Non-specific DNAases from the rumen bacterium Prevotella bryantii

Production of a new non-specific nuclease from Yersinia enterocolitica subsp. palearctica: optimization of induction conditions using response surface methodology

A new non-specific nuclease from Yersinia enterocolitica subsp. palearctica (Y. NSN) was expressed in Escherichia coli (E. coli) BL 21 Star^TM (DE3)plysS. Induction conditions, including isopropyl-β-D-thiogalactoside (IPTG) concentration, cell density (OD600), induction time and induction temperature, were optimized using response surface methodology. Statistical analysis of the results revealed that induction temperature and all the quadratic terms of variables had significant effects on enzyme activity of Y. NSN. The optimal induction conditions were as follows: 1.5 mmol/L IPTG, OD600 of 0.80, induction time of 20.5 h, and induction temperature of 32 °C. Under the optimized conditions, the highest enzyme activity could be obtained.

Bacterial sex in dental plaque

Genes are transferred between bacteria in dental plaque by transduction, conjugation, and transformation. Membrane vesicles can also provide a mechanism for horizontal gene transfer. DNA transfer is considered bacterial sex, but the transfer is not parallel to processes that we associate with sex in higher organisms. Several examples of bacterial gene transfer in the oral cavity are given in this review. How frequently this occurs in dental plaque is not clear, but evidence suggests that it affects a number of the major genera present. It has been estimated that new sequences in genomes established through horizontal gene transfer can constitute up to 30% of bacterial genomes. Gene transfer can be both inter- and intrageneric, and it can also affect transient organisms. The transferred DNA can be integrated or recombined in the recipient's chromosome or remain as an extrachromosomal inheritable element. This can make dental plaque a reservoir for antimicrobial resistance genes. The ability to transfer DNA is important for bacteria, making them better adapted to the harsh environment of the human mouth, and promoting their survival, virulence, and pathogenicity.

Characterization of a novel non-specific nuclease from thermophilic bacteriophage GBSV1

Background

Thermostable enzymes from thermophiles have attracted extensive studies. In this investigation, a nuclease-encoding gene (designated as GBSV1-NSN) was obtained from a thermophilic bacteriophage GBSV1 for the first time.

Results

After recombinant expression in Escherichia coli, the purified GBSV1-NSN exhibited non-specific nuclease activity, being able to degrade various nucleic acids, including RNA, single-stranded DNA and double-stranded DNA that was circular or linear. Based on sequence analysis, the nuclease shared no homology with any known nucleases, suggesting that it was a novel nuclease. The characterization of the recombinant GBSV1-NSN showed that its optimal temperature and pH were 60°C and 7.5, respectively. The results indicated that the enzymatic activity was inhibited by enzyme inhibitors or detergents, such as ethylene diamine tetraacetic acid, citrate, dithiothreitol, β-mercaptoethanol, guanidine hydrochloride, urea and SDS. In contrast, the nuclease activity was enhanced by TritonX-100, Tween-20 or chaps to approximately 124.5% – 141.6%. The K_m of GBSV1-NSN nuclease was 231, 61 and 92 μM, while its k_cat was 1278, 241 and 300 s^-1 for the cleavage of dsDNA, ssDNA and RNA, respectively.

Conclusion

Our study, therefore, presented a novel thermostable non-specific nuclease from thermophilic bacteriophage and its overexpression and purification for scientific research and applications.

Expression of nuclease gene nucA, a member of an operon putatively involved in uracil removal from DNA and its subsequent reuse in Prevotella bryantii

The genomic region of Prevotella bryantii TC1-1 that conferred an increased nucleolytic activity on Escherichia coli was characterized. It contains two divergent transcriptional units separated by an AT-rich promoter region. One unit is comprised of three genes involved in nucleotide metabolism. nucA, the first gene of this unit, whose product belongs to exonuclease/endonuclease/phosphatase Pfam family, was thought to be required for the increased nucleolytic activity and various expression strategies were employed to confirm its role. The nucA expression was only successful in cell free system where DNase and RNase activity was observed. Two genes downstream of nucA code for a putative uracil DNA glycosylase and uridine kinase which could be involved in the removal of misincorporated uracil from DNA and its reuse. Given that apurinic/apyrimidinic nuclease activity is required after uracil removal from DNA, it was somewhat surprising to find out that nucA, whose product belongs to protein family consisting mostly of apurinic/apyrimidinic nucleases, has no apurinic/apyrimidinic activity.

