The McrBC restriction endonuclease assembles into a ring structure in the presence of G nucleotides.

McrBC from Escherichia coli K-12 is a restriction enzyme that belongs to the family of AAA(+) proteins and cuts DNA containing modified cytosines. Two proteins are expressed from the mcrB gene: a full-length version, McrB(L), and a short version, McrB(S). McrB(L) binds specifically to the methylated recognition site and is, therefore, the DNA-binding moiety of the McrBC endonuclease. McrB(S) is devoid of DNA-binding activity. We observed that the quaternary structure of the endonuclease depends on binding of the cofactors. In gel filtration experiments, McrB(L) and McrB(S) form high molecular weight oligomers in the presence of Mg(2+) and GTP, GDP or GTP-gamma-S. Oligomerization did not require the presence of DNA and was independent of GTP hydrolysis. Electron micrographs of negatively stained McrB(L) and McrB(S) revealed ring-shaped particles with a central channel. Mass analysis by scanning transmission electron microscopy indicates that McrB(L) and McrB(S) form single heptameric rings as well as tetradecamers. In the presence of McrC, a subunit that is essential for DNA cleavage, the tetradecameric species was the major form of the endonuclease.

Subunit assembly and mode of DNA cleavage of the type III restriction endonucleases EcoP1I and EcoP15I.

DNA cleavage by type III restriction endonucleases requires two inversely oriented asymmetric recognition sequences and results from ATP-dependent DNA translocation and collision of two enzyme molecules. Here, we characterized the structure and mode of action of the related EcoP1I and EcoP15I enzymes. Analytical ultracentrifugation and gel quantification revealed a common Res(2)Mod(2) subunit stoichiometry. Single alanine substitutions in the putative nuclease active site of ResP1 and ResP15 abolished DNA but not ATP hydrolysis, whilst a substitution in helicase motif VI abolished both activities. Positively supercoiled DNA substrates containing a pair of inversely oriented recognition sites were cleaved inefficiently, whereas the corresponding relaxed and negatively supercoiled substrates were cleaved efficiently, suggesting that DNA overtwisting impedes the convergence of the translocating enzymes. EcoP1I and EcoP15I could co-operate in DNA cleavage on circular substrate containing several EcoP1I sites inversely oriented to a single EcoP15I site; cleavage occurred predominantly at the EcoP15I site. EcoP15I alone showed nicking activity on these molecules, cutting exclusively the top DNA strand at its recognition site. This activity was dependent on enzyme concentration and local DNA sequence. The EcoP1I nuclease mutant greatly stimulated the EcoP15I nicking activity, while the EcoP1I motif VI mutant did not. Moreover, combining an EcoP15I nuclease mutant with wild-type EcoP1I resulted in cutting the bottom DNA strand at the EcoP15I site. These data suggest that double-strand breaks result from top strand cleavage by a Res subunit proximal to the site of cleavage, whilst bottom strand cleavage is catalysed by a Res subunit supplied in trans by the distal endonuclease in the collision complex.

Methyl-specific DNA binding by McrBC, a modification-dependent restriction enzyme.

McrBC, a GTP-requiring, modification-dependent endonuclease of Escherichia coli K-12, specifically recognizes DNA sites of the form 5' R(m)C 3'. DNA cleavage normally requires translocation-mediated coordination between two such recognition elements at distinct sites. We have investigated assembly of the cleavage-competent complex with gel-shift and DNase I footprint analysis. In the gel-shift system, McrB(L) binding resulted in a fast-migrating specific shifted band, in a manner requiring both GTP and Mg(2+). The binding was specific for methylated DNA and responded to local sequence changes in the same way that cleavage does. Single-stranded DNA competed for McrB(L)-binding in a modification and sequence-specific fashion. A supershifted species was formed in the presence of McrC and GTPgammaS. DNase I footprint analysis showed modest cooperativity in binding to two sites, and a two-site substrate displayed protection in non-specific spacer DNA in addition to the recognition elements. The addition of McrC did not affect the footprint obtained. We propose that McrC effects a conformational change in the complex rather than a reorganization of the DNA:protein interface.

DNA supercoiling during ATP-dependent DNA translocation by the type I restriction enzyme EcoAI.

