AP1/2β-mediated exocytosis of tapetum-specific transporters is required for pollen development in Arabidopsis thaliana

Adaptor protein-2 regulate root cell division and differentiation in Arabidopsis thaliana

In Arabidopsis, the root apical meristem consists of quiescent center (QC) and its surrounding stem cells, which form a stem cell niche (SCN) that develops into the root structure. The formation and maintenance of stem cells are regulated by hormones and transcription factors. Previous studies have shown that clathrin-mediated endocytosis impairs root growth; however, the underlying mechanisms remain unclear. Clathrin-mediated endocytosis is dependent on the function of clathrin, Adaptor Protein-2 (AP-2) and the TPLATE complex (TPC). In this study, our phenotypic analysis indicated that the reduced root length in the clathrin, AP-2, and TPC mutants resulted from a decreased number of meristem cells and a reduction in meristem size. Further modified pseudo-schiff propidium iodide (mPS-PI) staining revealed that clathrin heavy chain mutant, chc2-2, and ap2σ which is a subunit of AP-2 exhibited disordered columella stem cells (CSCs), decreased columella cells, abnormal cortex/endodermis initiation (CEI), and excessive division of the endodermis. Moreover, the transcription and protein levels of SHORTROOT (SHR) and SCARECROW (SCR) as well as PLETHORA1 (PLT1) and PLT2 were significantly decreased in ap-2 mutants. Yeast two-hybrid and bimolecular fluorescence complementation demonstrated that AP2σ interacted with SHR. In addition, disruption of AP-2 function reduced the auxin accumulation and the plasma membrane expression of its polar transporters PIN-FORMED1 (PIN1), PIN3 and PIN7. Taken together, this study revealed that AP-2 regulates both the SHR/SCR activity and the PINs-auxin transport to maintain the root division and differentiation in Arabidopsis thaliana.

The green ESCRTs: Newly defined roles for ESCRT proteins in plants

Endocytosis and endosomal trafficking of plasma membrane proteins for degradation regulate cellular homeostasis and development. As part of these processes, ubiquitinated plasma membrane proteins (cargo) are recognized, clustered, and sorted into intraluminal vesicles of multivesicular endosomes by endosomal sorting complexes required for transport (ESCRT) proteins. At endosomes, ESCRT proteins recognize ubiquitinated cargo and mediate the deformation of the endosomal membrane in a negative geometry, away from the cytosol. ESCRTs are organized in five major complexes that are sequentially recruited to the endosomal membrane where they mediate its vesiculation and cargo sequestration. ESCRTs also participate in other membrane remodeling events and are widely conserved across organisms, both eukaryotes and prokaryotes. Plants contain both conserved and unique ESCRT components and show a general trend toward gene family expansion. Plant endosomes show a wide range of membrane budding patterns with potential implications in cargo sequestration efficiency, plant development, and hormone signaling. Understanding the diversification and specialization of plant ESCRT proteins can provide valuable insights in the mechanisms of ESCRT-mediated membrane bending. In this review, we discuss the endosomal function of ESCRT proteins, their unique features in plants, and the potential connections to the modes of plant endosomal vesiculation.

Clathrin-mediated trafficking regulates copper tolerance by modulating the localization of HEAVY METAL ATPase 5 in Arabidopsis root cells

Plant clathrin and its adaptor protein complexes-adaptor protein complex-1 (AP-1) at the trans-Golgi network/early endosome (TGN/EE) and the adaptor protein complex-2 (AP-2) at the plasma membrane (PM)-function in clathrin-mediated trafficking (CMT). This study reports the role of CMT in regulating copper (Cu) tolerance in plants. We found that high concentrations of exogenous Cu treatment increase the abundance of clathrin and adaptor protein complexes at the TGN/EE and/or the PM. We further found that a CMT-deficient mutant ap2μ2, clc2 clc3 exhibits hypersensitivity to Cu stress, similar to a mutant lacking the Cu transporter HEAVY METAL ATPase 5 (HMA5). As previously reported, HMA5 relocates from the endoplasmic reticulum (ER) to the PM on the soil side, where it excretes excess Cu from the root cell, which is crucial for Cu tolerance. Our protein interaction assays showed that the AP-1 and AP-2 σ subunits depend on the YXXΦ sorting motif of HMA5 for recognition. Defective AP-1 hinders HMA5 translocation to the PM after its transfer from the ER to the TGN/EE following Cu stress, while impaired AP-2 function inhibits HMA5 endocytosis at the PM. These results demonstrate that CMT mediates the endocytic recycling of HMA5 between the TGN/EE and the PM, thereby regulating Cu efflux from root cells. Our findings highlight a function of CMT in maintaining Cu homeostasis.

