Your search keyword '"Lin, Zongcheng"' showing total 7 results

1. Peptides: Opening the door.

Author

Lin, Zongcheng, Jin, Ke, and Franklin-Tong, Noni

Published

2024

2. Depletion plays a pivotal role in self‐incompatibility, revealing a link between cellular energy status, cytosolic acidification and actin remodelling in pollen tubes.

Author

Wang, Ludi, Lin, Zongcheng, Carli, José, Gladala‐Kostarz, Agnieszka, Davies, Julia M., Franklin‐Tong, Vernonica E., and Bosch, Maurice

Subjects

*POLLEN tube, *ACTIN, *CYTOSKELETON, *POLLINATION, *ACIDIFICATION, *APOPTOSIS, *F-actin

Abstract

Summary: Self‐incompatibility (SI) involves specific interactions during pollination to reject incompatible ('self') pollen, preventing inbreeding in angiosperms. A key event observed in pollen undergoing the Papaver rhoeas SI response is the formation of punctate F‐actin foci.Pollen tube growth is heavily energy‐dependent, yet ATP levels in pollen tubes have not been directly measured during SI. Here we used transgenic Arabidopsis lines expressing the Papaver pollen S‐determinant to investigate a possible link between ATP levels, cytosolic pH ([pH]cyt) and alterations to the actin cytoskeleton.We identify for the first time that SI triggers a rapid and significant ATP depletion in pollen tubes. Artificial depletion of ATP triggered cytosolic acidification and formation of actin aggregates. We also identify in vivo, evidence for a threshold [pH]cyt of 5.8 for actin foci formation. Imaging revealed that SI stimulates acidic cytosolic patches adjacent to the plasma membrane.In conclusion, this study provides evidence that ATP depletion plays a pivotal role in SI upstream of programmed cell death and reveals a link between the cellular energy status, cytosolic acidification and alterations to the actin cytoskeleton in regulating Papaver SI in pollen tubes. See also the Commentary on this article by Cheung, 236: 1625–1628. [ABSTRACT FROM AUTHOR]

Published

2022

3. Self-incompatibility requires GPI anchor remodeling by the poppy PGAP1 ortholog HLD1.

Author

Lin, Zongcheng, Xie, Fei, Triviño, Marina, Zhao, Tao, Coppens, Frederik, Sterck, Lieven, Bosch, Maurice, Franklin-Tong, Vernonica E., and Nowack, Moritz K.

Subjects

*GLYCOSYLPHOSPHATIDYLINOSITOL, *PLANT fertilization, *DEACYLATION, *CELL membranes, *PAPAVERACEAE

Abstract

Glycosylphosphatidylinositol-anchored proteins (GPI-APs) are tethered to the outer leaflet of the plasma membrane where they function as key regulators of a plethora of biological processes in eukaryotes. Self-incompatibility (SI) plays a pivotal role regulating fertilization in higher plants through recognition and rejection of "self" pollen. Here, we used Arabidopsis thaliana lines that were engineered to be self-incompatible by expression of Papaver rhoeas SI determinants for an SI suppressor screen. We identify HLD1 / AtPGAP1 , an ortholog of the human GPI-inositol deacylase PGAP1 , as a critical component required for the SI response. Besides a delay in flowering time, no developmental defects were observed in HLD1 / AtPGAP1 knockout plants, but SI was completely abolished. We demonstrate that HLD1/AtPGAP1 functions as a GPI-inositol deacylase and that this GPI-remodeling activity is essential for SI. Using GFP-SKU5 as a representative GPI-AP, we show that the HLD1 / AtPGAP1 mutation does not affect GPI-AP production and targeting but affects their cleavage and release from membranes in vivo. Our data not only implicate GPI-APs in SI, providing new directions to investigate SI mechanisms, but also identify a key functional role for GPI-AP remodeling by inositol deacylation in planta. [Display omitted] • Mutation of the PGAP1 ortholog HLD1 abolishes the Papaver SI response • Lack of HLD1/AtPGAP1 does not affect fertility or overall development • Deacylation of GPI-anchored protein(s) is required for the Papaver SI response • HLD1/AtPGAP1 likely regulates SI by affecting PLC-mediated release of GPI-APs Lin et al. identify a requirement for the GPI-inositol deacylase HLD1/AtPGAP1, an ortholog of mammalian PGAP1, in Papaver self-incompatibility. They demonstrate that the remodeling of GPI-anchored proteins by inositol deacylation is crucial for self-pollen rejection, implicating a role for GPI-APs and their cleavage/release from the plasma membrane. [ABSTRACT FROM AUTHOR]