Type I restriction enzymes cleave DNA at non-specific sites far from their recognition sequence as a consequence of ATP-dependent DNA translocation past the enzyme. During this reaction, the enzyme remains bound to the recognition sequence and translocates DNA towards itself simultaneously from both directions, generating DNA loops, which appear to be supercoiled when visualised by electron microscopy. To further investigate the mechanism of DNA translocation by type I restriction enzymes, we have probed the reaction intermediates with DNA topoisomerases. A DNA cleavage-deficient mutant of EcoAI, which has normal DNA translocation and ATPase activities, was used in these DNA supercoiling assays. In the presence of eubacterial DNA topoisomerase I, which specifically removes negative supercoils, the EcoAI mutant introduced positive supercoils into relaxed plasmid DNA substrate in a reaction dependent on ATP hydrolysis. The same DNA supercoiling activity followed by DNA cleavage was observed with the wild-type EcoAI endonuclease. Positive supercoils were not seen when eubacterial DNA topoisomerase I was replaced by eukaryotic DNA topoisomerase I, which removes both positive and negative supercoils. Furthermore, addition of eukaryotic DNA topoisomerase I to the product of the supercoiling reaction resulted in its rapid relaxation. These results are consistent with a model in which EcoAI translocation along the helical path of closed circular DNA duplex simultaneously generates positive supercoils ahead and negative supercoils behind the moving complex in the contracting and expanding DNA loops, respectively. In addition, we show that the highly positively supercoiled DNA generated by the EcoAI mutant is cleaved by EcoAI wild-type endonuclease much more slowly than relaxed DNA. This suggests that the topological changes in the DNA substrate associated with DNA translocation by type I restriction enzymes do not appear to be the trigger for DNA cleavage.

The McrBC endonuclease translocates DNA in a reaction dependent on GTP hydrolysis.

McrBC specifically recognizes and cleaves methylated DNA in a reaction dependent on GTP hydrolysis. DNA cleavage requires at least two recognition sites that are optimally separated by 40-80 bp, but can be spaced as far as 3 kb apart. The nature of the communication between two recognition sites was analyzed on DNA substrates containing one or two recognition sites. DNA cleavage of circular DNA required only one methylated recognition site, whereas the linearized form of this substrate was not cleaved. However, the linearized substrate was cleaved if a Lac repressor was bound adjacent to the recognition site. These results suggest a model in which communication between two remote sites is accomplished by DNA translocation rather than looping. A mutant protein with defective GTPase activity cleaved substrates with closely spaced recognition sites, but not substrates where the sites were further apart. This indicates that McrBC translocates DNA in a reaction dependent on GTP hydrolysis. We suggest that DNA cleavage occurs by the encounter of two DNA-translocating McrBC complexes, or can be triggered by non-specific physical obstacles like the Lac repressor bound on the enzyme's path along DNA. Our results indicate that McrBC belongs to the general class of DNA "motor proteins", which use the free energy associated with nucleoside 5'-triphosphate hydrolysis to translocate along DNA.

Single amino acid substitutions in the HsdR subunit of the type IB restriction enzyme EcoAI uncouple the DNA translocation and DNA cleavage activities of the enzyme.

Type I restriction enzymes bind to specific DNA sequences but subsequently translocate non-specific DNA past the complex in a reaction coupled to ATP hydrolysis and cleave DNA at any barrier that can halt the translocation process. The restriction subunit of these enzymes, HsdR, contains a cluster of seven amino acid sequence motifs typical of helicase superfamily II, that are believed to be relevant to the ATP-dependent DNA translocation. Alignment of all available HsdR sequences reveals an additional conserved region at the protein N-terminus with a consensus sequence reminiscent of the P-D.(D/E)-X-K catalytic motif of many type II restriction enzymes. To investigate the role of these conserved residues, we have produced mutants of the type IB restriction enzyme Eco AI. We have found that single alanine substitutions at Asp-61, Glu-76 and Lys-78 residues of the HsdR subunit abolished the enzyme's restriction activity but had no effect on its ATPase and DNA translocation activities, suggesting that these residues are part of the active site for DNA cleavage.

