Stepwise cloning and genetic organization of the seemingly unclonable HgiCII restriction-modification system from Herpetosiphon giganteus strain Hpg9, using PCR technique

Functional roles of the conserved threonine 250 in the target recognition domain of HhaI DNA methyltransferase

DNA cytosine-5-methyltransferase HhaI recognizes the GCGC sequence and flips the inner cytosine out of DNA helix and into the catalytic site for methylation. The 5'-phosphate of the flipped out cytosine is in contact with the conserved Thr-250 from the target recognition domain. We have produced 12 mutants of Thr-250 and examined their methylation potential in vivo. Six active mutants were subjected to detailed biochemical and structural studies. Mutants with similar or smaller side chains (Ser, Cys, and Gly) are very similar to wild-type enzyme in terms of steady-state kinetic parameters k(cat), K(m)(DNA), K(m)(AdoMet). In contrast, the mutants with bulkier side chains (Asn, Asp, and His) show increased K(m) values for both substrates. Fluorescence titrations and stopped-flow kinetic analysis of interactions with duplex oligonucleotides containing 2-aminopurine at the target base position indicate that the T250G mutation leads to a more polar but less solvent-accessible position of the flipped out target base. The x-ray structure of the ternary M. HhaI(T250G).DNA.AdoHcy complex shows that the target cytosine is locked in the catalytic center of enzyme. The space created by the mutation is filled by water molecules and the adjacent DNA backbone atoms dislocate slightly toward the missing side chain. In aggregate, our results suggest that the side chain of Thr-250 is involved in constraining the conformation the DNA backbone and the target base during its rotation into the catalytic site of enzyme.

Evidence of horizontal transfer of the EcoO109I restriction-modification gene to Escherichia coli chromosomal DNA

A DNA fragment carrying the genes coding for EcoO109I endonuclease and EcoO109I methylase, which recognize the nucleotide sequence 5'-(A/G)GGNCC(C/T)-3', was cloned from the chromosomal DNA of Escherichia coli H709c. The EcoO109I restriction-modification (R-M) system was found to be inserted between the int and psu genes from satellite bacteriophage P4, which were lysogenized in the chromosome at the P4 phage attachment site of the corresponding leuX gene observed in E. coli K-12 chromosomal DNA. The sid gene of the prophage was inactivated by insertion of one copy of IS21. These findings may shed light on the horizontal transfer and stable maintenance of the R-M system.

Sequence comparison of the EcoHK31I and EaeI restriction-modification systems suggests an intergenic transfer of genetic material

The genes coding for the EcoHK31I and EaeI restriction-modification (R-M) systems from Escherichia coli strain HK31 and Enterobacter aerogenes, respectively, have been cloned and sequenced. Both ENases recognize and cleave Y/GGCCR leaving 4 nucleotide 5'-protruding ends, while the MTases modify the internal cytosine. The systems were isolated on a 2.3kb AseI fragment for EcoHK31I, and a 4.6 kb HindIII fragment for EaeI. The R and M genes of both systems converge and overlap by 14 nucleotides. Previously, we found that M.EcoHK31I consisted of two subunits, (alpha and beta), with the beta subunit being translated from an alternative open reading frame within the gene encoding the alpha subunit. Sequence comparison between the EcoHK31I and EaeI systems reveals striking similarity. The eaeIM gene also encodes alpha and beta polypeptides of 309 and 176 amino acids which share 96% and 97% identity, respectively, with those of ecoHK31IM. ecoHK31IR and eaeIR encode proteins of 318 and 315 aa, respectively, which share 92% identity but are otherwise unique in the GenBank database. The EaeI and the EcoHK31I R-M systems were found to be flanked by genes coding for integrases. It is possible that these integrases have facilitated the transfer of this system among different bacterial species.

Cloning and characterization of the gene encoding PspPI methyltransferase from the Antarctic psychrotroph Psychrobacter sp. strain TA137. Predicted interactions with DNA and organization of the variable region

The gene (pspPIM) encoding the PspPI DNA methyltransferase (MTase) associated with the PspPI restriction-modification (R-M) system (5'-GGNCC-3') of Psychrobacter species TA137 has been cloned and expressed in E. coli, and its nucleotide (nt) sequence has been determined. The coding region was 1248 nt in length and capable of specifying a 46826-Da protein of 416 amino acids (aa). The predicted sequence of the MTase protein displays ten sequence motifs characteristic of all prokaryotic m5C-MTases and shows the highest similarity to other MTases that methylate the GGNCC sequence, namely M . Eco47II and M . Sau96I. All three MTases methylate the internal cytosine within their recognition sequence. Sequence similarities between M . PspPI and its isospecific M . Eco47II and M . Sau96I as well as with four other m5C-MTases that methylate the related GGWCC sequence, namely M . SinI, M . HgiCII, M . HgiBI, M . HgiEI have been also found within the variable region of these proteins. On the basis of structural information from M . HhaI and M . HaeIII, several M . PspPI residues that are expected to interact with DNA can be predicted. Furthermore, an organization of the variable region of m5C-MTases into two segments exhibiting a pattern of conserved residues and a considerable degree of structural homologies is described.

