). Core Sorghum Breeding (Midge-South East QLD in years 2017 to 2020). The University of Queensland. (Dataset) doi: 10.48610/44b9cad |
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2023 Other Outputs Core Sorghum Breeding (Breeding Trials-South West QLD in years 2006 to 2011)Jordan, David, Cruickshank, Alan, Hunt, Colleen and Mace, Emma (2023). Core Sorghum Breeding (Breeding Trials-South West QLD in years 2006 to 2011). The University of Queensland. (Dataset) doi: 10.48610/e05c9c6 |
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2023 Other Outputs Core Sorghum Breeding (Breeding Trials-Central QLD in years 2004 to 2020)Jordan, David, Cruickshank, Alan, Hunt, Colleen and Mace, Emma (2023). Core Sorghum Breeding (Breeding Trials-Central QLD in years 2004 to 2020). The University of Queensland. (Dataset) doi: 10.48610/8bd7ba2 |
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2023 Other Outputs Core Sorghum Breeding (Breeding Trials-South East QLD in years 2004 to 2022)Jordan, David, Cruickshank, Alan, Hunt, Colleen and Mace, Emma (2023). Core Sorghum Breeding (Breeding Trials-South East QLD in years 2004 to 2022). The University of Queensland. (Dataset) doi: 10.48610/35920ea |
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2023 Other Outputs Core Sorghum Breeding (Breeding Trials-North East NSW in years 2007 to 2018)Jordan, David, Cruickshank, Alan, Hunt, Colleen and Mace, Emma (2023). Core Sorghum Breeding (Breeding Trials-North East NSW in years 2007 to 2018). The University of Queensland. (Dataset) doi: 10.48610/b1a9171 |
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2022 Journal Article Genetic and genomic diversity in the sorghum gene bank collection of UgandaChakrabarty, Subhadra, Mufumbo, Raphael, Windpassinger, Steffen, Jordan, David, Mace, Emma, Snowdon, Rod J. and Hathorn, Adrian (2022). Genetic and genomic diversity in the sorghum gene bank collection of Uganda. BMC Plant Biology, 22 (1) 378, 1-11. doi: 10.1186/s12870-022-03770-y |
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2022 Conference Publication Ensuring the future of taroCampbell, Bradley, Godwin, Ian, Mace, Emma, Sukal, Amit, Waqainabete, Logo, Restall, Jemma and Smith, Millicent (2022). Ensuring the future of taro. TropAg International Agriculture Conference, Brisbane, QLD Australia, 31 October - 2 November 2022. |
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2022 Journal Article Genetic modification of PIN genes induces causal mechanisms of stay-green drought adaptation phenotypeBorrell, Andrew K., Wong, Albert C. S., George-Jaeggli, Barbara, van Oosterom, Erik J., Mace, Emma S., Godwin, Ian D., Liu, Guoquan, Mullet, John E., Klein, Patricia E., Hammer, Graeme L., McLean, Greg, Hunt, Colleen and Jordan, David R. (2022). Genetic modification of PIN genes induces causal mechanisms of stay-green drought adaptation phenotype. Journal of Experimental Botany, 73 (19), 6711-6726. doi: 10.1093/jxb/erac336 |
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2022 Journal Article Genetic basis of sorghum leaf width and its potential as a surrogate for transpiration efficiencyZhi, Xiaoyu, Hammer, Graeme, Borrell, Andrew, Tao, Yongfu, Wu, Alex, Hunt, Colleen, van Oosterom, Erik, Massey-Reed, Sean Reynolds, Cruickshank, Alan, Potgieter, Andries B., Jordan, David, Mace, Emma and George-Jaeggli, Barbara (2022). Genetic basis of sorghum leaf width and its potential as a surrogate for transpiration efficiency. Theoretical and Applied Genetics, 135 (9), 3057-3071. doi: 10.1007/s00122-022-04167-z |
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2022 Journal Article Maximizing value of genetic sequence data requires an enabling environment and urgencyGaffney, Jim, Girma, Dejene, Kane, Ndjido Ardo, Llaca, Victor, Mace, Emma, Taylor, Nigel and Tibebu, Redeat (2022). Maximizing value of genetic sequence data requires an enabling environment and urgency. Global Food Security, 33 100619, 100619. doi: 10.1016/j.gfs.2022.100619 |