Published

2022

4. Transposable elements cause the loss of self‐incompatibility in citrus.

Author

Hu, Jianbing, Liu, Chenchen, Du, Zezhen, Guo, Furong, Song, Dan, Wang, Nan, Wei, Zhuangmin, Jiang, Jingdong, Cao, Zonghong, Shi, Chunmei, Zhang, Siqi, Zhu, Chenqiao, Chen, Peng, Larkin, Robert M., Lin, Zongcheng, Xu, Qiang, Ye, Junli, Deng, Xiuxin, Bosch, Maurice, and Franklin‐Tong, Vernonica E.

Subjects

*GENETIC variation, *PROMOTERS (Genetics), *PLANT genes, *CITRUS, *ANGIOSPERMS, *MITES

Abstract

Summary: Self‐incompatibility (SI) is a widespread prezygotic mechanism for flowering plants to avoid inbreeding depression and promote genetic diversity. Citrus has an S‐RNase‐based SI system, which was frequently lost during evolution. We previously identified a single nucleotide mutation in Sm‐RNase, which is responsible for the loss of SI in mandarin and its hybrids. However, little is known about other mechanisms responsible for conversion of SI to self‐compatibility (SC) and we identify a completely different mechanism widely utilized by citrus. Here, we found a 786‐bp miniature inverted‐repeat transposable element (MITE) insertion in the promoter region of the FhiS2‐RNase in Fortunella hindsii Swingle (a model plant for citrus gene function), which does not contain the Sm‐RNase allele but are still SC. We demonstrate that this MITE plays a pivotal role in the loss of SI in citrus, providing evidence that this MITE insertion prevents expression of the S‐RNase; moreover, transgenic experiments show that deletion of this 786‐bp MITE insertion recovers the expression of FhiS2‐RNase and restores SI. This study identifies the first evidence for a role for MITEs at the S‐locus affecting the SI phenotype. A family‐wide survey of the S‐locus revealed that MITE insertions occur frequently adjacent to S‐RNase alleles in different citrus genera, but only certain MITEs appear to be responsible for the loss of SI. Our study provides evidence that insertion of MITEs into a promoter region can alter a breeding strategy and suggests that this phenomenon may be broadly responsible for SC in species with the S‐RNase system. [ABSTRACT FROM AUTHOR]

Published

2024

5. A developmentally controlled cellular decompartmentalization process executes programmed cell death in the Arabidopsis root cap.

Author

Wang, Jie, Bollier, Norbert, Buono, Rafael Andrade, Vahldick, Hannah, Lin, Zongcheng, Feng, Qiangnan, Hudecek, Roman, Jiang, Qihang, Mylle, Evelien, Van Damme, Daniel, and Nowack, Moritz K

Subjects

*APOPTOSIS, *COTYLEDONS, *ARABIDOPSIS, *INTRACELLULAR calcium, *EXTRACELLULAR matrix proteins, *ANIMAL mortality

