Filamentous Temperature-Sensitive Z Protein J175 Regulates Maize Chloroplasts’ and Amyloplasts’ Division and Development

Filamentous Temperature-Sensitive Z Protein J175 Regulates Maize Chloroplasts’ and Amyloplasts’ Division and Development

Plastid division regulatory genes play a crucial role in the morphogenesis of chloroplasts and amyloplasts. Chloroplasts are the main sites for photosynthesis and metabolic reactions, while amyloplasts are the organelles responsible for forming and storing starch granules. The proper division of chl...

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Main Authors: Huayang Lv, Xuewu He, Hongyu Zhang, Dianyuan Cai, Zeting Mou, Xuerui He, Yangping Li, Hanmei Liu, Yinghong Liu, Yufeng Hu, Zhiming Zhang, Yubi Huang, Junjie Zhang
Format: Article
Language:English
Published: MDPI AG 2025-07-01
Series:Plants
Subjects:
maize
chloroplast
amyloplast
FtsZ
Online Access:https://www.mdpi.com/2223-7747/14/14/2198
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Summary:Plastid division regulatory genes play a crucial role in the morphogenesis of chloroplasts and amyloplasts. Chloroplasts are the main sites for photosynthesis and metabolic reactions, while amyloplasts are the organelles responsible for forming and storing starch granules. The proper division of chloroplasts and amyloplasts is essential for plant growth and yield maintenance. Therefore, this study aimed to examine the <i>J175</i> (<i>FtsZ2-2</i>) gene, cloned from an ethyl methanesulphonate (EMS) mutant involved in chloroplast and amyloplast division in maize, through map-based cloning. We found that <i>J175</i> encodes a cell division protein, FtsZ (filamentous temperature-sensitive Z). The FtsZ family of proteins is widely distributed in plants and may be related to the division of chloroplasts and amyloplasts. The J175 protein is localized in plastids, and its gene is expressed across various tissues. From the seedling stage, the leaves of the <i>j175</i> mutant exhibited white stripes, while the division of chloroplasts was inhibited, leading to a significant increase in volume and a reduction in their number. Measurement of the photosynthetic rate showed a significant decrease in the photosynthetic efficiency of <i>j175</i>. Additionally, the division of amyloplasts in <i>j175</i> grains at different stages was impeded, resulting in irregular polygonal starch granules. RNA-seq analyses of leaves and kernels also showed that multiple genes affecting plastid division, such as <i>FtsZ1</i>, <i>ARC3</i>, <i>ARC6</i>, <i>PDV1-1</i>, <i>PDV2</i>, and <i>MinE1</i>, were significantly downregulated. This study demonstrates that the maize gene <i>j175</i> is essential for maintaining the division of chloroplasts and amyloplasts and ensuring normal plant growth, and provides an important gene resource for the molecular breeding of maize.
ISSN:2223-7747

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