Rosa Giglio scite author profile

The cotG and cotH genes of Bacillus subtilis encode two previously characterized spore coat proteins. The two genes are adjacent on the chromosome and divergently transcribed by K , a sporulation-specific factor of the RNA polymerase. We report evidence that the cotH promoter maps 812 bp upstream of the beginning of its coding region and that the divergent cotG gene is entirely contained between the promoter and the coding part of cotH. A bioinformatic analysis of all entirely sequenced prokaryotic genomes showed that such chromosomal organization is not common in spore-forming bacilli. Indeed, CotG is present only in B. subtilis, B. amyloliquefaciens, and B. atrophaeus and in two Geobacillus strains. When present, cotG always encodes a modular protein composed of tandem repeats and is always close to but divergently transcribed with respect to cotH. Bioinformatic and phylogenic data suggest that such genomic organizations have a common evolutionary origin and that the modular structure of the extant cotG genes is the outcome of multiple rounds of gene elongation events of an ancestral minigene.Endospore-forming bacteria are Gram-positive microorganisms belonging to different genera and including more than 200 species (13). The common feature of these organisms is the ability to form a quiescent cellular type called an endospore (spore) in response to harsh environments. The spore can survive in this dormant state for long periods, resisting a vast range of stresses, such as high temperature, dehydration, absence of nutrients, and presence of toxic chemicals. When the environmental conditions ameliorate, the spore germinates, originating a vegetative cell able to grow and to sporulate again. Spore resistance is made possible by the presence of the spore coat, a multilayered structure composed by more than 70 proteins synthesized in the mother cell compartment of the sporangium and assembled around the forming spore (16). Coat formation is finely controlled through various processes acting at the transcriptional or posttranslational level. The synthesis of coat proteins is regulated by a cascade of at least five transcription factors: E and K (two mother cell-specific factors of the RNA polymerase), SpoIIID and GerE (two transcriptional regulators acting in conjunction with E and

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Discovery of hyperstable carbohydrate‐active enzymes through metagenomics of extreme environments

Strazzulli

Cobucci‐Ponzano

Iacono

et al. 2019

The FEBS Journal

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The enzymes from hyperthermophilic microorganisms populating volcanic sites represent interesting cases of protein adaptation and biotransformations under conditions where conventional enzymes quickly denature. The difficulties in cultivating extremophiles severely limit access to this class of biocatalysts. To circumvent this problem, we embarked on the exploration of the biodiversity of the solfatara Pisciarelli, Agnano (Naples, Italy), to discover hyperthermophilic carbohydrate‐active enzymes (CAZymes) and to characterize the entire set of such enzymes in this environment (CAZome). Here, we report the results of the metagenomic analysis of two mud/water pools that greatly differ in both temperature and pH (T = 85 °C and pH 5.5; T = 92 °C and pH 1.5, for Pool1 and Pool2, respectively). DNA deep sequencing and following in silico analysis led to 14 934 and 17 652 complete ORFs in Pool1 and Pool2, respectively. They exclusively belonged to archaeal cells and viruses with great genera variance within the phylum Crenarchaeota, which reflected the difference in temperature and pH of the two Pools. Surprisingly, 30% and 62% of all of the reads obtained from Pool1 and 2, respectively, had no match in nucleotide databanks. Genes associated with carbohydrate metabolism were 15% and 16% of the total in the two Pools, with 278 and 308 putative CAZymes in Pool1 and 2, corresponding to ~ 2.0% of all ORFs. Biochemical characterization of two CAZymes of a previously unknown archaeon revealed a novel subfamily GH5_19 β‐mannanase/β‐1,3‐glucanase whose hemicellulose specificity correlates with the vegetation surrounding the sampling site, and a novel NAD+‐dependent GH109 with a previously unreported β‐N‐acetylglucosaminide/β‐glucoside specificity. Databases The sequencing reads are available in the NCBI Sequence Read Archive (SRA) database under the accession numbers SRR7545549 (Pool1) and SRR7545550 (Pool2). The sequences of GH5_Pool2 and GH109_Pool2 are available in GenBank database under the accession numbers MK869723 and MK86972, respectively. The environmental data relative to Pool1 and Pool2 (NCBI BioProject PRJNA481947) are available in the Biosamples database under the accession numbers SAMN09692669 (Pool1) and SAMN09692670 (Pool2).

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Flexibility of the Prograamme of Spore Coat Formation in Bacillus subtilis: Bypass of CotE Requirement by Over-Production of CotH

et al. 2013

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Bacterial spores are surrounded by the coat, a multilayered shell that contributes in protecting the genome during stress conditions. In Bacillus subtilis, the model organism for spore formers, the coat is composed by about seventy different proteins, organized into four layers by the action of several regulatory proteins. A major component of this regulatory network, CotE, is needed to assemble the outer coat and develop spores fully resistant to lysozyme and able to germinate efficiently. Another regulator, CotH, is controlled by CotE and is present in low amounts both during sporulation and in mature spores. In spite of this CotH controls the assembly of at least nine outer coat proteins and cooperates with CotE in producing fully resistant and efficiently germinating spores. In order to improve our understanding of CotH role in spore formation, we over-produced CotH by placing its coding region under the control of a promoter stronger than its own promoter but with a similar timing of activity during sporulation. Over-production of CotH in an otherwise wild type strain did not cause any major effect, whereas in a cotE null background a partial recovery of the phenotypes associated to the cotE null mutation was observed. Western blot, fluorescence microscopy and Surface-Enhanced Raman Scattering spectroscopy data indicate that, in the absence of CotE, over-production of CotH allowed the formation of spores overall resembling wild type spores and carrying in their coat some CotE−/CotH-dependant proteins. Our results suggest that the B. subtilis spore differentiation programme is flexible, and that an increase in the amount of a regulatory protein can replace a missing partner and partially substitute its function in the assembly of the spore coat.

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Novel thermophilic hemicellulases for the conversion of lignocellulose for second generation biorefineries

Cobucci‐Ponzano

Strazzulli

Iacono

et al. 2015

Enzyme and Microbial Technology

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Rosa Giglio

Organization and Evolution of the cotG and cotH Genes of Bacillus subtilis

Discovery of hyperstable carbohydrate‐active enzymes through metagenomics of extreme environments

Flexibility of the Prograamme of Spore Coat Formation in Bacillus subtilis: Bypass of CotE Requirement by Over-Production of CotH

Novel thermophilic hemicellulases for the conversion of lignocellulose for second generation biorefineries

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