The C-terminal domain of SEC-10 is fundamental for exocyst function, Spitzenkorper organization and cell morphogenesis in Neurospora crassa.

The exocyst is a conserved multimeric complex that participates in the final steps of the secretion of vesicles. In the filamentous fungus Neurospora crassa, the exocyst is crucial for polar growth, morphology, and the organization of the Spitzenkorper (Spk), the apical body where secretory vesicles accumulate before being delivered to the plasma membrane. In the highly polarized cells of N. crassa, the exocyst subunits SEC-3, SEC-5, SEC-6, SEC-8, and SEC-15 were previously found localized at the plasma membrane of the apices of the cells, while EXO-70 and EXO-84 occupied the frontal outer layer of the Spk, occupied by vesicles. The localization of SEC-10 had remained so far elusive. In this work, SEC-10 was tagged with the green fluorescent protein (GFP) either at its N- or C-terminus and found localized at the plasma membrane of growing hyphal tips, similar to what was previously observed for some exocyst subunits. While expression of an N-terminally tagged version of SEC-10 at its native locus was fully viable, expression of a C-terminally tagged version at its native locus resulted in severe hyphal growth and polarity defects. Additionally, a sec-10 knockout mutant in a heterokaryotic state (with genetically different nuclei) was viable but showed a strongly aberrant phenotype, confirming that this subunit is essential to maintain hyphal morphogenesis. Transmission electron microscopy analysis revealed the lack of a Spk in the SEC-10-GFP strain, suggesting a critical role of the exocyst in the vesicular organization at the Spk. Mass spectrometry analysis revealed fewer peptides of exocyst subunits interacting with SEC-10-GFP than with GFP-SEC-10, suggesting an essential role of the C-terminus of SEC-10 in exocyst assembly and/or stability. Altogether, our data suggest that an unobstructed C-terminus of SEC-10 is indispensable for the exocyst complex function and that a GFP tag could be blocking important subunit-subunit interactions.

Tobacco HY5, NtHY5, positively regulates flavonoid biosynthesis and enhances salt stress tolerance

Plants have evolved complex signaling networks to regulate their growth and development. Some of these signaling components also play a crucial role in secondary metabolite biosynthesis. Among the signaling components identified to date, ELONGATED HYPOCOTYL 5 (HY5), a bZIP family transcription factor is the most investigated and known as the center of transcriptional network hub. However, HY5 has not been characterized from plants known to synthesize important secondary metabolites. In this study, based on homology search and phylogenetic analysis, HY5 has been identified from Nicotiana tobaccum, and characterized for its role in secondary plant product biosynthesis and stress response through developing overexpressing lines and CRISPR/Cas9-based knockout mutant plants. NtHY5 was able to complement the Arabidopsis thaliana hy5 mutant at molecular, morphological and biochemical levels. Overexpression of NtHY5 in tobacco led to the up-regulation of the phenylpropanoid pathway genes and enhanced the flavonoid content, whereas mutant plants had the opposite effect. Electrophoretic Mobility Shift Assay (EMSA) suggested that NtHY5 interacts with the promoter of NtMYB12, a transcription factor known to regulate flavonoid biosynthesis. In addition, NtHY5 enhanced the abiotic stress tolerance as evident by the salt tolerance ability of HY5 overexpressing lines by diminishing the ROS accumulation after salt treatment. These data provide credible evidence about the potential role of NtHY5 in light-mediated flavonoid biosynthesis, plant growth and abiotic stress tolerance in tobacco. The photomorphogenic mutant, Nthy5, developed in this study, will help in elucidating the role of the HY5 in different biological processes in tobacco.

CRISPR/Cas9-Mediated Gene Editing of Vacuolar ATPase Subunit D Mediates Phytohormone Biosynthesis and Virus Resistance in Rice

Background: Vacuolar ATPases (v-ATPases) are proton pumps for proton translocation across membranes that utilize energy derived from ATP hydrolysis; Previous research revealed Osv-ATPases mediates phytohormes levels and resistance in rice. Osv-ATPase subunit d (Osv-ATPase d) is part of an integral, membrane-embedded V0 complex of V-ATPases complex, whether Osv-ATPase d involves in phytohormes biosynthesis and resistance in rice remains unknown.Finding: The knockout mutant line (line 5) of Osv-ATPase d was generated using the CRISPR/Cas9 system, mutation of Osv-ATPase d did not show any detrimental effect on plant growth or yield productivity. Transcriptomic results showed Osv-ATPase d probably involved in mediating the biosynthesis of plant hormones and resistance in rice. Mutation of Osv-ATPase d significantly increased JA and ABA biosynthesis than wild type. Compared to wild type, mutation of Osv-ATPase d increased the resistance against Southern rice black-streaked dwarf virus (SRBSDV), however, decreased the resistance against Rice stripe virus (RSV) in rice. Conclusion: Taken together, our data reveal the Osv-ATPase d mediates phytohormone biosynthesis and virus resistance in rice, which can be selected as a potential target for resistance breeding in rice.

