Production of Reverse Transcriptase and DNA Polymerase in Bacterial Expression Systems.

DNA amplification and reverse transcription enzymes have proven to be invaluable in fast and reliable diagnostics and research applications because of their processivity, specificity, and robustness. Our study focused on the production of mutant Taq DNA polymerase and mutant M-MLV reverse transcriptase in the expression hosts Vibrio natriegens and Escherichia coli under various expression conditions. We also examined nonspecific extracellular production in V. natriegens. Intracellularly, M-MLV was produced in V. natriegens at the level of 11% of the total cell proteins (TCPs) compared with 16% of TCPs in E. coli. We obtained a soluble protein that accounted for 11% of the enzyme produced in V. natriegens and 22% of the enzyme produced in E. coli. Taq pol was produced intracellularly in V. natriegens at the level of 30% of TCPs compared with 26% of TCPs in E. coli. However, Taq pol was almost non-soluble in E. coli, whereas in V. natriegens, we obtained a soluble protein that accounted for 23% of the produced enzyme. We detected substantial extracellular production of Taq pol. Thus, V. natriegens is a suitable alternative host with the potential for production of recombinant proteins.

Novel expression system based on enhanced permeability of Vibrio natriegens cells induced by D,D- carboxypeptidase overexpression.

Vibrio natriegens is a fast-growing, non-pathogenic marine bacterium with promising features for biotechnological applications such as high-level recombinant protein production or fast DNA propagation. A remarkable short generation time (< 10 min), robust proteosynthetic activity and versatile metabolism with abilities to utilise wide range of substrates contribute to its establishment as a future industrial platform for fermentation processes operating with high productivity.D,D-carboxypeptidases are membrane-associated enzymes involved in peptidoglycan biosynthesis and cell wall formation. This study investigates the impact of overexpressed D,D-carboxypeptidases on membrane integrity and the increased leakage of intracellular proteins into the growth medium in V. natriegens. Our findings confirm that co-expression of these enzymes can enhance membrane permeability, thereby facilitating the transport of target proteins into the extracellular environment, without the need for secretion signals, tags, or additional permeabilization methods. Using only a single step IMAC chromatography, we were able to purify AfKatG, MDBP or Taq polymerase in total yields of 117.9 ± 56.0 mg/L, 36.5 ± 12.9 mg/L and 26.5 ± 6.0 mg/L directly from growth medium, respectively. These results demonstrate the feasibility of our V. natriegens based system as a broadly applicable extracellular tag-less recombinant protein producer.

Role of RNAIII in Resistance to Antibiotics and Antimicrobial Agents in Staphylococcus epidermidis Biofilms.

Staphylococcus epidermidis is a known opportunistic pathogen and is one of the leading causes of chronic biofilm-associated infections. Biofilm formation is considered as a main strategy to resist antibiotic treatment and help bacteria escape from the human immune system. Understanding the complex mechanisms in biofilm formation can help find new ways to treat resistant strains and lower the prevalence of nosocomial infections. In order to examine the role of RNAIII regulated by the agr quorum sensing system and to what extent it influences biofilm resistance to antimicrobial agents, deletion mutant S. epidermidis RP62a-ΔRNAIII deficient in repressor domains with a re-maining functional hld gene was created. A deletion strain was used to examine the influence of oxacillin in combination with vanillin on biofilm resistance and cell survival was determined. Utilizing real-time qPCR, confocal laser scanning microscopy (CLSM), and crystal violet staining analyses, we found that the RNAIII-independent controlled phenol soluble modulins (PSMs) and RNAIII effector molecule have a significant role in biofilm resistance to antibiotics and phenolic compounds, and it protects the integrity of biofilms. Moreover, a combination of antibiotic and antimicrobial agents can induce methicillin-resistant S. epidermidis biofilm formation and can lead to exceedingly difficult medical treatment.

Comparison of simple expression procedures in novel expression host Vibrio natriegens and established Escherichia coli system.

Marine bacterium Vibrio natriegensis a novel host platform for different applications in molecular biology and biotechnology. It has one of the fastest growth rates of any known microorganisms and its extremely short doubling time indicates a high level of proteosynthetic activity. Regarding the necessity of developing new high-level protein expression systems it represents an extremely interesting subject. V. natriegens fulfills many important features for a suitable host including non- pathogenicity, easy scale-up process, potential for using alternative carbon sources (compared to E. coli), growth media and potential for further genetic and metabolic engineering with employment of a wide range of genetic tools. This work compares V. natriegens as an expression host for production of recombinant human growth hormone (hGH), yeast alcohol dehydrogenase (ADH) and archaeal catalase-peroxidase (AfKatG) to E. coliand establishes the basis for future development of this platform. The selected proteins are of different origins, sizes and intended applications. Our results have shown that cultures of V. natriegens using sucrose as a main carbon source can be used for the production of industrially applicable proteins, where it offers higher biomass productions compared to E. coli. In case of human growth hormone production, produced amounts were lower compared to those of E. coli (38 % of total cell protein (TCP) for V. natriegens vs. 58 % of TCP for E. coli, with similar solubility of around 40 % in both cases). In case of yeast alcohol dehydrogenase, V. natriegens produced 26 % of TCP vs. 42 % of TCP in E. coli, but with severely decreased solubility in case of V. natriegens cultures. Finally V. natriegens cultures were able to produce catalase-peroxidase AfKatG at the level of 33 % of TCP compared to 26 % of TCP in E. coli. Obtained results suggest that there are still significant differences in reliability and ease of use between E. coli and V. natriegens, with latter being more susceptible to condition changes and producing inconsistent results.