The dwarf & pale leaf mutation reduces chloroplast numbers, resulting in sugar depletion that inhibits leaf growth of maize seedlings

IF 5.4 Q1 PLANT SCIENCES Current Plant Biology Pub Date : 2024-11-06 DOI:10.1016/j.cpb.2024.100409
Hamada AbdElgawad , Katrien Sprangers , Sofie Thys , Isabel Pintelon , Bart Cuypers , Mohamed A. El-Tayeb , Clifford Weil , Kris Laukens , Gerrit T.S. Beemster
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Abstract

Plant growth is ultimately driven by cell division and expansion, but how these processes are regulated to mediate a wide range of genotypic variation in organ size is still poorly understood. To address this, we screened an EMS maize mutant population to identify a new EMS maize dwarf mutant with small, pale-yellow leaves (dpl). The mutation was mapped to a region of 11.58 Mb at the 3’ end of chromosome 7. We identified Zm00001d022394 as a potential causal gene for the dpl phenotype, encoding a pentatricopeptide repeat-containing (PPR) family protein involved in chloroplast gene expression and function, explaining the pale color of dpl. Mature dpl leaves are thinner and shorter due to a reduced number of cells of approximately normal length. The chloroplasts of dpl are reduced in size and number, correlating with a decreased chlorophyll content, however chloroplast ultrastructure was not affected. Consistent with the reduced chlorophyll content photosynthetic rate of dpl were reduced by 50 % and a 30 reduction of Fv/Fm suggests photoinhibition. As a consequence, soluble and insoluble sugar levels are severely reduced throughout the leaf growth zone. At the cell level reduced cell division rates and size of the division zone, explain the reduced leaf elongation rate (LER). The growth of dpl leaves can be restored by supplying growing leaves with sucrose through their cut tips, which also restores sucrose levels in the division zone of maize leaf, demonstrating that limited sugar availability explains the reduced growth phenotype. Inversely, we phenocopied the mutant growth phenotype by inhibiting photosynthetic electron transport in wild type plants with DCMU (3-(3,4-dichlorophenyl)-1,1-dimethylurea). Our study of dpl provides a functional link between inhibition of photosynthesis, soluble sugar flux to the leaf growth zone, the regulation of cell division and whole leaf growth.
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矮化和苍白叶突变会减少叶绿体数量,导致糖分耗竭,从而抑制玉米幼苗的叶片生长
植物生长最终是由细胞分裂和扩展驱动的,但人们对这些过程如何调控以介导器官大小的广泛基因型变异仍然知之甚少。为了解决这个问题,我们筛选了一个 EMS 玉米突变体群体,发现了一个新的 EMS 玉米矮小突变体,该突变体叶片较小,呈淡黄色(dpl)。该突变被映射到 7 号染色体 3' 端 11.58 Mb 的区域。我们发现 Zm00001d022394 是 dpl 表型的潜在致病基因,它编码一种含五肽重复(PPR)的家族蛋白,参与叶绿体基因的表达和功能,从而解释了 dpl 叶片颜色变淡的原因。成熟的 dpl 叶片更薄、更短,这是因为长度接近正常的细胞数量减少了。dpl 的叶绿体在大小和数量上都有所减少,这与叶绿素含量的减少有关,但叶绿体的超微结构并未受到影响。与叶绿素含量减少相一致的是,dpl 的光合速率降低了 50%,Fv/Fm 降低了 30%,这表明存在光抑制。因此,整个叶片生长区的可溶性和不溶性糖含量都严重下降。在细胞水平上,细胞分裂率和分裂区大小的降低解释了叶片伸长率(LER)降低的原因。通过向生长叶片的切端供应蔗糖,可以恢复 dpl 叶片的生长,这也恢复了玉米叶片分裂区的蔗糖水平,表明糖的有限供应可以解释生长表型的降低。相反,我们用 DCMU(3-(3,4-二氯苯基)-1,1-二甲基脲)抑制野生型植株的光合电子传递,从而表征了突变体的生长表型。我们对 dpl 的研究提供了光合作用抑制、叶片生长区可溶性糖通量、细胞分裂调节和整个叶片生长之间的功能联系。
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来源期刊
Current Plant Biology
Current Plant Biology Agricultural and Biological Sciences-Plant Science
CiteScore
10.90
自引率
1.90%
发文量
32
审稿时长
50 days
期刊介绍: Current Plant Biology aims to acknowledge and encourage interdisciplinary research in fundamental plant sciences with scope to address crop improvement, biodiversity, nutrition and human health. It publishes review articles, original research papers, method papers and short articles in plant research fields, such as systems biology, cell biology, genetics, epigenetics, mathematical modeling, signal transduction, plant-microbe interactions, synthetic biology, developmental biology, biochemistry, molecular biology, physiology, biotechnologies, bioinformatics and plant genomic resources.
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