The polar-localized borate exporter BOR1 facilitates boron transport in tapetal cells to the developing pollen grains

Boron is an essential micronutrient required for plant cell wall integrity, as it is necessary for crosslinking the pectic polysaccharide rhamnogalacturonan II. Reproductive organs require a greater amount of boron for development and growth compared with vegetative organs. However, the mechanism by which plants distribute boron to specific organs is not fully understood. Under boron-limited conditions, the borate exporter BOR1 plays a central role in transporting boron from the roots to the shoots in Arabidopsis (Arabidopsis thaliana). Here, we found that BOR1 is expressed in the tapetal cells of young anthers in unopened buds, showing polar localization toward the locule where microspores develop. Tapetum-localized BOR1 undergoes endocytosis and is subsequently degraded during anther development. BOR1 degradation occurs independently of the lysine residue at Position 590 of BOR1, which is responsible for high boron-induced ubiquitination and degradation. Loss-of-function bor1 mutants exhibit disrupted pollen structure, causing reduced fertility under boron-sufficient conditions in the wild type. These phenotypes were rescued by supplementing with high boron concentrations. Furthermore, inflorescence stem grafting experiments suggested that BOR1-dependent boron transport in the flower is necessary for pollen development and subsequent fertilization under boron-sufficient conditions. Our findings suggest the borate exporter BOR1, together with the previously described boric acid channel NIP7;1, facilitates boron transport in tapetal cells toward the locule, thereby supporting pollen development in young anthers under boron-limited conditions.

Identity Transitions of Tapetum Phases: Insights into Vesicular Dynamics and in Mortem Support During Pollen Maturation

Flower development progresses through twelve distinct stages, meticulously regulated to optimize plant reproductive success. At stage 5, the initiation of anther development occurs, which is further categorized into 14 stages divided into two defined phases: phase 1, known as microsporogenesis, and phase 2, termed microgametogenesis-encompassing pollen maturation and anther dehiscence. The maturation of pollen grains must be temporally synchronized with anther dehiscence, with auxin serving as a pivotal spatio-temporal link between these processes, coordinating various aspects of anther development, including stamen elongation, anther dehiscence, and tapetum development. The tapetum, a secretory tissue adjacent to the meiocytes, is essential for nurturing developing pollen grains by secreting components of the pollen wall and ultimately undergoing programmed cell death (PCD). This review primarily focuses on microgametogenesis, the identity and function of the tapetum during the different progression phases, the role of vesicular signaling in delivering external components crucial for pollen grain maturation, and the distinctive process of PCD associated with these developmental processes.

Genome-wide identification of the adaptor protein complexes and its expression patterns analysis in foxtail millet (Setaria italica L.)

BACKGROUNDS

Adapter proteins (APs) complex is a class of heterotetrameric complexes comprising of 4-subunits with important regulatory functions in eukaryotic cell membrane vesicle trafficking. Foxtail millet (Setaria italica L.) is a significant C4 model plant for monocotyledon studies, and vesicle trafficking may plays a crucial role in various life activities related to growth and development. Despite this importance, studies on AP complexes in foxtail millet have been lacking.

