Dual Roles of Pseudomonas aeruginosa AlgE in Secretion of the Virulence Factor Alginate and Formation of the Secretion Complex

AlgE is a monomeric 18-stranded β-barrel protein required for secretion of the extracellular polysaccharide alginate in Pseudomonas aeruginosa. To assess the molecular mechanism of alginate secretion, AlgE was subjected to site-specific and FLAG epitope insertion mutagenesis. Except for β-strands 6 and 10, epitope insertions into the transmembrane β-strands abolished localization of AlgE to the outer membrane. Interestingly, an epitope insertion into β-strand 10 produced alginate and was only detectable in outer membranes isolated from cells grown on solid media. The deletion of nine C-terminal amino acid residues destabilized AlgE. Replacement of amino acids that constitute the highly electropositive pore constriction showed that individual amino acid residues have a specific function in alginate secretion. Two of the triple mutants (K47E+R353A+R459E and R74E+R362A+R459E) severely reduced alginate production. Mutual stability analysis using the algE deletion mutant PDO300ΔalgE(miniCTX) showed the periplasmic alginate biosynthesis proteins AlgK and AlgX were completely destabilized, while the copy number of the inner membrane c-di-GMP receptor Alg44 was reduced. Chromosomal integration of algE restored AlgK, AlgX, and Alg44, providing evidence for a multiprotein complex that spans the cell envelope. Periplasmic turn 4 of AlgE was identified as an important region for maintaining the stability of the putative multiprotein complex.     

Three unrelated protease inhibitors enhance accumulation of pharmaceutical recombinant proteins in Nicotiana benthamiana

Agroinfiltrated Nicotiana benthamiana is a flexible and scalable platform for recombinant protein (RP) production, but its great potential is hampered by plant proteases that degrade RPs. Here, we tested 29 candidate protease inhibitors (PIs) in agroinfiltrated N. benthamiana leaves for enhancing accumulation of three unrelated RPs: glycoenzyme α‐Galactosidase; glycohormone erythropoietin (EPO); and IgG antibody VRC01. Of the previously described PIs enhancing RP accumulation, we found only cystatin SlCYS8 to be effective. We identified three additional new, unrelated PIs that enhance RP accumulation: N. benthamiana NbPR4, NbPot1 and human HsTIMP, which have been reported to inhibit cysteine, serine and metalloproteases, respectively. Remarkably, accumulation of all three RPs is enhanced by each PI similarly, suggesting that the mechanism of degradation of unrelated RPs follows a common pathway. Inhibitory functions HsTIMP and SlCYS8 are required to enhance RP accumulation, suggesting that their target proteases may degrade RPs. Different PIs additively enhance RP accumulation, but the effect of each PI is dose‐dependent. Activity‐based protein profiling (ABPP) revealed that the activities of papain‐like Cys proteases (PLCPs), Ser hydrolases (SHs) or vacuolar processing enzymes (VPEs) in leaves are unaffected upon expression of the new PIs, whereas SlCYS8 expression specifically suppresses PLCP activity only. Quantitative proteomics indicates that the three new PIs affect agroinfiltrated tissues similarly and that they all increase immune responses. NbPR4, NbPot1 and HsTIMP can be used to study plant proteases and improve RP accumulation in molecular farming.     

Molecular Elucidation of Two Novel Seed Specific Flavonoid Glycosyltransferases in Soybean

Flavonoids are specialized plant secondary metabolites that are mainly present as glycoconjugates and function as attractants to pollinators and symbionts, UV protectants, allelochemicals, and have antimicrobial and antiherbivore activity for plant health. Because of the heterogeneity of UDP-glycosyltransferases (UGTs) for glycosylation in plants, their function in flavonoid glycosylation remains largely unknown in soybean and other legumes, particularly that of the UGT92 genes. Here, we identified 152 putative UGT92 genes across 48 plant species and elucidated their mode of duplication, expansion/deletion pattern, alignment, phylogenetic analysis, and genome-wide distribution. Two novel UGT-encoding genes Glyma14g04790 (UGT92G1) and Glyma15g03670 (UGT92G2) were isolated from soybean and their heterologous expression was optimized in Escherichia. coli. Both genes exhibited catalytic activity toward quercetin, kaempferol, and myricetin, with UDPglucose as the sugar donor and were characterized as flavanol-specific UGTs. High expression of both UGTs was observed in adaxial and abaxial parenchyma, suspensor cells, and adaxial and abaxial epidermis cells during seed development, suggesting that they are seed-specific flavanol glycosyltransferases in soybean. Co-expression analysis of UGT92 genes with their first and second neighborhood genes provided a basis for their network elucidation in soybean. We provide valuable information on the role of UGT92 in seed development via the glycosylation of multiple flavanols and the potential metabolic engineering of flavonoid compounds in both plants and E. coli.     