DNA translocation blockage, a general mechanism of cleavage site selection by type I restriction enzymes.

Type I restriction enzymes bind to a specific DNA sequence and subsequently translocate DNA past the complex to reach a non-specific cleavage site. We have examined several potential blocks to DNA translocation, such as positive supercoiling or a Holliday junction, for their ability to trigger DNA cleavage by type I restriction enzymes. Introduction of positive supercoiling into plasmid DNA did not have a significant effect on the rate of DNA cleavage by EcoAI endonuclease nor on the enzyme's ability to select cleavage sites randomly throughout the DNA molecule. Thus, positive supercoiling does not prevent DNA translocation. EcoR124II endonuclease cleaved DNA at Holliday junctions present on both linear and negatively supercoiled substrates. The latter substrate was cleaved by a single enzyme molecule at two sites, one on either side of the junction, consistent with a bi-directional translocation model. Linear DNA molecules with two recognition sites for endonucleases from different type I families were cut between the sites when both enzymes were added simultaneously but not when a single enzyme was added. We propose that type I restriction enzymes can track along a DNA substrate irrespective of its topology and cleave DNA at any barrier that is able to halt the translocation process.

Probing interactions between HIV-1 reverse transcriptase and its DNA substrate with backbone-modified nucleotides.

BACKGROUND: To gain a molecular understanding of a biochemical process, the crystal structure of enzymes that catalyze the reactions involved is extremely helpful. Often the question arises whether conformations obtained in this way appropriately reflect the reactivity of enzymes, however. Rates that characterize transitions are therefore compulsory experiments for the elucidation of the reaction mechanism. Such experiments have been performed for the reverse transcriptase of the type 1 human immunodeficiency virus (HIV-1 RT). RESULTS: We have developed a methodology to monitor the interplay between HIV-1 RT and its DNA substrate. To probe the protein-DNA interactions, the sugar backbone of one nucleotide was modified by a substituent that influenced the efficiency of the chain elongation in a characteristic way. We found that strand elongation after incorporation of the modified nucleotide follows a discontinuous efficiency for the first four nucleotides. The reaction efficiencies could be correlated with the distance between the sugar substituent and the enzyme. The model was confirmed by kinetic experiments with HIV-1 RT mutants. CONCLUSIONS: Experiments with HIV-1 RT demonstrate that strand-elongation efficiency using a modified nucleotide correlates well with distances between the DNA substrate and the enzyme. The functional group at the modified nucleotides acts as an 'antenna' for steric interactions that changes the optimal transition state. Kinetic experiments in combination with backbone-modified nucleotides can therefore be used to gain structural information about reverse transcriptases and DNA polymerases.

The DNA recognition subunit of the type IB restriction-modification enzyme EcoAI tolerates circular permutions of its polypeptide chain.

The DNA specificity subunit (HsdS) of type I restriction-modification enzymes is composed of two independent target recognition domains and several regions whose amino acid sequence is conserved within an enzyme family. The conserved regions participate in intersubunit interactions with two modification subunits (HsdM) and two restriction subunits (HsdR) to form the complete endonuclease. It has been proposed that the domains of the HsdS subunit have a circular organisation providing the required symmetry for their interaction with the other subunits and with the bipartite DNA target. To test this model, we circularly permuted the HsdS subunit of the type IB R-M enzyme EcoAI at the DNA level by direct linkage of codons for original termini and introduction of new termini elsewhere along the N-terminal and central conserved regions. By analysing the activity of mutant enzymes, two circularly permuted variants of HsdS that had termini located at equivalent positions in the N-terminal and central repeats, respectively, were found to fold into a functional DNA recognition subunit with wild-type specificity, suggesting a close proximity of the N and C termini in the native protein. The wild-type HsdS subunit was purified to homogeneity and shown to form a stable trimeric complex with HsdM, M2S1, which was fully active as a DNA methyltransferase. Gel electrophoretic mobility shift assays revealed that the HsdS protein alone was not able to form a specific complex with a 30-mer oligoduplex containing a single EcoAI recognition site. However, addition of stoichiometric amounts of HsdM to HsdS led to efficient specific DNA binding. Our data provide evidence for the circular organisation of domains of the HsdS subunit. In addition, they suggest a possible role of HsdM subunits in the formation of this structure.