RESULTS

This research conducted genome-wide identification and systematical analysis of AP complexes in foxtail millet. 33 SiAP complex genes were identified and classified into 7 groups, distributed unevenly across 9 chromosomes in foxtail millet. Among these genes, 11 segmental duplication pairs were found. Out of the 33 SiAP complex genes, 24 exhibited collinear relationships with Setaria viridis, while only one showed relationship with Arabidopsis thaliana. Gene structure and motif composition were investigated to understand the function and evolution of these SiAP complex genes. Furthermore, these promoter region of the SiAP complex genes contains 49 cis-elements that are associated with responses to light, hormones, abiotic stress, growth and development. The interaction network between the SiAP complexes was analyzed, and there were strong interactions among the SiAP complex proteins. Expression patterns of SiAP complex genes in different organs and developmental stages of foxtail millet were investigated. The majority of the SiAP complex genes exhibited expressed in multiple tissues, with some genes being predominantly expressed in specific tissues. Subsequently, we selected SiAP4M and SiAP2M for validation of subcellular localization. The signal of 35 S:: SiAP4M: GFP (Long) and 35 S:: SiAP4M: GFP (Short) fused proteins were primarily observed in the nucleus, while the signal of 35 S:: SiAP2M: GFP fused proteins was widely distributed on the cell membrane and vesicles.

CONCLUSIONS

Overall, this study presents a comprehensive map of the SiAP complexes in foxtail millet. These findings not only administer to understanding the biological functions of AP complexes in foxtail millet growth and development but also offer insights for enhancing genetic breeding in this crop.

SlECA4, an epsin-like clathrin adaptor protein, improves tomato heat tolerance via clathrin-mediated endocytosis

Clathrin-mediated endocytosis (CME) is one of the main pathways for plant cells to internalize membrane proteins in response to changing environmental conditions. The Epsin-like Clathrin Adaptor (ECA) proteins play important roles in the assembly of the clathrin coat; however, their involvement in plant responses to heat stress remains unclear. Here we report that in tomato (Solanum lycopersicum), Epsin-like Clathrin Adaptor 4 (SlECA4) expression responded to heat stress. The silencing and knockout of SlECA4 increased tomato sensitivity to heat stress while the overexpression of SlECA4 enhanced tomato tolerance to heat stress. Treatment with a CME inhibitor, ES9-17, reduced tomato heat tolerance. SlECA4 localized to the plasma membrane, the trans-Golgi network/early endosomes, and the prevacuolar compartment/late endosomes. In a SlECA4 knockout line, both CME and recycling from the trans-Golgi network/early endosomes to the plasma membrane were inhibited. These data indicate that SlECA4 is involved in CME. After heat treatment, more punctate structures of SlECA4-green fluorescent protein accumulated in tobacco leaf epidermal cells by transient expression. Furthermore, compared with wild type, the rate of CME was inhibited under heat stress in the SlECA4 knockout line. Taken together, the ECA protein SlECA4 plays a positive role in tomato tolerance to heat stress via the CME pathway.

Endosomal membrane budding patterns in plants

Multivesicular endosomes (MVEs) sequester membrane proteins destined for degradation within intralumenal vesicles (ILVs), a process mediated by the membrane-remodeling action of Endosomal Sorting Complex Required for Transport (ESCRT) proteins. In Arabidopsis, endosomal membrane constriction and scission are uncoupled, resulting in the formation of extensive concatenated ILV networks and enhancing cargo sequestration efficiency. Here, we used a combination of electron tomography, computer simulations, and mathematical modeling to address the questions of when concatenated ILV networks evolved in plants and what drives their formation. Through morphometric analyses of tomographic reconstructions of endosomes across yeast, algae, and various land plants, we have found that ILV concatenation is widespread within plant species, but only prevalent in seed plants, especially in flowering plants. Multiple budding sites that require the formation of pores in the limiting membrane were only identified in hornworts and seed plants, suggesting that this mechanism has evolved independently in both plant lineages. To identify the conditions under which these multiple budding sites can arise, we used particle-based molecular dynamics simulations and found that changes in ESCRT filament properties, such as filament curvature and membrane binding energy, can generate the membrane shapes observed in multiple budding sites. To understand the relationship between membrane budding activity and ILV network topology, we performed computational simulations and identified a set of membrane remodeling parameters that can recapitulate our tomographic datasets.