Abstract

Programmed cell death (PCD) is a fundamental cellular process crucial to development, homeostasis, and immunity in multicellular eukaryotes. In contrast to our knowledge on the regulation of diverse animal cell death subroutines, information on execution of PCD in plants remains fragmentary. Here, we make use of the accessibility of the Arabidopsis (Arabidopsis thaliana) root cap to visualize the execution process of developmentally controlled PCD. We identify a succession of selective decompartmentalization events and ion fluxes as part of the terminal differentiation program that is orchestrated by the NO APICAL MERISTEM, ARABIDOPSIS THALIANA ACTIVATING FACTOR, CUP-SHAPED COTYLEDON (NAC) transcription factor SOMBRERO. Surprisingly, the breakdown of the large central vacuole is a relatively late and variable event, preceded by an increase of intracellular calcium levels and acidification, release of mitochondrial matrix proteins, leakage of nuclear and endoplasmic reticulum lumina, and release of fluorescent membrane reporters into the cytosol. In analogy to animal apoptosis, the plasma membrane remains impermeable for proteins during and after PCD execution. Elevated intracellular calcium levels and acidification are sufficient to trigger cell death execution specifically in terminally differentiated root cap cells, suggesting that these ion fluxes act as PCD-triggering signals. This detailed information on the cellular processes occurring during developmental PCD in plants is a pivotal prerequisite for future research into the molecular mechanisms of cell death execution. Live-cell imaging of the Arabidopsis root cap reveals a series of developmentally controlled cellular decompartmentalization events occurring during the execution of programmed cell death. [ABSTRACT FROM AUTHOR]

Published

2024

6. New opportunities and insights into Papaver self-incompatibility by imaging engineered Arabidopsis pollen.

Author

Wang, Ludi, Triviño, Marina, Lin, Zongcheng, Carli, José, Eaves, Deborah J, Damme, Daniёl Van, Nowack, Moritz K, Franklin-Tong, Vernonica E, and Bosch, Maurice

Abstract

Pollen tube growth is essential for plant reproduction. Their rapid extension using polarized tip growth provides an exciting system for studying this specialized type of growth. Self-incompatibility (SI) is a genetically controlled mechanism to prevent self-fertilization. Mechanistically, one of the best-studied SI systems is that of Papaver rhoeas (poppy). This utilizes two S -determinants: stigma-expressed PrsS and pollen-expressed PrpS. Interaction of cognate PrpS–PrsS triggers a signalling network, causing rapid growth arrest and programmed cell death (PCD) in incompatible pollen. We previously demonstrated that transgenic Arabidopsis thaliana pollen expressing PrpS–green fluorescent protein (GFP) can respond to Papaver PrsS with remarkably similar responses to those observed in incompatible Papaver pollen. Here we describe recent advances using these transgenic plants combined with genetically encoded fluorescent probes to monitor SI-induced cellular alterations, including cytosolic calcium, pH, the actin cytoskeleton, clathrin-mediated endocytosis (CME), and the vacuole. This approach has allowed us to study the SI response in depth, using multiparameter live-cell imaging approaches that were not possible in Papaver. This lays the foundations for new opportunities to elucidate key mechanisms involved in SI. Here we establish that CME is disrupted in self-incompatible pollen. Moreover, we reveal new detailed information about F-actin remodelling in pollen tubes after SI. [ABSTRACT FROM AUTHOR]

Published

2020

7. Killing me softly - Programmed cell death in plant reproduction from sporogenesis to fertilization.

Author

Xie, Fei, Vahldick, Hannah, Lin, Zongcheng, and Nowack, Moritz K.

Subjects

*APOPTOSIS, *PLANT reproduction, *SEX determination, *PLANT development, *ABIOTIC stress, *POLLINATION

Abstract

Regulated or programmed cell death (RCD or PCD) is a fundamental biological principle integral to a considerable variety of functions in multicellular organisms. In plants, different PCD processes are part of biotic and abiotic stress responses, but also occur as an essential aspect of unperturbed plant development. PCD is particularly abundant during plant reproduction, eliminating unwanted or no longer needed cells, tissues, or organs in a precisely controlled manner. Failure in reproductive PCD can have detrimental consequences for plant reproduction. Here we shed a light on the latest research into PCD mechanisms in plant reproduction from sex determination over sporogenesis to pollination and fertilization. [ABSTRACT FROM AUTHOR]

Published

2022