DLP1‐dependent mitochondrial fragmentation and redistribution mediate prion‐associated mitochondrial dysfunction and neuronal death

Mitochondrial malfunction is a universal and critical step in the pathogenesis of many neurodegenerative diseases including prion diseases. Dynamin‐like protein 1 (DLP1) is one of the key regulators of mitochondrial fission. In this study, we investigated the role of DLP1 in mitochondrial fragmentation and dysfunction in neurons using in vitro and in vivo prion disease models. Mitochondria became fragmented and redistributed from axons to soma, correlated with increased mitochondrial DLP1 expression in murine primary neurons (N2a cells) treated with the prion peptide PrP^106–126 in vitro as well as in prion strain‐infected hamster brain in vivo. Suppression of DLP1 expression by DPL1 RNAi inhibited prion‐induced mitochondrial fragmentation and dysfunction (measured by ADP/ATP ratio, mitochondrial membrane potential, and mitochondrial integrity). We also demonstrated that DLP1 RNAi is neuroprotective against prion peptide in N2a cells as shown by improved cell viability and decreased apoptosis markers, caspase 3 induced by PrP^106–126. On the contrary, overexpression of DLP1 exacerbated mitochondrial dysfunction and cell death. Moreover, inhibition of DLP1 expression ameliorated PrP^106–126‐induced neurite loss and synaptic abnormalities (i.e., loss of dendritic spine and PSD‐95, a postsynaptic scaffolding protein as a marker of synaptic plasticity) in primary neurons, suggesting that altered DLP1 expression and mitochondrial fragmentation are upstream events that mediate PrP^106–126‐induced neuron loss and degeneration. Our findings suggest that DLP1‐dependent mitochondrial fragmentation and redistribution plays a pivotal role in PrP^Sc‐associated mitochondria dysfunction and neuron apoptosis. Inhibition of DLP1 may be a novel and effective strategy in the prevention and treatment of prion diseases.     

Phytochemical,antioxidant and mineral composition of hydroalcoholic extract of chicory (Cichorium intybus L.) leaves

The phytochemical, antioxidant and mineral composition of hydroalcoholic extract of leaves of Cichorium intybus L., was determined. The leaves were found to possess comparatively higher values of total flavonoids, total phenolic acids. The phytochemical screening confirmed the presence of tannins, saponins, flavonoids, in the leaves of the plant. The leaf extract was found to show comparatively low value of IC₅₀ for 2,2-diphenyl-1-picrylhydrazyl (DPPH) inhibition. The IC₅₀ value of chicory leaves extract was found to be 67.2 ± 2.6 μg/ml. The extracts were found to contain high amount of mineral elements especially Mg and Zn. Due to good phytochemical and antioxidant composition, C. intybus L., leaves would be an important candidate in pharmaceutical formulations and play an important role in improving the human health by participating in the antioxidant defense system against free radical generation.     

Contribution of EDRF and EDHF to restoration of endothelial function following dietary restrictions in hypercholesterolemic rats

The mechanisms underlying the impairment of endothelium-mediated vasorelaxation induced by dietary hypercholesterolemia and the mechanisms of restoration of endothelial function following reintroduction of low cholesterol diet were evaluated. Feeding rats with high cholesterol diet induced hypercholesterolemia and high blood pressure. This was associated with reduced vasorelaxation in response to acetylcholine, isoproterenol, and adenosine. At the same time, exaggerated contractile responses to serotonin and phenylephrine were observed. Reintroduction of a normal diet to cholesterol fed rats resulted in significant normalization of blood pressure, serum lipid profile, relaxation and contractile responses. The contributions of endothelial derived relaxing factors (EDRF), endothelial derived contractile factors (EDCFs)/prostanoids, and endothelial derived hyperpoalrising factor (EDHF) to the vasorelaxation in each group of animals were assessed. EDCFs constricting activity was increased in both cholesterol fed groups as compared to the control group. EDRF and EDHF were found to be the primary factors involved in the regulation of endothelium-mediated responsiveness. In control animals, EDRF was responsible for 70-90% of relaxation, depending on the agonist used. In cholesterol fed animals, EDRF was significantly reduced while EDHF was maintained or enhanced showing that EDHF had a significant role in maintaining the endothelial responses. Importantly, the restoration of vasorelaxation following reintroduction of normal diet was mediated not only by improvement of EDRF-dependent relaxation, but also to a significant extent by a further increase in EDHF-mediated relaxation. Taken together, the data showed that EDRF was attenuated during hypercholesterolemia and dietary interventions with low fat content restored these responses. However, EDHF-mediated responses were not reduced by hypercholesterolemia and subsequently improved their function after application of low cholesterol diet. The results implicate EDHF-mediated relaxation is also an important mechanism for restoration of endothelial function upon application of dietary restrictions for reduction of serum cholesterol level.     

The role of plant-associated rhizobacteria in plant growth,biocontrol and abiotic stress management

The rhizosphere is the region around the plant roots where maximum microbial activities occur. In the rhizosphere, microorganisms' beneficial and harmful activities affect plant growth and development. The mutualistic rhizospheric bacteria which improve plant growth and health are known as plant growth-promoting rhizobacteria (PGPR). They are very important due to their ability to help the plant in diverse ways. PGPR such as Pseudomonas, Bacillus, Azospirillum, Azotobacter, Arthrobacter, Achromobacter, Micrococcus, Enterobacter, Rhizobium, Agrobacterium, Pantoea and Serratia are now very well known. Rhizomicrobiome plays critical roles in nutrient acquisition and assimilation, improved soil texture, secreting and modulating extracellular molecules such as hormones, secondary metabolites, antibiotics and various signal compounds, all leading to the enhancement of plant growth and development. The microbes and compounds they secrete constitute valuable biostimulants and play pivotal roles in modulating plant stress responses. In this review, we highlight the rhizobacteria diversity and cutting-edge findings focusing on the role of a PGPR in plant growth and development. We also discussed the role of PGPR in resisting the adverse effects arising from various abiotic (drought, salinity, heat, heavy metals) stresses.