Transcript analysis of the extended hyp-operon in the cyanobacteria Nostoc sp. strain PCC 7120 and Nostoc punctiforme ATCC 29133

<p>Abstract</p> <p>Background</p> <p>Cyanobacteria harbor two [NiFe]-type hydrogenases consisting of a large and a small subunit, the Hup- and Hox-hydrogenase, respectively. Insertion of ligands and correct folding of nickel-iron hydrogenases require assistance of accessory maturation proteins (encoded by the <it>hyp</it>-genes). The intergenic region between the structural genes encoding the uptake hydrogenase (<it>hupSL</it>) and the accessory maturation proteins (<it>hyp </it>genes) in the cyanobacteria <it>Nostoc </it>PCC 7120 and <it>N. punctiforme </it>were analysed using molecular methods.</p> <p>Findings</p> <p>The five ORFs, located in between the uptake hydrogenase structural genes and the <it>hyp</it>-genes, can form a transcript with the <it>hyp</it>-genes. An identical genomic localization of these ORFs are found in other filamentous, N₂-fixing cyanobacterial strains. In <it>N. punctiforme </it>and <it>Nostoc </it>PCC 7120 the ORFs upstream of the <it>hyp</it>-genes showed similar transcript level profiles as <it>hupS </it>(hydrogenase structural gene), <it>nifD </it>(nitrogenase structural gene), <it>hypC </it>and <it>hypF </it>(accessory hydrogenase maturation genes) after nitrogen depletion. <it>In silico </it>analyzes showed that these ORFs in <it>N. punctiform</it>e harbor the same conserved regions as their homologues in <it>Nostoc </it>PCC 7120 and that they, like their homologues in <it>Nostoc </it>PCC 7120, can be transcribed together with the <it>hyp</it>-genes forming a larger extended <it>hyp-</it>operon. DNA binding studies showed interactions of the transcriptional regulators CalA and CalB to the promoter regions of the extended <it>hyp</it>-operon in <it>N. punctiforme </it>and <it>Nostoc </it>PCC 7120.</p> <p>Conclusions</p> <p>The five ORFs upstream of the <it>hyp</it>-genes in several filamentous N₂-fixing cyanobacteria have an identical genomic localization, in between the genes encoding the uptake hydrogenase and the maturation protein genes. In <it>N. punctiforme </it>and <it>Nostoc </it>PCC 7120 they are transcribed as one operon and may form transcripts together with the <it>hyp</it>-genes. The expression pattern of the five ORFs within the extended <it>hyp</it>-operon in both <it>Nostoc punctiforme </it>and <it>Nostoc </it>PCC 7120 is similar to the expression patterns of <it>hupS</it>, <it>nifD</it>, <it>hypF </it>and <it>hypC</it>. CalA, a known transcription factor, interacts with the promoter region between <it>hupSL </it>and the five ORFs in the extended <it>hyp</it>-operon in both <it>Nostoc </it>strains.</p

Perception of a divergent family of phytocytokines by the Arabidopsis receptor kinase MIK2

Plant genomes encode hundreds of receptor kinases and peptides, but the number of known plant receptor-ligand pairs is limited. We report that the Arabidopsis leucine-rich repeat receptor kinase LRR-RK MALE DISCOVERER 1-INTERACTING RECEPTOR LIKE KINASE 2 (MIK2) is the receptor for the SERINE RICH ENDOGENOUS PEPTIDE (SCOOP) phytocytokines. MIK2 is necessary and sufficient for immune responses triggered by multiple SCOOP peptides, suggesting that MIK2 is the receptor for this divergent family of peptides. Accordingly, the SCOOP12 peptide directly binds MIK2 and triggers complex formation between MIK2 and the BRASSINOSTEROID INSENSITIVE 1-ASSOCIATED KINASE 1 (BAK1) co-receptor. MIK2 is required for resistance to the important root pathogen Fusarium oxysporum. Notably, we reveal that Fusarium proteomes encode SCOOP-like sequences, and corresponding synthetic peptides induce MIK2-dependent immune responses. These results suggest that MIK2 may recognise Fusarium-derived SCOOP-like sequences to induce immunity against Fusarium. The definition of SCOOPs as MIK2 ligands will help to unravel the multiple roles played by MIK2 during plant growth, development and stress responses

Salmonella Typhi Vi capsule prime-boost vaccination induces convergent and functional antibody responses

Vaccine development to prevent Salmonella Typhi infections has accelerated over the past decade, resulting in licensure of new vaccines, which use the Vi polysaccharide (Vi PS) of the bacterium conjugated to an unrelated carrier protein as the active component. Antibodies elicited by these vaccines are important for mediating protection against typhoid fever. However, the characteristics of protective and functional Vi antibodies are unknown. In this study, we investigated the human antibody repertoire, avidity maturation, epitope specificity, and function after immunization with a single dose of Vi-tetanus toxoid conjugate vaccine (Vi-TT) and after a booster with plain Vi PS (Vi-PS). The Vi-TT prime induced an IgG1-dominant response, whereas the Vi-TT prime followed by the Vi-PS boost induced IgG1 and IgG2 antibody production. B cells from recipients who received both prime and boost showed evidence of convergence, with shared V gene usage and CDR3 characteristics. The detected Vi antibodies showed heterogeneous avidity ranging from 10 μM to 500 pM, with no evidence of affinity maturation after the boost. Vi-specific antibodies mediated Fc effector functions, which correlated with antibody dissociation kinetics but not with association kinetics. We identified antibodies induced by prime and boost vaccines that recognized subdominant epitopes, indicated by binding to the de–O-acetylated Vi backbone. These antibodies also mediated Fc-dependent functions, such as complement deposition and monocyte phagocytosis. Defining strategies on how to broaden epitope targeting for S. Typhi Vi and enriching for antibody Fc functions that protect against typhoid fever will advance the design of high-efficacy Vi vaccines for protection across diverse populations