AtSYP71 Is Important for Plant Cell Wall Biosynthesis and Stress Adaptation.

Background: SYP71, the plant-specific Qc-SNARE protein, is reported to regulate vesicle trafficking. SYP71 is localized on the ER, endosome, plasma membrane and cell plate, suggesting its multiple functions. Lotus SYP71 is essential for symbiotic nitrogen fixation in nodules. AtSYP71, GmSYP71 and OsSYP71 are implicated in plant resistance to pathogenesis. To date, SYP71 regulatory role on plant development remain unclear.Results: AtSYP71-knockout mutant atsyp71-4 was lethal at early development stage. Early development of AtSYP71-knockdown mutant atsyp71-2 was delayed, and stress response was also affected. Confocal images revealed that protein secretion was blocked in atsyp71-2. Transcriptomic analysis indicated that metabolism, response to environmental stimuli pathways and apoplast components were influenced in atsyp71-2. Moreover, the contents of lignin, cellulose and flavonoids as well as cell wall structures were also altered.Conclusion: Our findings suggested that AtSYP71 is essential for plant development. AtSYP71 probably regulates plant development, metabolism and environmental adaptation by affecting cell wall homeostasis via mediating secretion of materials and regulators required for cell wall biosynthesis and dynamics.

Cortactin Promotes Effective AGS Cell Scattering by Helicobacter pylori CagA, but Not Cellular Vacuolization and Apoptosis Induced by the Vacuolating Cytotoxin VacA

Cortactin is an actin-binding protein and actin-nucleation promoting factor regulating cytoskeletal rearrangements in eukaryotes. Helicobacter pylori is a gastric pathogen that exploits cortactin to its own benefit. During infection of gastric epithelial cells, H. pylori hijacks multiple cellular signaling pathways, leading to the disruption of key cell functions. Two bacterial virulence factors play important roles in this scenario, the vacuolating cytotoxin VacA and the translocated effector protein CagA of the cag type IV secretion system (T4SS). Specifically, by overruling the phosphorylation status of cortactin, H. pylori alternates the activity of molecular interaction partners of this important protein, thereby manipulating the performance of cytoskeletal rearrangements, endosomal trafficking and cell movement. Based on shRNA knockdown and other studies, it was previously reported that VacA utilizes cortactin for its cellular uptake, intracellular travel and induction of apoptosis by a mitochondria-dependent mechanism, while CagA induces cell scattering, motility and elongation. To investigate the role of cortactin in these phenotypes in more detail, we produced a complete knockout mutant of cortactin in the gastric adenocarcinoma cell line AGS by CRISPR-Cas9. These cells were infected with H. pylori wild-type or various isogenic mutant strains. Unexpectedly, cortactin deficiency did not prevent the uptake and formation of VacA-dependent vacuoles, nor the induction of apoptosis by internalized VacA, while the induction of T4SS- and CagA-dependent AGS cell movement and elongation were strongly reduced. Thus, we provide evidence that cortactin is required for the function of internalized CagA, but not VacA.

Engineering selectivity of Cutibacterium acnes phages by epigenetic imprinting

Cutibacterium acnes (C. acnes) is a gram-positive bacterium and a member of the human skin microbiome. Despite being the most abundant skin commensal, certain members have been associated with common inflammatory disorders such as acne vulgaris. The availability of the complete genome sequences from various C. acnes clades have enabled the identification of putative methyltransferases, some of them potentially belonging to restriction-modification (R-M) systems which protect the host of invading DNA. However, little is known on whether these systems are functional in the different C. acnes strains. To investigate the activity of these putative R-M and their relevance in host protective mechanisms, we analyzed the methylome of seven representative C. acnes strains by Oxford Nanopore Technologies (ONT) sequencing. We detected the presence of a 6-methyladenine modification at a defined DNA consensus sequence in strain KPA171202 and recombinant expression of this R-M system confirmed its methylation activity. Additionally, a R-M knockout mutant verified the loss of methylation properties of the strain. We studied the potential of one C. acnes bacteriophage (PAD20) in killing various C. acnes strains and linked an increase in its specificity to phage DNA methylation acquired upon infection of a methylation competent strain. We demonstrate a therapeutic application of this mechanism where phages propagated in R-M deficient strains selectively kill R-M deficient acne-prone clades while probiotic ones remain resistant to phage infection.

