SummaryThe ability to move towards favourable conditions provides fundamental advantages to organisms. Interestingly, flagella as motility structures evolved independently in the bacterial and the archaeal kingdom. Whereas bacterial flagella have been intensively studied, our knowledge regarding the archaeal counterpart is mostly restricted to Euryarchaeota rather than crenarchaeal flagella. We therefore investigated the flagellar assembly system of the crenarchaeal model organism Sulfolobus acidocaldarius in vivo. Promoter studies and qRT-PCR analyses of the flagella gene cluster provided evidence that the expression of the fla genes was induced by tryptone starvation. Moreover, we confirmed presence of a secondary fla promoter within the flaB gene that regulates the transcription of downstream genes flaX-J. Markerless in-frame deletions for all fla genes encoded in the fla gene cluster were constructed. Western blot analysis of all fla deletion strains suggested hierarchical protein interactions during the archaeal flagella assembly. Moreover, functional analysis by thermomicroscopy revealed non-motile cells for each of the mutant strains. Electron micrographs demonstrated that lack of motility coincided with the loss of flagellar assembly. Thus we demonstrated that all seven fla genes are essential for crenarchaeal flagellum assembly and function.
The worldwide increase in human population raises a big threat to the food security of each people as the land for agriculture is limited and even getting reduced with time. Therefore, it is essential that agricultural productivity should be enhanced significantly within the next few decades to meet the large demand of food by emerging population. Not to mention, too much dependence on chemical fertilizers for more crop productions inevitably damages both environmental ecology and human health with great severity. Exploitation of microbes as biofertilizers is considered to some extent an alternative to chemical fertilizers in agricultural sector due to their extensive potentiality in enhancing crop production and food safety. It has been observed that some microorganisms including plant growth promoting bacteria, fungi, Cyanobacteria, etc. have showed biofertilizer-like activities in the agricultural sector. Extensive works on biofertilizers have revealed their capability of providing required nutrients to the crop in sufficient amounts that resulted in the enhancement of crop yield. The present review elucidates various mechanisms that have been exerted by biofertilizers in order to promote plant growth and also provides protection against different plant pathogens. The aim of this review is to discuss the important roles and applications of biofertilizers in different sectors including agriculture, bioremediation, and ecology.
SUMMARY Superfamily ATPases in Type IV pili (T4P), Type 2 secretion (T2S), and archaella (formerly archaeal flagella) employ similar sequences for distinct biological processes. Here we structurally and functionally characterize prototypical superfamily ATPase FlaI from Sulfolobus acidocaldarius showing FlaI activities in archaeal swimming organelle assembly and movement. FlaI solution X-ray scattering and crystal structures with and without nucleotide reveal a hexameric crown assembly with key cross-subunit interactions: rigid building blocks form between N-terminal domains (points) and neighboring subunit C-terminal domains (crown ring). Upon nucleotide binding, these six cross-subunit blocks move with respect to each other distinctly from secretion and pilus ATPases. Crown interactions and conformations regulate assembly, motility and force direction by a basic-clamp switching mechanism driving conformational changes between stable, backbone-interconnected moving blocks. Collective structural and mutational results identify in vivo functional components for assembly and motility, phosphate triggered rearrangements by ATP-hydrolysis, and molecular predictors for distinct ATPase superfamily functions.
SummaryThe motor of the membrane‐anchored archaeal motility structure, the archaellum, contains FlaX, FlaI and FlaH. FlaX forms a 30 nm ring structure that acts as a scaffold protein and was shown to interact with the bifunctional ATPase FlaI and FlaH. However, the structure and function of FlaH has been enigmatic. Here we present structural and functional analyses of isolated FlaH and archaellum motor subcomplexes. The FlaH crystal structure reveals a RecA/Rad51 family fold with an ATP bound on a conserved and exposed surface, which presumably forms an oligomerization interface. FlaH does not hydrolyze ATP in vitro, but ATP binding to FlaH is essential for its interaction with FlaI and for archaellum assembly. FlaH interacts with the C‐terminus of FlaX, which was earlier shown to be essential for FlaX ring formation and to mediate interaction with FlaI. Electron microscopy reveals that FlaH assembles as a second ring inside the FlaX ring in vitro. Collectively these data reveal central structural mechanisms for FlaH interactions in mediating archaellar assembly: FlaH binding within the FlaX ring and nucleotide‐regulated FlaH binding to FlaI form the archaellar basal body core.
