Differential proteomics research of Bacillus amyloliquefaciens and its genome-shuffled saltant for improving fengycin production

Abstract In the previous study, we used genome shuffling to improve fengycin production of the original strain Bacillus amyloliquefaciens ES-24. After two rounds of genome shuffling, a high-yield recombinant FMB72 strain that exhibited 8.30-fold increase in fengycin production was obtained. In this study, comparative proteomic analysis of the parental ES-24 and genome-shuffled FMB72 strains was conducted to examine the differentially expressed proteins. In the shuffled strain FMB72, 50 differently expressed spots (p 0.05) were selected to be excised and analyzed using Matrix-Assisted Laser Desorption/Ionization Time of Flight/Time of Flight Mass Spectrometry, and finally 44 protein spots were confidently identified according to NCBI database. According to clusters of orthologous groups (COG) functional category analysis and related references, the differentially expressed proteins could be classified into several functional categories, including proteins involved in metabolism, energy generation and conversion, DNA replication, transcription, translation, ribosomal structure and biogenesis, cell motility and secretion, signal transduction mechanisms, general function prediction. Of the 44 identified proteins, signaling proteins ComA and Spo0A may positively regulate fengycin synthesis at transcriptional level. Taken together, the present study will be informative for exploring the exact roles of ComA and Spo0A in fengycin synthesis and explaining the molecular mechanism of fengycin synthesis.

Differential proteomics research of Bacillus amyloliquefaciens and its genome-shuffled saltant for improving fengycin production

Abstract In the previous study, we used genome shuffling to improve fengycin production of the original strain Bacillus amyloliquefaciens ES-2-4. After two rounds of genome shuffling, a high-yield recombinant FMB72 strain that exhibited 8.30-fold increase in fengycin production was obtained. In this study, comparative proteomic analysis of the parental ES-2-4 and genome-shuffled FMB72 strains was conducted to examine the differentially expressed proteins. In the shuffled strain FMB72, 50 differently expressed spots (p < 0.05) were selected to be excised and analyzed using Matrix-Assisted Laser Desorption/Ionization Time of Flight/Time of Flight Mass Spectrometry, and finally 44 protein spots were confidently identified according to NCBI database. According to clusters of orthologous groups (COG) functional category analysis and related references, the differentially expressed proteins could be classified into several functional categories, including proteins involved in metabolism, energy generation and conversion, DNA replication, transcription, translation, ribosomal structure and biogenesis, cell motility and secretion, signal transduction mechanisms, general function prediction. Of the 44 identified proteins, signaling proteins ComA and Spo0A may positively regulate fengycin synthesis at transcriptional level. Taken together, the present study will be informative for exploring the exact roles of ComA and Spo0A in fengycin synthesis and explaining the molecular mechanism of fengycin synthesis.

Spo0A positively regulates epr expression by negating the repressive effect of co-repressors, SinR and ScoC, in Bacillus subtilis.

Bacillus subtilis under nutritional deprivation exhibits several physiological responses such as synthesis of degradative enzymes, motility, competence, sporulation, etc. At the onset of post-exponential phase the global response regulator, Spo0A, directly or indirectly activates the expression of genes involved in the above processes. These genes are repressed during the exponential phase by a group of proteins called transition state regulators, e.g. AbrB, ScoC and SinR. One such post-exponentially expressed gene is epr, which encodes a minor extracellular serine protease and is involved in the swarming motility of B. subtilis. Deletion studies of the upstream region of epr promoter revealed that epr is co-repressed by transition state regulators, SinR and ScoC. Our study shows that Spo0A positively regulates epr expression by nullifying the repressive effect of co-repressors, SinR and ScoC. We demonstrate via in vitro mobility shift assays that Spo0A binds to the upstream region of epr promoter and in turn occludes the binding site of one of the co-repressor, SinR. This explains the mechanism behind the positive regulatory effect of Spo0A on epr expression.

Formación de endosporas en Clostridium y su interacción con el proceso de solventogénesis / Endospore formation in Clostridium and its interaction with solventogenesis

La solventogénesis y la esporulación son mecanismos de las células de Clostridium para resistir ambientes hostiles. Este segundo proceso ha sido estudiado utilizando como modelo lo que sucede con Bacillus, aunque se reconocen diferencias marcadas entre los dos géneros especialmente en el inicio, específicamente en los eventos por medio de los que se da la fosforilación del regulador maestro Spo0A. En la actualidad se ha avalado la teoría que afirma que tres histidin quinasas huérfanas, diferentes a las proteínas Spo0B (histidin quinasa) y Spo0F(fosfotransferasa) en Bacillus, son las encargadas de fosforilar en Clostridium de forma directa a Spo0A, que posteriormente activa la transcripción de diferentes factores sigma relacionados, de forma similar en los dos géneros bacterianos. La proteína Spo0A, perteneciente a la familia de reguladores de respuesta, se comporta como una entidad regulatoria global que tiene injerencia sobre los procesos de formación de esporas y solventes, modulando genes necesarios para que se produzcan acetona y butanol, además de genes de esporulación. El entendimiento de este proceso ha llevado a los investigadores a emplear diferentes técnicas moleculares que permitan incrementar la producción de solventes, así como eliminar la propiedad de las células de producir endosporas. Por tal razón, este escrito presenta un resumen de estas dos redes de expresión de genes, conectadas por el regulador maestro Spo0A.

Solventogenesis and sporulation are mechanisms used by Clostridium cells to resist hostile environments. Sporulation has been studied using as a model what happens with Bacillus, but marked differences were recognized, particularly in the events that led the phosphorylation of the master controller Spo0A. Currently, a theory that claims that three orphan histidine kinases, different from Spo0B (histidin kinase) and spo0F (phosphotransferase) proteins in Bacillus, phosphorilate directly Spo0A in Clostridium activating transcription of different sigma factors which are similar in the two bacterial genera, has been supported. Spo0A protein, which belongs to the family of response regulators, behaves as an entity that has global regulatory interference on the processes of spore formation and solvents, modulating genes necessary to produce acetone and butanol. The understanding of this process has led researchers to employ different molecular techniques that increase the production of solvents, and remove the property of the cells to produce endospores. Reason why, this paper presents an updated summary of these two gene expression networks, connected by the master regulator spo0A.