Molecular Mechanisms of hsdS Inversions in the cod Locus of Streptococcus pneumoniae.

Streptococcus pneumoniae (pneumococcus), a major human pathogen, is well known for its adaptation to various host environments. Multiple DNA inversions in the three DNA methyltransferase hsdS genes (hsdSA, hsdSB, and hsdSC) of the colony opacity determinant (cod) locus generate extensive epigenetic and phenotypic diversity. However, it is unclear whether all three hsdS genes are functional and how the inversions mechanistically occur. In this work, our transcriptional analysis revealed active expression of hsdSA but not hsdSB and hsdSC, indicating that hsdSB and hsdSC do not produce functional proteins and instead act as sources for altering the sequence of hsdSA by DNA inversions. Consistent with our previous finding that the hsdS inversions are mediated by three pairs of inverted repeats (IR1, IR2, and IR3), this study showed that the 15-bp IR1 and its upstream sequence are strictly required for the inversion between hsdSA and hsdSB Furthermore, a single tyrosine recombinase PsrA catalyzes the inversions mediated by IR1, IR2, and IR3, based on the dramatic loss of these inversions in the psrA mutant. Surprisingly, PsrA-independent inversions were also detected in the hsdS sequences flanked by the IR2 (298 bp) and IR3 (85 bp) long inverted repeats, which appear to occur spontaneously in the absence of site-specific or RecA-mediated recombination. Because the HsdS subunit is responsible for the sequence specificity of type I restriction modification DNA methyltransferase, these results have revealed that S. pneumoniae varies the methylation patterns of the genome DNA (epigenetic status) by employing multiple mechanisms of DNA inversion in the cod locus.IMPORTANCEStreptococcus pneumoniae is a major pathogen of human infections with the capacity for adaptation to host environments, but the molecular mechanisms behind this phenomenon remain unclear. Previous studies reveal that pneumococcus extends epigenetic and phenotypic diversity by DNA inversions in three methyltransferase hsdS genes of the cod locus. This work revealed that only the hsdS gene that is in the same orientation as hsdM is actively transcribed, but the other two are silent, serving as DNA sources for inversions. While most of the hsdS inversions are catalyzed by PsrA recombinase, the sequences bound by long inverted repeats also undergo inversions via an unknown mechanism. Our results revealed that S. pneumoniae switches the methylation patterns of the genome (epigenetics) by employing multiple mechanisms of DNA inversion.

A rapid purification procedure for the HsdM protein of EcoR124I and biophysical characterization of the purified protein.

Type I restriction-modification (R-M) systems are comprised of two multi-subunit enzymes with complementary functions: the methyltransferase (~160 kDa), responsible for methylation of DNA, and the restriction endonuclease (~400 kDa), responsible for DNA cleavage. Both enzymes share a number of subunits, including HsdM. Characterisation of either enzyme first requires the expression and purification of its constituent subunits, before reconstitution of the multisubunit complex. Previously, purification of the HsdM protein had proved problematic, due to the length of time required for the purification and its susceptibility to degradation. A new protocol was therefore developed to decrease the length of time required to purify the HsdM protein and thus prevent degradation. Finally, we show that the HsdM subunit exhibits a concentration dependent monomer-dimer equilibrium.

Understanding key features of bacterial restriction-modification systems through quantitative modeling.