McrBs, a modulator peptide for McrBC activity.

McrBC is a methylation-dependent endonuclease from Escherichia coli K-12. The enzyme recognizes DNA with modified cytosines preceded by a purine. McrBC restricts DNA that contains at least two methylated recognition sites separated by 40-80 bp. Two gene products, McrBL and McrBs, are produced from the mcrB gene and one, McrC, from the mcrC gene. DNA cleavage in vitro requires McrBL, McrC, GTP and Mg2+. We found that DNA cleavage was optimal at a ratio of 3-5 McrBL per molecule of McrC, suggesting that formation of a multisubunit complex with several molecules of McrBL is required for cleavage. To understand the role of McrBs, we have purified the protein and analyzed its role in vitro. At the optimal ratio of 3-5 McrBL per molecule of McrC, McrBs acted as an inhibitor of DNA cleavage. Inhibition was due to sequestration of McrC and required the presence of GTP, suggesting that the interaction is GTP dependent. If McrC was in excess, a condition resulting in suboptimal DNA cleavage, addition of McrBs enhanced DNA cleavage, presumably due to sequestration of excess McrC. We suggest that the role of McrBs is to modulate McrBC activity by binding to McrC.

4'-Acylated thymidine 5'-triphosphates: a tool to increase selectivity towards HIV-1 reverse transcriptase.

4'-Acylated thymidines represent a new class of DNA chain terminators, since they have been shown to act as post-incorporation chain-terminating nucleotides despite the presence of a free 3'-hydroxyl group. Here, we describe the action of the 4'-acetyl- (MeTTP) and 4'-propanoylthymidine 5'-triphosphate (EtTTP) on HIV-1 reverse transcriptase in RNA- and DNA-dependent DNA synthesis and on DNA synthesis catalyzed by the cellular DNA polymerases alpha, beta, delta and epsilon. MeTTP exhibits a high selectivity towards HIV-1 reverse transcriptase. By the use of the bulkier propanoyl group as the 4'-substituent of the nucleoside 5'-triphosphate, selectivity towards HIV-1 reverse transcriptase could be increased without affecting substrate efficiency. Thus, 4'-modifications may serve as a tool to increase selectivity towards HIV-1 reverse transcriptase.

KpnAI, a new type I restriction-modification system in Klebsiella pneumoniae.

The KpnAI restriction-modification (R-M) system has been identified in Klebsiella pneumoniae strain M5a1. The restriction gene of KpnAI was first cloned into pBR322 using an r-m+ M5a1 derivative and phage SBS for screening. Subsequently, an adjacent DNA fragment showing modification activity was cloned into pUC19. A total of 7.2 kb DNA sequencing data revealed three open reading frames, corresponding to hsdR, hsdM and hsdS genes of type I R-M systems. The predicted hsdR, hsdM and hsdS-coded peptides shared 95%, 98% and 44% identity, respectively, with the corresponding peptides of the recently identified StySBLI system, a prototype of the type ID family. This high homology suggests that KpnAI is also a member of the type ID family. The KpnAI system seems to be the first type I system identified in Klebsiella species.

The type IC hsd loci of the enterobacteria are flanked by DNA with high homology to the phage P1 genome: implications for the evolution and spread of DNA restriction systems.

EcoR124l, EcoDXXl and Ecoprrl are the known members of the type IC family of DNA restriction and modification systems. The first three are carried on large, conjugative plasmids, while Ecoprrl is chromosomally encoded. The enzymes are coded by three genes, hsdR, hsdM and hsdS. Analysis of the DNA sequences upstream and downstream of the type IC hsd loci shows that all are highly homologous to each other and also to sequences present in the bacteriophage P1 genome. The upstream sequences include functional phd and doc genes, which encode an addiction system that stabilizes the P1 prophage state, and extend to and beyond pac, the site at which phage DNA packaging begins. Downstream of the hsd loci, P1 DNA sequences begin at exactly the same place for all of the systems. For EcoDXXl and Ecoprrl the P1 homology extends for thousands of base pairs while for EcoR124l and IS1 insertion and an associated deletion have removed most of the P1-homologous sequences. The significance of these results for the evolution of DNA restriction and modification systems is discussed.