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2022 Journal Article Decoding the sorghum methylome: understanding epigenetic contributions to agronomic traitsVafadarshamasbi, Ulduz, Mace, Emma, Jordan, David and Crisp, Peter A. (2022). Decoding the sorghum methylome: understanding epigenetic contributions to agronomic traits. Biochemical Society Transactions, 50 (1), 583-596. doi: 10.1042/bst20210908 |
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2021 Journal Article Genetic control of leaf angle in sorghum and its effect on light interceptionZhi, Xiaoyu, Tao, Yongfu, Jordan, David, Borrell, Andrew, Hunt, Colleen, Cruickshank, Alan, Potgieter, Andries, Wu, Alex, Hammer, Graeme, George-Jaeggli, Barbara and Mace, Emma (2021). Genetic control of leaf angle in sorghum and its effect on light interception. Journal of Experimental Botany, 73 (3) erab467, 801-816. doi: 10.1093/jxb/erab467 |
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2021 Journal Article Manipulating assimilate availability provides insight into the genes controlling grain size in sorghumTao, Yongfu, Trusov, Yuri, Zhao, Xianrong, Wang, Xuemin, Cruickshank, Alan W., Hunt, Colleen, van Oosterom, Erik J., Hathorn, Adrian, Liu, Guoquan, Ian, Godwin D., Botella, Jose R., Mace, Emma S. and Jordan, David R. (2021). Manipulating assimilate availability provides insight into the genes controlling grain size in sorghum. The Plant Journal, 108 (1) tpj.15437, 1-13. doi: 10.1111/tpj.15437 |
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2021 Journal Article Extensive variation within the pan-genome of cultivated and wild sorghumTao, Yongfu, Luo, Hong, Xu, Jiabao, Cruickshank, Alan, Zhao, Xianrong, Teng, Fei, Hathorn, Adrian, Wu, Xiaoyuan, Liu, Yuanming, Shatte, Tracey, Jordan, David, Jing, Haichun and Mace, Emma (2021). Extensive variation within the pan-genome of cultivated and wild sorghum. Nature Plants, 7 (6), 766-773. doi: 10.1038/s41477-021-00925-x |
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2021 Journal Article Genomic resources in plant breeding for sustainable agricultureThudi, Mahendar, Palakurthi, Ramesh, Schnable, James C., Chitikineni, Annapurna, Dreisigacker, Susanne, Mace, Emma, Srivastava, Rakesh K., Satyavathi, C. Tara, Odeny, Damaris, Tiwari, Vijay K., Lam, Hon-Ming, Hong, Yan Bin, Singh, Vikas K., Li, Guowei, Xu, Yunbi, Chen, Xiaoping, Kaila, Sanjay, Nguyen, Henry, Sivasankar, Sobhana, Jackson, Scott A., Close, Timothy J., Shubo, Wan and Varshney, Rajeev K. (2021). Genomic resources in plant breeding for sustainable agriculture. Journal of Plant Physiology, 257 153351, 1-18. doi: 10.1016/j.jplph.2020.153351 |
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2021 Journal Article Enhancement of sorghum grain yield and nutrition: a role for arbuscular mycorrhizal fungi regardless of soil phosphorus availabilityWatts-Williams, Stephanie J., Gill, Alison R., Jewell, Nathaniel, Brien, Christopher J., Berger, Bettina, Tran, Binh T. T., Mace, Emma, Cruickshank, Alan W., Jordan, David R., Garnett, Trevor and Cavagnaro, Timothy R. (2021). Enhancement of sorghum grain yield and nutrition: a role for arbuscular mycorrhizal fungi regardless of soil phosphorus availability. Plants, People, Planet, 4 (2), 143-156. doi: 10.1002/ppp3.10224 |
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2021 Book Chapter SorghumBorrell, Andrew, van Oosterom, Erik, George-Jaeggli, Barbara, Rodriguez, Daniel, Eyre, Joe, Jordan, David J., Mace, Emma, Singh, Vijaya, Vadez, Vincent, Bell, Mike, Godwin, Ian, Cruickshank, Alan, Tao, Yongfu and Hammer, Graeme (2021). Sorghum. Crop physiology: case histories for major crops. (pp. 196-221) edited by Victor O. Sadras and Daniel F. Calderini. London, United Kingdom: Academic Press. doi: 10.1016/B978-0-12-819194-1.00005-0 |
