African Sustainable Agriculture Research Institute (ASARI), Mohammed VI Polytechnic University (UM6P), Laâyoune, Morocco.
AgroBioSciences Department (AgBS), Mohammed VI Polytechnic University (UM6P), Ben Guerir, Morocco.
BMC Plant Biol. 2024 Jul 19;24(1):690. doi: 10.1186/s12870-024-05406-9.
Sorghum (Sorghum bicolor) is a promising opportunity crop for arid regions of Africa due to its high tolerance to drought and heat stresses. Screening for genetic variability in photosynthetic regulation under salt stress can help to identify target trait combinations essential for sorghum genetic improvement. The primary objective of this study was to identify reliable indicators of photosynthetic performance under salt stress for forage yield within a panel of 18 sorghum varieties from stage 1 (leaf 3) to stage 7 (late flowering to early silage maturity). We dissected the genetic diversity and variability in five stress-sensitive photosynthetic parameters: nonphotochemical chlorophyll fluorescence quenching (NPQ), the electron transport rate (ETR), the maximum potential quantum efficiency of photosystem II (F/F), the CO assimilation rate (A), and the photosynthetic performance based on absorption (PI). Further, we investigated potential genes for target phenotypes using a combined approach of bioinformatics, transcriptional analysis, and homologous overexpression.
The panel revealed polymorphism, two admixed subpopulations, and significant molecular variability between and within population. During the investigated development stages, the PI varied dramatically and consistently amongst varieties. Under higher saline conditions, PI also showed a significant positive connection with A and dry matter gain. Because PI is a measure of plants' overall photosynthetic performance, it was applied to predict the salinity performance index (SPI). The SPI correlated positively with dry matter gain, demonstrating that PI could be used as a reliable salt stress performance marker for forage sorghum. Eight rubisco large subunit genes were identified in-silico and validated using qPCR with variable expression across the varieties under saline conditions. Overexpression of Rubisco Large Subunit 8 increased PI, altered the OJIP, and growth with an insignificant effect on A.
These findings provide insights into strategies for enhancing the photosynthetic performance of sorghum under saline conditions for improved photosynthetic performance and potential dry matter yield. The integration of molecular approaches, guided by the identified genetic variability, holds promise for genetically breeding sorghum tailored to thrive in arid and saline environments, contributing to sustainable agricultural practices.
高粱(Sorghum bicolor)对干旱和热胁迫具有很高的耐受性,因此是非洲干旱地区很有前途的机会作物。在盐胁迫下筛选光合作用调节的遗传可变性有助于确定高粱遗传改良所必需的目标性状组合。本研究的主要目的是在 18 个高粱品种的小组中鉴定出在盐胁迫下对饲用产量有可靠影响的光合作用性能指标,这些品种的生育期从第 1 期(第 3 叶)到第 7 期(开花后期到青贮早期成熟)。我们剖析了五个对光合作用敏感的参数的遗传多样性和可变性:非光化学叶绿素荧光猝灭(NPQ)、电子传递率(ETR)、最大光化学系统 II 量子效率(F/F)、CO 同化率(A)和基于吸收的光合作用性能(PI)。此外,我们使用生物信息学、转录分析和同源过表达相结合的方法,研究了潜在的目标表型基因。
该小组揭示了多态性、两个混合亚群以及群体内和群体间的显著分子可变性。在所研究的发育阶段,品种间的 PI 差异很大且一致。在较高盐度条件下,PI 也与 A 和干物质增益呈显著正相关。由于 PI 是植物整体光合作用性能的衡量标准,因此它被用于预测盐度性能指数(SPI)。SPI 与干物质增益呈正相关,表明 PI 可作为饲用高粱盐胁迫性能的可靠标记。在盐胁迫条件下,通过 qPCR 鉴定了 8 个 Rubisco 大亚基基因,并对其进行了验证,结果表明这些基因在品种间的表达存在差异。Rubisco 大亚基 8 的过表达增加了 PI,改变了 OJIP,并对 A 有一定的影响,但对生长没有影响。
这些发现为提高高粱在盐胁迫下的光合作用性能以提高光合作用性能和潜在干物质产量提供了策略。分子方法的整合,以鉴定出的遗传可变性为指导,有望为在干旱和盐渍环境中茁壮成长的高粱进行遗传育种,为可持续农业实践做出贡献。