BACKGROUND: Restriction-modification (R-M) systems are rudimentary bacterial immune systems. The main components include restriction enzyme (R), which cuts specific unmethylated DNA sequences, and the methyltransferase (M), which protects the same DNA sequences. The expression of R-M system components is considered to be tightly regulated, to ensure successful establishment in a naïve bacterial host. R-M systems are organized in different architectures (convergent or divergent) and are characterized by different features, i.e. binding cooperativities, dissociation constants of dimerization, translation rates, which ensure this tight regulation. It has been proposed that R-M systems should exhibit certain dynamical properties during the system establishment, such as: i) a delayed expression of R with respect to M, ii) fast transition of R from "OFF" to "ON" state, iii) increased stability of the toxic molecule (R) steady-state levels. It is however unclear how different R-M system features and architectures ensure these dynamical properties, particularly since it is hard to address this question experimentally. RESULTS: To understand design of different R-M systems, we computationally analyze two R-M systems, representative of the subset controlled by small regulators called 'C proteins', and differing in having convergent or divergent promoter architecture. We show that, in the convergent system, abolishing any of the characteristic system features adversely affects the dynamical properties outlined above. Moreover, an extreme binding cooperativity, accompanied by a very high dissociation constant of dimerization, observed in the convergent system, but absent from other R-M systems, can be explained in terms of the same properties. Furthermore, we develop the first theoretical model for dynamics of a divergent R-M system, which does not share any of the convergent system features, but has overlapping promoters. We show that i) the system dynamics exhibits the same three dynamical properties, ii) introducing any of the convergent system features to the divergent system actually diminishes these properties. CONCLUSIONS: Our results suggest that different R-M architectures and features may be understood in terms of constraints imposed by few simple dynamical properties of the system, providing a unifying framework for understanding these seemingly diverse systems. We also provided predictions for the perturbed R-M systems dynamics, which may in future be tested through increasingly available experimental techniques, such as re-engineering R-M systems and single-cell experiments.

[Restriction endonucleases: the detection of new producer strains and the isolation of enzyme preparations]. / Endonukleazy restriktsii: vyiavlenie novykh shtammov produtsentov i poluchenie fermentnykh preparatov.

The method for analysis of microorganisms for the presence of the modification-restriction systems has been developed. The method has permitted to detect more than 10 new producing strains of restrictases including microorganisms of Rhizobium genus. Some of them are promising for practical use. It has been shown that using selection of clones the strain productivity can be increased. The purification process for the majority of restrictases has been proposed. Some physical and catalytic properties of new enzymes have been studied.

Expression and characterisation of the N-terminal fragment of the HsdS subunit of M.EcoR124I.

The type IC modification methyltransferase M.EcoR124I is a trimeric enzyme of 162 kDa consisting of two copies of the modification subunit, HsdM, and a single DNA specificity subunit, HsdS. Studies to date have been largely restricted to the HsdM subunit or the intact methyltransferase, since the HsdS subunit is insoluble when expressed independently of HsdM. Using PCR, we have cloned and expressed 13 fragments of the gene for the HsdS subunit, including the sequences encoding each of the variable and conserved domains and various combinations of these. Only two of these fragments were found to be soluble, a 8.6 kDa fragment (S11) comprising the central conserved domain and a 25 kDa N-terminal fragment (S3) containing the N-terminal variable domain and the central conserved domain. Analysis of the larger of these fragments by gel retardation shows that the protein binds DNA in the presence of HsdM at a subunit stoichiometry of 1:1. Gel filtration and CD spectroscopy indicate that the protein is monomeric and predominantly alpha-helical.

Cloning and nucleotide sequences of the AccI restriction-modification genes in Acinetobacter calcoaceticus.

The genes of the AccI restriction-modification system specific for GT(A/C) (G/T)AC were cloned from the chromosomal DNA of Acinetobacter calcoaceticus, and their nucleotides sequenced. The restriction and modification genes coded for polypeptides with calculated molecular weights of 42,494 and 63,078, respectively. Both the enzymes were coded by the same DNA strand and the restriction gene was upstream of the methylase gene, separated by 2 bp. The restriction gene was significantly expressed in E. coli cells, so that the AccI restriction endonuclease could be purified to homogeneity. Analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and gel filtration indicated that the catalytically active form of the endonuclease was tetrameric. Sequence comparison with related enzymes indicated that AccI methylase contained a segment of tetra-amino acids, NPPY, characteristic of N6-adenine methylases. In addition, some homologous regions were found in the sequence of HincII methylase specific for GT(C/T) (A/G)AC.