The thermoacidophilic crenarchaeote Sulfolobus acidocaldarius displays three distinct type IV pili-like structures on its surface: (i) the flagellum, (ii) the UV-induced pili and (iii) the adhesive pili. In bacteria, surface appendages play an important role in the spatial organization of cells from initial surface attachment to the development of mature community structures. To investigate the influence of the diverse set of type IV pili-like structures in S. acidocaldarius, single, double and triple mutants lacking the cell surface appendages were constructed and analysed for their behaviour in attachment assays and during biofilm formation. A heat stable green fluorescent protein was employed the first time in a hyperthermophilic archaeon. A codon adjusted eCGP123 was expressed to study mixed biofilms of different deletion mutants to understand the interplay of the surface structures during biofilm formation. During this process the deletion of the adhesive pili and UV-induced pili led to the most pronounced effects, either an increase in cell density or increased cluster formation respectively. However, all three cell surface appendages played a role in the colonization of surfaces and only the interplay of all three appendages leads to the observed wild-type biofilm phenotype.
Archaea display a variety of type IV pili on their surface and employ them in different physiological functions. In the crenarchaeon Sulfolobus acidocaldarius the most abundant surface structure is the aap pilus (archaeal adhesive pilus). The construction of in frame deletions of the aap genes revealed that all the five genes (aapA, aapX, aapE, aapF, aapB) are indispensible for assembly of the pilus and an impact on surface motility and biofilm formation was observed. Our analyses revealed that there exists a regulatory cross-talk between the expression of aap genes and archaella (formerly archaeal flagella) genes during different growth phases. The structure of the aap pilus is entirely different from the known bacterial type IV pili as well as other archaeal type IV pili. An aap pilus displayed 3 stranded helices where there is a rotation per subunit of ~ 138° and a rise per subunit of ~ 5.7 Å. The filaments have a diameter of ~ 110 Å and the resolution was judged to be ~ 9 Å. We concluded that small changes in sequence might be amplified by large changes in higher-order packing. Our finding of an extraordinary stability of aap-pili possibly represents an adaptation to harsh environments that S. acidocaldarius encounters.
Bacillus aryabhattai AB211 is a plant growth promoting, Gram-positive firmicute, isolated from the rhizosphere of tea (Camellia sinensis), one of the oldest perennial crops and a major non-alcoholic beverage widely consumed all over the world. The whole genome of B. aryabhattai AB211 was sequenced, annotated and evaluated with special focus on genomic elements related to plant microbe interaction. It’s genome sequence reveals the presence of a 5,403,026 bp chromosome. A total of 5226 putative protein-coding sequences, 16 rRNA, 120 tRNA, 8 ncRNAs, 58 non-protein coding genes, and 11 prophage regions were identified. Genome sequence comparisons between strain AB211 and other related environmental strains of B. aryabhattai, identified about 3558 genes conserved among all B. aryabhattai genomes analyzed. Most of the common genes involved in plant growth promotion activities were found to be present within core genes of all the genomes used for comparison, illustrating possible common plant growth promoting traits shared among all the strains of B. aryabhattai. Besides the core genes, some genes were exclusively identified in the genome of strain AB211. Functional annotation of the genes predicted in the strain AB211 revealed the presence of genes responsible for mineral phosphate solubilization, siderophores, acetoin, butanediol, exopolysaccharides, flagella biosynthesis, surface attachment/biofilm formation, and indole acetic acid production, most of which were experimentally verified in the present study. Genome analysis and experimental evidence suggested that AB211 has robust central carbohydrate metabolism implying that this bacterium can efficiently utilize the root exudates and other organic materials as an energy source. Genes for the production of peroxidases, catalases, and superoxide dismutases, that confer resistance to oxidative stresses in plants were identified in AB211 genome. Besides these, genes for heat shock tolerance, cold shock tolerance, glycine-betaine production, and antibiotic/heavy metal resistance that enable bacteria to survive biotic/abiotic stress were also identified. Based on the genome sequence information and experimental evidence as presented in this study, strain AB211 appears to be metabolically diverse and exhibits tremendous potential as a plant growth promoting bacterium.
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