Endocytic recycling in plants: pathways and regulation

Endocytic recycling is an intracellular trafficking pathway that returns endocytosed molecules to the plasma membrane via the recycling endosome. This pathway plays a crucial role in remodelling plasma membrane composition and is thus essential for cellular homeostasis. In plants, endocytic recycling regulates the localization and abundance of receptors, transporters, and channels at the plasma membrane that are involved in many aspects of plant growth and development. Despite its importance, the recycling endosome and the underlying sorting mechanisms for cargo recycling in plants remain understudied in comparison to the endocytic recycling pathways in animals. In this review, we focus on the cumulative evidence suggesting the existence of endosomes decorated by regulators that contribute to recycling in plant cells. We summarize the chemical inhibitors used for analysing cargo recycling and discuss recent advances in our understanding of how endocytic recycling participates in various plant cellular and physiological events.

Structural and Evolutionary Aspects of Plant Endocytosis

Endocytosis is an essential eukaryotic process that maintains the homeostasis of the plasma membrane proteome by vesicle-mediated internalization. Its predominant mode of operation utilizes the polymerization of the scaffold protein clathrin forming a coat around the vesicle; therefore, it is termed clathrin-mediated endocytosis (CME). Throughout evolution, the machinery that mediates CME is marked by losses, multiplications, and innovations. CME employs a limited number of conserved structural domains and folds, whose assembly and connections are species dependent. In plants, many of the domains are grouped into an ancient multimeric complex, the TPLATE complex, which occupies a central position as an interaction hub for the endocytic machinery. In this review, we provide an overview of the current knowledge regarding the structural aspects of plant CME, and we draw comparisons to other model systems. To do so, we have taken advantage of recent developments with respect to artificial intelligence-based protein structure prediction.

Genome-Wide Identification and Characterization of the RWP-RK Proteins in Zanthoxylum armatum

Apomixis is a common reproductive characteristic of Zanthoxylum plants, and RWP-RKs are plant-specific transcription factors known to regulate embryonic development. However, the genome-wide analysis and function prediction of RWP-RK family genes in Z. armatum are unclear. In this study, 36 ZaRWP-RK transcription factors were identified in the genome of Z. armatum, among which 15 genes belonged to the RKD subfamily and 21 belonged to the NLP subfamily. Duplication events of ZaRWP-RK genes were mainly segmental duplication, and synteny analysis revealed a close phylogenetic relationship between Z. armatum and Arabidopsis. The analysis of cis-elements indicated that ZaRWP-RK genes may be involved in the regulation of the embryonic development of Z. armatum by responding to plant hormones such as abscisic acid, auxin, and gibberellin. Results of a real-time PCR showed that the expression levels of most ZaRWP-RK genes were significantly increased from flowers to young fruits. Protein-protein interaction network analysis further revealed the potential roles of the ZaRWP-RK proteins in apomixis. Collectively, this study is expected to improve our understanding of ZaRWP-RK transcription factors and provide a theoretical basis for future investigations into the ZaRWP-RK genes and their regulatory mechanisms in the apomixis process of Z. armatum.

The emerging roles of clathrin-mediated endocytosis in plant development and stress responses

Clathrin-mediated endocytosis (CME) is a highly conserved pathway that plays a crucial role in the endocytosis of plasma membrane proteins in eukaryotic cells. The pathway is initiated when the adaptor protein complex 2 (AP2) and TPLATE complex (TPC) work together to recognize cargo proteins and recruit clathrin. This review provides a concise overview of the functions of each subunit of AP2 and TPC, and highlights the involvement of CME in various biological processes, such as pollen development, root development, nutrient transport, extracellular signal transduction, auxin polar transport, hyperosmotic stress, salinity stress, high ammonium stress, and disease resistance. Additionally, the review explores the regulation of CME by phytohormones, clathrin-mediated exocytosis (CMX), and AP2M phosphorylation. It also suggests potential future research directions for CME.