DNA cleavage by the type IC restriction-modification enzyme EcoR124II.

Type I restriction-modification systems bind to non-palindromic, bipartite recognition sequences. Although these enzymes methylate specific adenine residues within their recognition sequences, they cut DNA at sites up to several thousand base-pairs away. We have investigated the mechanism of how EcoR124II, a type IC restriction-modification system, selects the cleavage site. Restriction studies with different DNA constructs revealed that circular DNA requires only one non-methylated recognition sequence to be cut, whereas linear DNA needs at least two such sites. Cleavage of linear DNA is independent of site orientation. Further investigations of the linear substrates revealed a mechanism whereby the double-strand break is introduced between two recognition sequences. We propose a model for the selection of restriction sites by type I enzymes where two EcoR124II complexes bind to two recognition sequences. Lack of methylation at a site stimulates the enzyme to translocate DNA on both sides of the recognition sequence. Thus the two complexes approach each other and, at the point where they meet, they interact to introduce a double-strand break in the DNA.

Regulation of the activity of the type IC EcoR124I restriction enzyme.

Restriction-modification (R-M) systems must regulate the expression of their genes so that the chromosomal genome is modified at all times by the methyltransferase to protect the host cell from the potential lethal action of the cognate restriction endonuclease. Since type I R-M systems can be transferred to non-modified Escherichia coli cells by conjugation or transformation without killing the recipient, they must have some means to regulate their restriction activity upon entering a new host cell to avoid restriction of unprotected host DNA and cell death. This is especially true for EcoR124I, a type IC family member, which is coded for by a conjugative plasmid. Control of EcoR124I restriction activity is most likely at the post-translational level as the transfer of the EcoR124I system into a recipient cell that already expressed the HsdR subunit of this system was not a lethal event. Additionally, the kinetics of restriction activity upon transfer of the genes coding for the EcoR124I RM system to a recipient cell are the same, irrespective of the modification state of the recipient cell or the presence or absence of the EcoR124I HsdR subunit in the new host cells. The mechanism controlling the restriction activity of a type IC R-M system upon transfer to a new host cell is different from that controlling the chromosomally coded type IA and IB R-M systems. The previously discovered hsdC mutant, which affects the establishment of the type IA system EcoKI, was shown to affect the establishment of the type IB system EcoAI, but to have no influence on EcoR124I.

Generation of new DNA binding specificity by truncation of the type IC EcoDXXI hsdS gene.

The hsdS subunit of a type IC restriction-modification enzyme is responsible for the enzyme's DNA binding specificity. Type I recognition sites are characterized by two defined half-sites separated by a non-specific spacer of defined length. The hsdS subunit contains two independent DNA binding domains, each targeted towards one DNA half-site. We have shown previously that the 5' half of hsdS can code for a functional substitute of the full-length hsdS. Here we demonstrate that the 3' half of the gene, when fused to the appropriate transcriptional and translational start signals, also codes for a peptide which imparts DNA binding specificity to the enzyme. About half the natural hsdS size, the mutant peptide contains a single DNA recognition domain flanked by one copy of each internal repeat found in the full-length hsdS. Deletion of either repeat sequence results in loss of activity. Like the 5' hsdS mutant, the 3' mutant recognizes an interrupted palindrome, GAAYN(5)RTTC, suggesting that two truncated subunits participate in DNA recognition. Co-expression of the 5' hsdS mutant and the 3' hsdS mutant along with hsdM regenerates the wild-type methylation specificity. Thus, there is a free assortment of subunits in the cell.

ATPase activity of the type IC restriction-modification system EcoR124II.

We have investigated the ATPase activity of the type IC restriction-modification (R-M) system EcoR124II. As with all type I R-M systems EcoR 124II requires ATP hydrolysis to cut DNA. We determined the KM for ATP to be 10(-5) to 10(-4) M. By measuring ATP hydrolysis under different conditions and by simultaneously monitoring DNA restriction, methylation and ATP hydrolysis we propose that the order of events during restriction is: (1) binding of EcoR124II to a non-methylated recognition sequence, (2) start of DNA-dependent ATP hydrolysis which continues even after restriction is complete, (3) restriction of DNA, (4) methylation of the product. Non-cleavable DNA substrates, such as recognition site containing oligonucleotides, also support ATP hydrolysis. Methylation can also occur prior to ATP hydrolysis and prevent DNA degradation.

