BackgroundMisfolded proteins accumulating outside the bacterial cytoplasmic membrane can interfere with the secretory machinery, hence the existence of quality factors to eliminate these misfolded proteins is of capital importance in bacteria that are efficient producers of secretory proteins. These bacteria normally use a specific two-component system to respond to the stress produced by the accumulation of the misfolded proteins, by activating the expression of HtrA-like proteases to specifically eliminate the incorrectly folded proteins.Methodology/Principal FindingsOverproduction of alpha-amylase in S. lividans causing secretion stress permitted the identification of a two-component system (SCO4156-SCO4155) that regulates three HtrA-like proteases which appear to be involved in secretion stress response. Mutants in each of the genes forming part of the two-genes operon that encodes the sensor and regulator protein components accumulated misfolded proteins outside the cell, strongly suggesting the involvement of this two-component system in the S. lividans secretion stress response.Conclusions/SignificanceTo our knowledge this is the first time that a specific secretion stress response two-component system is found to control the expression of three HtrA-like protease genes in S. lividans, a bacterium that has been repeatedly used as a host for the synthesis of homologous and heterologous secretory proteins of industrial application.
Expression of the steffimycin gene cluster in Steptomyces albus in combination with plasmids directing the biosynthesis of different neutral and branched-chain deoxyhexoses led to the identification of twelve new glycosylated derivatives of steffimycin with different degrees of decoration in the tetracyclic core. These experiments demonstrate the flexibility of L-rhamnosyltransferase StfG for recognition of a variety of D- and L-deoxyhexoses, harboring different degrees of deoxygenation as 2-deoxyhexoses, 2,6-deoxyhexoses, and 2,3,6-deoxyhexoses, and their attachment to 8-demethoxy-10-deoxysteffimycinone. In addition, the flexibility of 3'-O-methyltransferase OleY, from Streptomyces, for the methylation of deoxyhexoses attached to the steffimycin aglycone is shown by expression of oleY in Streptomyces steffisburgensis, leading to the isolation of 3'-O-methylsteffimycin. Analysis of the biological activities of these compounds against three human tumor cell lines-breast adenocarcinoma, non-small cell lung cancer, and colon adenocarcinoma-revealed two of them, 3'-O-methylsteffimycin and D-digitoxosyl-8-demethoxy-10-deoxysteffimycinone, to possess improved antitumor activities, showing GI50 values below 1.0 microM, while steffimycin's GI50 values fluctuate between 2.61 to 6.79 microM depending upon the cell line used. The antitumor activity data provide some insights into the structure-activity relationships of the new steffimycin derivatives, in relation to the configuration of hydroxy groups at positions C-3' and C-4' of the sugar moiety and positions C-8 and C-10 of the tetracyclic core.
BackgroundBacterial two-component signal transduction regulatory systems are the major set of signalling proteins frequently mediating responses to changes in the environment. They typically consist of a sensor, a membrane-associated histidine kinase and a cytoplasmic response regulator. The membrane-associated sensor detects the environmental signal or stress, whereas the cytoplasmic regulatory protein controls the cellular response usually by gene transcription modulation.Methodology/PrincipalFindingsThe Streptomyces coelicolor two genes operon SCO5784-SCO5785 encodes a two-component system, where SCO5784 encodes a histidine-kinase sensor and SCO5785 encodes a response regulator protein. When the expression level of the regulator gene decreases, the antibiotic synthesis and sporulation is delayed temporarily in addition to some ribosomal genes became up regulated, whereas the propagation of the regulatory gene in high copy number results in the earlier synthesis of antibiotics and sporulation, as well as the down regulation of some ribosomal genes and, moreover, in the overproduction of several extracellular proteins. Therefore, this two-component system in S. coelicolor seems to influence various processes characterised by the transition from primary to secondary metabolism, as determined by proteomic and transcriptomic analyses.Conclusions/SignificancePropagation of SCO5785 in multicopy enhances the production of antibiotics as well as secretory proteins. In particular, the increase in the expression level of secretory protein encoding genes, either as an artefactual or real effect of the regulator, could be of potential usefulness when using Streptomyces strains as hosts for homologous or heterologous extracellular protein production.
Streptomyces lividans is considered an efficient host for the secretory production of homologous and heterologous proteins. To identify possible bottlenecks in the protein production process, a comparative transcriptomic approach was adopted to study cellular responses during the overproduction of a Sec-dependent model protein (alpha-amylase) and a Tat-dependent model protein (agarase) in Streptomyces lividans. The overproduction of the model secretory proteins via the Sec or the Tat route in S. lividans does elicit a different major cell response in the bacterium. The stringent response is a bacterial response to nutrients’ depletion, which naturally occurs at late times of the bacterial cell growth. While the induction of the stringent response at the exponential phase of growth may limit overall productivity in the case of the Tat route, the induction of that response does not take place in the case of the Sec route, which comparatively is an advantage in secretory protein production processes. Hence, this study identifies a potential major drawback in the secretory protein production process depending on the secretory route, and provides clues to improving S. lividans as a protein production host.
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