Arabidopsis HAPLESS13/AP-1µ is critical for pollen sac formation and tapetal function

The production of excess and viable pollen grains is critical for reproductive success of flowering plants. Pollen grains are produced within anthers, the male reproductive organ whose development involves precisely controlled cell differentiation, division, and intercellular communication. In Arabidopsis thaliana, specification of an archesporial cell (AC) at four corners of a developing anther, followed by programmed cell divisions, generates four pollen sacs, walled by four cell layers among which the tapetum is in close contact with developing microspores. Tapetum secretes callose-dissolving enzymes to release microspores at early stages and undergoes programmed cell death (PCD) to deliver nutrients and signals for microspore development at later stages. Except for transcription factors, plasma membrane (PM)-associated and secretory peptides have also been demonstrated to mediate anther development. Adaptor protein complexes (AP) recruit both cargos and coat proteins during vesicle trafficking. Arabidopsis AP-1µ/HAPLESS13 (HAP13) is a core component of AP-1 for protein sorting at the trans-Golgi network/early endosomes (TGN/EE). We report here that Arabidopsis HAP13 is critical for pollen sac formation and for sporophytic control of pollen production. Functional loss of HAP13 causes a reduction in pollen sac number. It also results in the dysfunction of tapetum such that secretory function of tapetum at early stages and PCD of tapetum at later stages are both compromised. We further show that the expression of SPL, the polar distribution of auxin maximum, as well as the asymmetric distribution of PIN1 are interfered in hap13 anthers, which in combination may lead to male sterility in hap13.

Potential candidate genes and pathways related to cytoplasmic male sterility in Dianthus spiculifolius as revealed by transcriptome analysis

KEY MESSAGE

We introduced the candidate gene DsHSP70 into Arabidopsis thaliana, resulting in male gametophyte sterility and abnormal degeneration of sepals and petals. Cytoplasmic male sterility (CMS) is a useful tool for hybrid production. However, the regulatory mechanism of CMS in Dianthus spiculifolius remains unclear. In this study, we investigated whether male-sterile line of D. spiculifolius has a malformed tapetum and fails to produce normal fertile pollen. RNA sequencing technology was used to compare the gene expression patterns of the D. spiculifolius male-sterile line and its male fertility maintainer line during anther development. A total of 12,365 differentially expressed genes (DEGs) were identified, among which 1765 were commonly expressed in the S1, S2 and S3 stages. Gene Ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG) analyses indicated that these DEGs were mainly involved in oxidation-reduction processes, signal transduction and programmed cell death. Additionally, weighted correlation network analysis (WGCNA) showed that three modules may be related to male sterility. A putative regulatory pathway for the male sterility traits was constructed based on the reproductive development network. After introducing the candidate DsHSP70 gene into Arabidopsis thaliana, we found that overexpressing plants showed anther abortion and shorter filaments, and accompanied by abnormal degeneration of sepals and petals. In summary, our results identified potential candidate genes and pathways related to CMS in D. spiculifolius, providing new insights for further research on the mechanism of male sterility.

Identifying pathogenicity-related genes in the pathogen Colletotrichum magnum causing watermelon anthracnose disease via T-DNA insertion mutagenesis

Fruit rot caused by Colletotrichum magnum is a crucial watermelon disease threatening the production and quality. To understand the pathogenic mechanism of C. magnum, we optimized the Agrobacterium tumefaciens-mediated transformation system (ATMT) for genetic transformation of C. magnum. The transformation efficiency of ATMT was an average of around 245 transformants per 100 million conidia. Southern blot analysis indicated that approximately 75% of the mutants contained a single copy of T-DNA. Pathogenicity test revealed that three mutants completely lost pathogenicity. The T-DNA integration sites (TISs) of three mutants were Identified. In mutant Cm699, the TISs were found in the intron region of the gene, which encoded a protein containing AP-2 complex subunit σ, and simultaneous gene deletions were observed. Two deleted genes encoded the transcription initiation protein SPT3 and a hypothetical protein, respectively. In mutant Cm854, the TISs were found in the 5'-flanking regions of a gene that was similar to the MYO5 encoding Myosin I of Pyricularia oryzae (78%). In mutant Cm1078, the T-DNA was integrated into the exon regions of two adjacent genes. One was 5'-3' exoribonuclease 1 encoding gene while the other encoded a WD-repeat protein retinoblastoma binding protein 4, the homolog of the MSl1 of Saccharomyces cerevisiae.