Studies on Prevotella nuclease using a system for the controlled expression of cloned genes in P. bryantii TC1-1

Available tools for genetic analysis in the anaerobic rumen bacterium Prevotella bryantii are limited to only two known systems for gene delivery, and no genes, with the exception of plasmid maintenance and selection genes, have been successfully expressed from plasmids in any species of the genus Prevotella until now. It is shown here that nucB, a newly cloned nuclease gene from P. bryantii, can be controllably expressed from shuttle vector pRH3 in P. bryantii strain TC1-1, depending on the tetracycline concentration in the growth medium. nucB expression is also growth-medium dependent and this regulation presumably takes place at the translational level. His-tagged NucB was purified from P. bryantii TC1-1 culture supernatant and was shown to degrade DNA as well as RNA; it is most likely a minor 36 kDa P. bryantii non-specific nuclease.

The relevance of gene transfer to the safety of food and feed derived from genetically modified (GM) plants

In 2000, the thematic network ENTRANSFOOD was launched to assess four different topics that are all related to the testing or assessment of food containing or produced from genetically modified organisms (GMOs). Each of the topics was linked to a European Commission (EC)-funded large shared cost action (see http://www.entransfood.com). Since the exchange of genetic information through horizontal (lateral) gene transfer (HGT) might play a more important role, in quantity and quality, than hitherto imagined, a working group dealing with HGT in the context of food and feed safety was established. This working group was linked to the GMOBILITY project (GMOBILITY, 2003) and the results of the deliberations are laid down in this review paper. HGT is reviewed in relation to the potential risks of consuming food or feed derived from transgenic crops. First, the mechanisms for obtaining transgenic crops are described. Next, HGT mechanisms and its possible evolutionary role are described. The use of marker genes is presented in detail as a special case for genes that may pose a risk. Furthermore, the exposure to GMOs and in particular to genetically modified (GM) deoxyribonucleic acid (DNA) is discussed as part of the total risk assessment. The review finishes off with a number of conclusions related to GM food and feed safety. The aim of this paper is to provide a comprehensive overview to assist risk assessors as well as regulators and the general public in understanding the safety issues related to these mechanisms.

Systematics and evolution of ruminal species of the genus Prevotella

Bacterial species of the genus Prevotella represent a numerically dominant microbial population in the rumen of cattle. They belong to the phylogenetic division Cytophaga-Flexibacter-Bacteroides (CFB) which is a large group of ecologically diverse bacteria with only a few shared traits. The phylogenetic descent from a common ancestor seems to be unquestionable, however, as judged from the small subunit ribosomal RNA analysis. Only 4 ruminal Prevotella species have been described to date, even though the sequence analysis of directly retrieved 16S rRNA genes indicates a large genetic diversity within this group of rumen bacteria. The closest relatives of ruminal Prevotella spp. are not surprisingly other species of the genus Prevotella, typically inhabiting the gastrointestinal tract, oral cavity and genital areas of other animals and man. The previous phylogenetic analysis showed that species of the genus Prevotella can be split into two groups or superclusters, the "ruminal" and the "non-ruminal prevotellas". One of 4 currently described ruminal Prevotella spp., i.e. P. albensis, has been placed outside the supercluster containing ruminal Prevotella spp. and within the supercluster containing the non-ruminal Prevotella spp. However, the number of available small subunit rRNA sequences from this species represents only a fraction of all known ruminal Prevotella sequences.

The bacteriophages of ruminal prevotellas

Rumen bacteriophage-lyzed bacterial strains of the genus Prevotella were isolated and preliminarily characterized. The strain TCl-1 the species P. bryantii was the only prevotella strain successfully infected with filter sterilized rumen fluid from a black-and-white Holstein cow. Two types of plaques were observed, both rather small and turbid. Preliminary electron microscopy observation showed that several morphologically different bacteriophages were present in these plaques. The plaque eluates were further used for the infection of other prevotella strains. The plaques produced by the bacteriophages were observed with two strains, i.e. P. bryantii B(1)4 and P. brevis GA33. The bacteriophages from both strains were examined by transmission electron microscopy and several morphologically different bacteriophages were observed, among others also a large virion with an icosahedral head with the diameter of approximately 120 nm. The bacteriophage was identified in plaques of bacterial cells of the strain GA33 and has an approximately 800 nm long helical tail, which places it among the largest ruminal bacteriophages described to date. Other bacteriophages from the same indicator strain as well as from P. bryantii B(1)4 strain were smaller and tail structures were not observed in all of them.