Iron supplementation delays aging and extends cellular lifespan through potentiation of mitochondrial function

Aging is the greatest challenge of humankind worldwide. Aging is associated with a progressive loss of physiological integrity due to a decline in cellular metabolism and functions. Such metabolic changes lead to age-related diseases, thereby compromising human health for the remaining life. Thus, there is an urgent need to identify geroprotectors that regulate metabolic functions to target the aging biological processes. Nutrients are the major regulator of metabolic activities to coordinate cell growth and development. Iron is an important nutrient involved in several biological functions, including metabolism. In this study, using yeast as an aging model organism, we show that iron supplementation delays aging and increases the cellular lifespan. To determine how iron supplementation increases the lifespan, we performed the gene expression analysis of mitochondria, the main cellular hub of iron utilization. Quantitative analysis of gene expression data reveals that iron supplementation upregulates the expression of mitochondrial tricarboxylic acid (TCA) cycle and electron transport chain (ETC) genes. Furthermore, in agreement with expression profiles of mitochondrial genes, ATP level is elevated by iron supplementation, which is required for increasing the cellular lifespan. To confirm, we tested the role of iron supplementation in the AMPK knockout mutant. AMPK is a highly conserved controller of mitochondrial metabolism and energy homeostasis. Remarkably, iron supplementation rescued the short lifespan of AMPK knockout mutant confirmed the anti-aging role through enhancement of mitochondrial functions. Thus our results suggest a potential therapeutic use of iron supplementation to delay aging and prolong healthspan.

Comparative Proteomic Analysis for a Putative Pyridoxal Phosphate-Dependent Aminotransferase Required for Virulence in Acidovorax citrulli

Acidovorax citrulli (Ac) is the causative agent of bacterial fruit blotch disease in watermelon. Since resistant cultivars have not yet been developed, the virulence factors/mechanisms of Ac need to be characterized. This study reports the functions of a putative pyridoxal phosphate-dependent aminotransferase (PpdaAc) that transfers amino groups to its substrates and uses pyridoxal phosphate as a coenzyme. It was observed that a ppdaAc knockout mutant had a significantly reduced virulence in watermelon when introduced via germinated-seed inoculation as well as leaf infiltration. Comparative proteomic analysis predicted the cellular mechanisms related to PpdaAc. Apart from causing virulence, the PpdaAc may have significant roles in energy production, cell membrane, motility, chemotaxis, post-translational modifications, and iron-related mechanisms. Therefore, it is postulated that PpdaAc may possess pleiotropic effects. These results provide new insights into the functions of a previously unidentified PpdaAc in Ac.

Rice Carbohydrate-Binding Malectin-Like Protein, OsCBM1, Contributes to Drought-Stress Tolerance by Participating in NADPH Oxidase-Mediated ROS Production

Carbohydrate-binding malectin/malectin-like domain-containing proteins (CBMs) are a recently identified protein subfamily of lectins that participates various functional bioprocesses in the animal, bacterial, and plant kingdoms. However, little is known the roles of CBMs in rice development and stress response. In this study, OsCBM1, which encodes a protein containing only one malectin-like domain, was cloned and characterized. OsCBM1 is localized in both the endoplasmic reticulum and plasma membrane. Its transcripts are dominantly expressed in leaves and could be significantly stimulated by a number of phytohormone applications and abiotic stress treatments. Overexpression of OsCBM1 increased drought tolerance and reactive oxygen species production in rice, whereas the knockdown of the gene decreased them. OsCBM1 physically interacts with OsRbohA, a NADPH oxidase, and the expression of OsCBM1 in osrbohA, an OsRbohA-knockout mutant, is significantly downregulated under both normal growth and drought stress conditions. Meanwhile, OsCBM1 can also physically interacts with OsRacGEF1, a specific guanine nucleotide exchange factor for the Rop/Rac GTPase OsRac1, and transient coexpression of OsCBM1 with OaRacGEF1 significantly enhanced ROS production. Further transcriptome analysis showed that multiple signaling regulatory mechanisms are involved in the OsCBM1-mediated processes. All these results suggest that OsCBM1 participates in NADPH oxidase-mediated ROS production by interacting with OsRbohA and OsRacGEF1, contributing to drought stress tolerance of rice. Multiple signaling pathways are likely involved in the OsCBM1-mediated stress tolerance in rice.

Phospholipase Dα1 Acts as a Negative Regulator of High Mg2+-Induced Leaf Senescence in Arabidopsis

Magnesium (Mg2+) is a macronutrient involved in essential cellular processes. Its deficiency or excess is a stress factor for plants, seriously affecting their growth and development and therefore, its accurate regulation is essential. Recently, we discovered that phospholipase Dα1 (PLDα1) activity is vital in the stress response to high-magnesium conditions in Arabidopsis roots. This study shows that PLDα1 acts as a negative regulator of high-Mg2+-induced leaf senescence in Arabidopsis. The level of phosphatidic acid produced by PLDα1 and the amount of PLDα1 in the leaves increase in plants treated with high Mg2+. A knockout mutant of PLDα1 (pldα1-1), exhibits premature leaf senescence under high-Mg2+ conditions. In pldα1-1 plants, higher accumulation of abscisic and jasmonic acid (JA) and impaired magnesium, potassium and phosphate homeostasis were observed under high-Mg2+ conditions. High Mg2+ also led to an increase of starch and proline content in Arabidopsis plants. While the starch content was higher in pldα1-1 plants, proline content was significantly lower in pldα1-1 compared with wild type plants. Our results show that PLDα1 is essential for Arabidopsis plants to cope with the pleiotropic effects of high-Mg2+ stress and delay the leaf senescence.