FgAP1σ Is Critical for Vegetative Growth, Conidiation, Virulence, and DON Biosynthesis in Fusarium graminearum

The AP1 complex is a highly conserved clathrin adaptor that plays important roles in regulating cargo protein sorting and intracellular vesicle trafficking in eukaryotes. However, the functions of the AP1 complex in the plant pathogenic fungi including the devastating wheat pathogen Fusarium graminearum are still unclear. In this study, we investigated the biological functions of FgAP1^σ, a subunit of the AP1 complex in F. graminearum. Disruption of FgAP1^σ causes seriously impaired fungal vegetative growth, conidiogenesis, sexual development, pathogenesis, and deoxynivalenol (DON) production. The ΔFgap1^σ mutants were found to be less sensitive to KCl- and sorbitol-induced osmotic stresses but more sensitive to SDS-induced stress than the wild-type PH-1. Although the growth inhibition rate of the ΔFgap1^σ mutants was not significantly changed under calcofluor white (CFW) and Congo red (CR) stresses, the protoplasts released from ΔFgap1^σ hyphae were decreased compared with the wild-type PH-1, suggesting that FgAP1^σ is necessary for cell wall integrity and osmotic stresses in F. graminearum. Subcellular localization assays showed that FgAP1^σ was predominantly localized to endosomes and the Golgi apparatus. In addition, FgAP1^β-GFP, FgAP1^γ-GFP, and FgAP1^μ-GFP also localize to the Golgi apparatus. FgAP1^β interacts with FgAP1^σ, FgAP1^γ, and FgAP1^μ, while FgAP1^σ regulates the expression of FgAP1^β, FgAP1^γ, and FgAP1^μ in F. graminearum. Furthermore, the loss of FgAP1^σ blocks the transportation of the v-SNARE protein FgSnc1 from the Golgi to the plasma membrane and delays the internalization of FM4-64 dye into the vacuole. Taken together, our results demonstrate that FgAP1^σ plays vital roles in vegetative growth, conidiogenesis, sexual reproduction, DON production, pathogenicity, cell wall integrity, osmotic stress, exocytosis, and endocytosis in F. graminearum. These findings unveil the functions of the AP1 complex in filamentous fungi, most notably in F. graminearum, and lay solid foundations for effective prevention and control of Fusarium head blight (FHB).

Comprehensive Insight into Tapetum-Mediated Pollen Development in Arabidopsis thaliana

In flowering plants, pollen development is a key process that is essential for sexual reproduction and seed set. Molecular and genetic studies indicate that pollen development is coordinatedly regulated by both gametophytic and sporophytic factors. Tapetum, the somatic cell layer adjacent to the developing male meiocytes, plays an essential role during pollen development. In the early anther development stage, the tapetal cells secrete nutrients, proteins, lipids, and enzymes for microsporocytes and microspore development, while initiating programmed cell death to provide critical materials for pollen wall formation in the late stage. Therefore, disrupting tapetum specification, development, or function usually leads to serious defects in pollen development. In this review, we aim to summarize the current understanding of tapetum-mediated pollen development and illuminate the underlying molecular mechanism in Arabidopsis thaliana.

ATP-Binding Cassette G Transporters and Their Multiple Roles Especially for Male Fertility in Arabidopsis, Rice and Maize

ATP-binding cassette subfamily G (ABCG) transporters are extensive in plants and play essential roles in various processes influencing plant fitness, but the research progress varies greatly among Arabidopsis, rice and maize. In this review, we present a consolidated nomenclature and characterization of the whole 51 ABCG transporters in maize, perform a phylogenetic analysis and classification of the ABCG subfamily members in maize, and summarize the latest research advances in ABCG transporters for these three plant species. ABCG transporters are involved in diverse processes in Arabidopsis and rice, such as anther and pollen development, vegetative and female organ development, abiotic and biotic stress response, and phytohormone transport, which provide useful clues for the functional investigation of ABCG transporters in maize. Finally, we discuss the current challenges and future perspectives for the identification and mechanism analysis of substrates for plant ABCG transporters. This review provides a basic framework for functional research and the potential application of ABCG transporters in multiple plants, including maize.