Organization and gene expression within restriction-modification systems of Herpetosiphon giganteus

We have characterized a family of related restriction-modification (R-M) systems from the soil bacterium Herpetosiphon giganteus (Hgi). A comparison of their genetic organization reveals two types of regulatory proteins, called controlling ORF C. While one of these small reading frames derived from RM.HgiCI seems to be an enhancer of its own promoter, evidence is provided for a silencer function of the other ORF C derived from the closely related AvaII-type systems RM.HgiBI/CII/EI. The respective silencer function is detected during our various attempts to clone three isoschizomers with unusually high differences in their specific activity. Sequencing and site-directed mutagenesis revealed just two amino acids as being responsible for a massive increase in specific activity of these endonucleases.

PCR-directed preparation and single-step purification of highly active histidine-tagged restriction endonuclease HgiBI (GGWCC)

The polymerase chain reaction was used to produce His6 fusion proteins via deletion of an intervening piece of DNA. The generally applicable method was performed using a standard primer with the advantage that the fusion does not produce additional amino acids. In a single-step purification highly purified, enzymatically active restriction endonuclease was obtained.

Sequence similarity among type-II restriction endonucleases, related by their recognized 6-bp target and tetranucleotide-overhang cleavage

The type-II restriction endonucleases (ENases) EcoRI (recognition sequence G decreases AATTC), RsrI (G decreases AATTC), XcyI (C decreases CCGGG), Cfr9I (C decreases CCGGG) and MunI (C decreases AATTG), all cleave hexanucleotide palindromic sequences, leaving tetranucleotide 5'-overhangs. Two regions of similarity that appear in the same order and relative position were identified among the amino-acid sequences of ENases. These regions map to the structural elements of EcoRI involved in the building of the catalytic site and in interactions with the central nucleotides of the recognized sequence. We propose that these ENases might all share a similar structural organization of the active site and structural motifs involved in interactions with specific DNA recognition sequences.

PCR directed preparation and single step purification of highly active histidine-tagged restriction endonuclease HgiBI (GGWCC)

The polymerase-chain-reaction technique is used to produce fusion proteins via deletion of any intervening piece of DNA. Here a stretch of six histidine codons is fused to the 3'-terminus of any defined gene using a standard plasmid vector or a derivative thereof. The advantage over existing methods is that no other amino acids besides the six histidines are added to the protein terminus and only one oligonucleotide needs to be synthesized as special primer. Genes of interest must only be cloned in the correct orientation into a universal multilinker. Using just one specific primer derived from the 3'-terminus of the gene and one standard primer derived from the six histidine codons the fusion is performed by amplifying the entire vector system as described for inverse PCR. As an example, we report on the modification and purification of the restriction endonuclease HgiBI (GGWCC). Enzymatically active protein was obtained in a single step purification under nondenaturating conditions with a purity greater than 95% according to polyacrylamide gel electrophoresis.

Effect of site-specific modification on restriction endonucleases and DNA modification methyltransferases

Restriction endonucleases have site-specific interactions with DNA that can often be inhibited by site-specific DNA methylation and other site-specific DNA modifications. However, such inhibition cannot generally be predicted. The empirically acquired data on these effects are tabulated for over 320 restriction endonucleases. In addition, a table of known site-specific DNA modification methyltransferases and their specificities is presented along with EMBL database accession numbers for cloned genes.

The NlaIV restriction and modification genes of Neisseria lactamica are flanked by leucine biosynthesis genes

The genes encoding the Neisseria lactamica restriction endonuclease IV (R.NlaIV) and its cognate DNA methyltransferase (M.NlaIV), both of which recognize the sequence GGNNCC, have been cloned in Escherichia coli and overexpressed using the T7 polymerase/promoter system. Analysis of a sequenced 3.58 kb fragment established the gene order, leuD-M.NlaIV-R.NlaIV-leuB. The predicted primary sequence of M.NlaIV (423 amino acids) shows the highest degree of identity to a pair of cytosine-specific methyltransferases, M.BanI (44.9%) and M.HgiCI (44.3%), which recognize the sequence GGYRCC (Y, pyrimidines; R, purines). In contrast, the R.NlaIV protein sequence (243 amino acids) is unique in the existing data-base, a situation that holds for most endonucleases. Flanking the NlaIV modification and restriction genes are homologues of the leuD and leuB genes of enteric bacteria, which code for enzymes in the leucine biosynthesis pathway. This gene context implies a possible new mode of gene regulation for the RM.NlaIV system, which would involve a mechanism similar to the recently discovered leucine/Lrp regulon in E. coli.

The DNA (cytosine-5) methyltransferases

The m5C-MTases form a closely-knit family of enzymes in which common amino acid sequence motifs almost certainly translate into common structural and functional elements. These common elements are located predominantly in a single structural domain that performs the chemistry of the reaction. Sequence-specific DNA recognition is accomplished by a separate domain that contains recognition elements not seen in other structures. This, combined with the novel and unexpected mechanistic feature of trapping a base out of the DNA helix, makes the m5C-MTases an intriguing class of enzymes for further study. The reaction pathway has suddenly become more complicated because of the base-flipping and much remains to be learned about the DNA recognition elements in the family members for which structural information is not yet available.