Lin Xiuling, Long Yuming, Yao Zhen, Shen Boran, Lin Min, Zhong Xiaofen, Chen Xiaohong, Li Xiangyang, Zhu Guohui, Zhang Zhisheng, Peng Xinxiang
State Key Laboratory for Conservation and Utilization of Subtropical Agro-Bioresources, College of Life Sciences, South China Agricultural University, Guangzhou, China.
College of Horticulture and Food, Guangdong Eco-Engineering Polytechnic, Guangzhou, China.
Plant Biotechnol J. 2025 Jul;23(7):2526-2536. doi: 10.1111/pbi.70076. Epub 2025 Apr 2.
The bioengineering of photorespiration has emerged as a key target for improving photosynthesis and crop yield. In our previous study, two photorespiratory bypasses, GOC and GCGT, were successfully established in rice, and the transgenic plants exhibited increased photosynthesis and yield. However, reduced seed-setting rates were observed in both GOC and GCGT rice. To overcome this bottleneck, we introduced the GOC bypass into potato, as potato is vegetatively reproduced without the need for pollination, unlike rice. After the GOC bypass was successfully established in potato, transgenic plants were tested in field experiments at different locations in China with contrasting climates. Consequently, the yield per plant increased by 21.3%-69.2% for GOC potatoes under normal growth conditions and enhanced by 12.9%-29.9% under adverse environments. GOC potatoes acquired a more stable yield increase than GOC rice. Moreover, the advantages under high light, as noticed earlier for GOC rice, were further verified in this study through various field experiments because the yield increase was obviously higher in GOC potatoes grown in the northern area with high solar radiation than in those grown in the south with relatively lower solar radiation. Mechanistic analyses indicated that photosynthesis increased while photorespiration was suppressed, and much fewer photosynthates accumulated in GOC potatoes. These results demonstrate that the GOC bypass increases yield per plant more stably in potato than in rice, as well as show promising prospects for practical application in improving crop yields, particularly under high-light conditions.
光呼吸的生物工程已成为提高光合作用和作物产量的关键目标。在我们之前的研究中,已在水稻中成功建立了两条光呼吸支路,即GOC和GCGT,转基因植株的光合作用和产量均有所提高。然而,在GOC和GCGT水稻中均观察到结实率降低的现象。为克服这一瓶颈,我们将GOC支路引入马铃薯,因为与水稻不同,马铃薯通过无性繁殖,无需授粉。在马铃薯中成功建立GOC支路后,在中国不同气候的地区对转基因植株进行了田间试验。结果表明,在正常生长条件下,GOC马铃薯单株产量提高了21.3%-69.2%,在逆境环境下单株产量提高了12.9%-29.9%。GOC马铃薯的产量增幅比GOC水稻更稳定。此外,正如之前在GOC水稻中所观察到的,在高光条件下的优势在本研究中通过各种田间试验得到了进一步验证,因为在太阳辐射高的北方地区种植的GOC马铃薯的产量增幅明显高于在太阳辐射相对较低的南方地区种植的GOC马铃薯。机理分析表明,GOC马铃薯的光合作用增强而光呼吸受到抑制,光合产物积累减少。这些结果表明,GOC支路在马铃薯中比在水稻中更稳定地提高单株产量,并且在提高作物产量,特别是在高光条件下的实际应用中显示出广阔前景。
