bims-plasge Biomed News
on Plastid genes
Issue of 2024‒07‒14
three papers selected by
Vera S. Bogdanova, Institute of Cytology and Genetics, Siberian Branch of the Russian Academy of Sciences
  1. PPR proteins in plants: roles, mechanisms, and prospects for rice research.
  2. Pentatricopeptide repeat 153 (PPR153) restores maize C-type cytoplasmic male sterility in conjunction with RF4.
  3. Seed production determines the entrance to dormancy of the inflorescence meristem of Pisum sativum and the end of the flowering period.
  1. Front Plant Sci. 2024 ;15 1416742
    PPR proteins in plants: roles, mechanisms, and prospects for rice research.
    Lingzhi Meng, Mengxue Du, Taotao Zhu, Gang Li, Yi Ding, Qiang Zhang.
      Pentatricopeptide repeat (PPR) proteins constitute one of the largest protein families in land plants, with over 300 members in various species. Nearly all PPR proteins are nuclear-encoded and targeted to the chloroplast and mitochondria, modulating organellar gene expression by participating in RNA metabolism, including mRNA stability, RNA editing, RNA splicing, and translation initiation. Organelle RNA metabolism significantly influences chloroplast and mitochondria functions, impacting plant photosynthesis, respiration, and environmental responses. Over the past decades, PPR proteins have emerged as a research focus in molecular biology due to their diverse roles throughout plant life. This review summarizes recent progress in understanding the roles and molecular mechanisms of PPR proteins, emphasizing their functions in fertility, abiotic and biotic stress, grain quality, and chloroplast development in rice. Furthermore, we discuss prospects for PPR family research in rice, aiming to provide a theoretical foundation for future investigations and applications.
    Keywords:  PPR proteins; RNA metabolism; chloroplast; mitochondria; stress response
    DOI:  https://doi.org/10.3389/fpls.2024.1416742
  2. PLoS One. 2024 ;19(7): e0303436
    Pentatricopeptide repeat 153 (PPR153) restores maize C-type cytoplasmic male sterility in conjunction with RF4.
    Jennifer S Jaqueth, Bailin Li, Erik Vollbrecht.
      Maize (Zea mays L.) C-type cytoplasmic male sterility (CMS-C) is a highly used CMS system for maize commercial hybrid seed production. Rf4 is the major dominant restorer gene for CMS-C. Inbreds were recently discovered which contain the restoring Rf4 allele yet are unable to restore fertility due to the lack of an additional gene required for Rf4's restoration. To find this additional gene, QTL mapping and positional cloning were performed using an inbred that contained Rf4 but was incapable of restoring CMS-C. The QTL was mapped to a 738-kb interval on chromosome 2, which contains a Pentatricopeptide Repeat (PPR) gene cluster. Allele content comparisons of the inbreds identified three potential candidate genes responsible for fertility restoration in CMS-C. Complementation via transformation of these three candidate genes showed that PPR153 (Zm00001eb114660) is required for Rf4 to restore fertility to tassels. The PPR153 sequence is present in B73 genome, but it is not capable of restoring CMS-C without Rf4. Analysis using NAM lines revealed that Rf4 requires the presence of PPR153 to restore CMS-C in diverse germplasms. This research uncovers a major CMS-C genetic restoration pathway and can be used for identifying inbreds suitable for maize hybrid production with CMS-C cytoplasm.
    DOI:  https://doi.org/10.1371/journal.pone.0303436
  3. Physiol Plant. 2024 Jul-Aug;176(4):176(4): e14425
    Seed production determines the entrance to dormancy of the inflorescence meristem of Pisum sativum and the end of the flowering period.
    Eduardo Burillo, Raul Ortega, Jacqueline K Vander Schoor, Irene Martínez-Fernández, James L Weller, Aureliano Bombarely, Vicente Balanzà, Cristina Ferrándiz.
      Flowering plants adjust their reproductive period to maximize the success of the offspring. Monocarpic plants, those with a single reproductive cycle that precedes plant senescence and death, tightly regulate both flowering initiation and flowering cessation. The end of the flowering period involves the arrest of the inflorescence meristem activity, known as proliferative arrest, in what has been interpreted as an evolutionary adaptation to maximize the allocation of resources to seed production and the viability of the progeny. Factors influencing proliferative arrest were described for several monocarpic plant species many decades ago, but only in the last few years studies performed in Arabidopsis have allowed to approach proliferative arrest regulation in a comprehensive manner by studying the physiology, hormone dynamics, and genetic factors involved in its regulation. However, these studies remain restricted to Arabidopsis and there is a need to expand our knowledge to other monocarpic species to propose general mechanisms controlling the process. In this work, we have characterized proliferative arrest in Pisum sativum, trying to parallel available studies in Arabidopsis to maximize this comparative framework. We have assessed quantitatively the role of fruits/seeds in the process, the influence of the positional effect of these fruits/seeds in the behavior of the inflorescence meristem, and the transcriptomic changes in the inflorescence associated with the arrested state of the meristem. Our results support a high conservation of the factors triggering arrest in pea and Arabidopsis, but also reveal differences reinforcing the need to perform similar studies in other species.
    DOI:  https://doi.org/10.1111/ppl.14425
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