Posttranscriptional regulation of EcoP1I and EcoP15I restriction activity.

Efficient establishment of a DNA restriction-modification (R-M) system in a non-modified cell requires a tight control of the potentially lethal activity of the restriction enzyme. The type III R-M systems EcoP1I and EcoP15I can be transferred to non-modified Escherichia coli cells by transfection, conjugation or transformation and become established without difficulty. Modification activity is expressed immediately after the R-M genes enter the cell, whereas the expression of restriction activity is delayed until complete protection of the cellular DNA is achieved by methylation. We have shown by Western blot analysis that the expression of the modification polypeptide subunit positively regulates the amount of restriction subunit present in the cell. The finding that ribosomal alterations affected the expression of restriction activity pointed to additional control at the translational level. The analysis of EcoP1I expression in E. coli strains mutated in either of the ribosomal proteins S12 (rpsL) or S4 (rpsD) suggests that the level of in vivo restriction activity can be modulated both by a decrease in the efficiency of translation and by varying ribosomal accuracy conditions. In addition, we have preliminary evidence from in vivo gene fusion studies that the res gene may code for more than one gene product.

Type III restriction endonucleases translocate DNA in a reaction driven by recognition site-specific ATP hydrolysis.

Type III restriction/modification systems recognize short non-palindromic sequences, only one strand of which can be methylated. Replication of type III-modified DNA produces completely unmethylated recognition sites which, according to classical mechanisms of restriction, should be signals for restriction. We have shown previously that suicidal restriction by the type III enzyme EcoP15I is prevented if all the unmodified sites are in the same orientation: restriction by EcoP15I requires a pair of unmethylated, inversely oriented recognition sites. We have now addressed the molecular mechanism of site orientation-specific DNA restriction. EcoP15I is demonstrated to possess an intrinsic ATPase activity, the potential driving force of DNA translocation. The ATPase activity is uniquely recognition site-specific, but EcoP15I-modified sites also support the reaction. EcoP15I DNA restriction patterns are shown to be predetermined by the enzyme-to-site ratio, in that site-saturating enzyme levels elicit cleavage exclusively between the closest pair of head-to-head oriented sites. DNA restriction is blocked by Lac repressor bound in the intervening sequence between the two EcoP15I sites. These results rule out DNA looping and strongly suggest that cleavage is triggered by the close proximity of two convergently tracking EcoP15I-DNA complexes.

The Escherichia coli prr region encodes a functional type IC DNA restriction system closely integrated with an anticodon nuclease gene.

The prr locus was originally described as coding a ribonuclease that is activated after phage T4 infection to cut within the anticodon of a specific tRNA, inactivating protein synthesis and thus blocking phage development. Wild-type T4 phage has two genes coding the enzymes polynucleotide kinase and RNA ligase, whose only function seems to be to repair the damage done by the anticodon nuclease. As the only apparent function of the prr ribonuclease is to combat phage infection, it can be considered as an RNA-based restriction enzyme. In non-infected cells, the prr enzyme is kept inactive in a complex with three other proteins which were predicted on the basis of DNA homologies to be the subunits of a type IC DNA restriction and modification system. Unlike other type IC systems so far characterized, prr is chromosomally rather than plasmid coded. However, sequences upstream from prr also have homology with sequences from the plasmid R124 and the prophage P1. We have now investigated the prr system and shown that it is indeed a bona fide type IC system which we call EcoprrI, and which is active both in vivo and in vitro. The system is fully functional even in the absence of the anticodon nuclease and seems to be a typical type I enzyme. EcoprrI recognizes the sequence CCA(N7)RTGC. One peculiarity is that, with low efficiency, EcoprrI will recognize and methylate variants of its recognition sequence such as CCT(N7)ATGC, which is methylated in one strand of the DNA only.