The type I restriction endonuclease R.EcoR124I: over-production and biochemical properties.

In this paper we describe a two-plasmid system which allows over-production of the R.EcoR124I restriction endonuclease. The endonuclease has been purified to homogeneity in milligram amounts and has been shown to be fully active for both restriction and modification. Unexpectedly, the enzyme was found to require only ATP and Mg2+ for ATPase activity and DNA cleavage; S-adenosyl methionine (SAM), which has been described as a cofactor of type I restriction enzymes, is not required by R.EcoR124I. However, SAM was found to stimulate the rate of ATPase activity and DNA cleavage. This may occur through an increase in specific DNA binding by R.EcoR124I in the presence of SAM, as indicated by our surface plasmon resonance experiments. These functional differences from the well described R.EcoKI restriction endonuclease are reflected in a possible structural difference between the two enzymes, namely that the stoichiometry of R.EcoR124I appears to be R1M2S1 while that of R.EcoKI is R2M2S1. Supercoiled DNA with one or two SR124I recognition sites is cleaved by the same mechanism inferring co-operation between specifically bound and excess enzymes. Nicked-circle DNA is an intermediate of cleavage reaction. Cleavage of DNA was inhibited by an increased degree of negative supercoiling, which may reflect an increased difficulty for the enzyme to translocate the DNA. Hemi-methylated DNA was the preferred substrate for methylation.

A novel mutant of the type I restriction-modification enzyme EcoR124I is altered at a key stage of the subunit assembly pathway.

The HsdS subunit of a type I restriction-modification (R-M) system plays an essential role in the activity of both the modification methylase and the restriction endonuclease. This subunit is responsible for DNA binding, but also contains conserved amino acid sequences responsible for protein-protein interactions. The most important protein-protein interactions are those between the HsdS subunit and the HsdM (methylation) subunit that result in assembly of an independent methylase (MTase) of stoichiometry M(2)S(1). Here, we analysed the impact on the restriction and modification activities of the change Trp(212)-->Arg in the distal border of the central conserved region of the EcoR124I HsdS subunit. We demonstrate that this point mutation significantly influences the ability of the mutant HsdS subunit to assemble with the HsdM subunit to produce a functional MTase. As a consequence of this, the mutant MTase has drastically reduced DNA binding, which is restored only when the HsdR (restriction) subunit binds with the MTase. Therefore, HsdR acts as a chaperon allowing not only binding of the enzyme to DNA, but also restoring the methylation activity and, at sufficiently high concentrations in vitro of HsdR, restoring restriction activity.

Deletions within the DNA recognition subunit of M.EcoR124I that identify a region involved in protein-protein interactions between HsdS and HsdM.

The DNA recognition subunit (HsdS) of type I restriction endonucleases can be divided into domains by means of amino acid identity between subunits from the same family. It has been proposed that DNA-protein interactions occur within the variable domains of the subunit and that protein-protein interactions involve the conserved domains. We have constructed a number of deletion mutants of HsdS that have allowed us to investigate protein-protein interactions. Using a combination of a "competitive" complementation assay and the ability of HsdM to "solubilize" HsdS, we have defined a region within the central conserved domain of HsdS that is responsible for HsdS-HsdM interaction. Computer analysis of amino acid identity between the N-terminal half and the C-terminal half of HsdS identifies a region (repeated in both conserved domains), one copy of which overlaps the region we have identified as essential for HsdS-HsdM interactions, which may be responsible for such protein-protein interactions.

Selection of non-specific DNA cleavage sites by the type IC restriction endonuclease EcoR124I.

The Type IC restriction endonuclease EcoR124I binds specifically to its recognition sequence but subsequently translocates non-specific DNA past the complex in an ATP-dependent mechanism. The enzyme thus has the potential to cleave DNA at loci distant from the recognition site. We have scrutinised the link between translocation and cleavage on linear and circular DNA substrates. On linear DNA carrying two recognition sites, the majority of cleavages at loci distant from the recognition site occurred between the two sites, regardless of the inter-site distance or relative orientations. On circular DNA carrying one site, distant cleavages occurred throughout the DNA but an equivalent linear molecule underwent considerably fewer cleavages at distant loci. These results agree with published models for DNA tracking. However, on every molecule investigated, discrete cleavage sites were also observed within +/-250 bp of the recognition sites. The localised cleavages were not confined to particular DNA sequences and were independent of DNA topology. We propose a model to account for both distant and localised cleavage events. The conformation of the DNA loop extruded during tracking may result in two DNA segments being held in proximity to the restriction moiety on the protein, one close to the EcoR124I site and another distant from the site: cleavage may occur in either segment. Alternatively, the cutting of DNA close to recognition sites may be the result of multiple nicks being generated in the expanding loop before any extensive translocation.

Probing the domain structure of the type IC DNA methyltransferase M.EcoR124I by limited proteolysis.

Limited proteolysis has been used to probe the domain structure of the type I DNA methyltransferase M.EcoR124I. Trypsin digestion of the methyltransferase generates two fragments derived from the HsdS subunit, a 28 kDa N-terminal domain and a 19 kDa C-terminal domain, leaving the HsdM subunit intact. Extensive digestion by chymotrypsin, however, removes 59 amino acid residues from the N terminus of the HsdM subunit to leave a 52 kDa C-terminal domain. Binding of the cofactor S-adenosyl methionine has no appreciable effect on the rate of cleavage, but binding of a 30 bp DNA duplex containing the cognate recognition sequence confers almost total protection. Following trypsin cleavage of the methyltransferase, a stable proteolytic product is produced which has been purified for biochemical characterisation. The trypsinised enzyme is shown to be a multimeric complex containing two intact HsdM subunits and both fragments of the HsdS subunit, consistent with the circular model proposed for the organisation of domains in the specificity subunit in type IC methyltransferases. Gel retardation studies show that the proteolysed enzyme still retains DNA binding activity, but its specificity for the DNA recognition sequence is dramatically reduced.

Mutation in the specificity polypeptide of the type I restriction endonuclease R.EcoK that affects subunit assembly.

We describe the isolation and characterization of a temperature-sensitive mutation within the hsdS gene of the type I restriction and modification system EcoK. This mutation appears to affect the ability of the HsdR subunit to interact with the HsdS subunit when forming an active endonuclease. We discuss the possibility that this mutant, together with another mutation described previously, may define a discontinuous domain, involved in protein-protein interactions, within the HsdS polypeptide.

Basis for changes in DNA recognition by the EcoR124 and EcoR124/3 type I DNA restriction and modification enzymes.

EcoR124 and EcoR124/3 are type I DNA restriction and modification systems. The EcoR124/3 system arose from the EcoR124 system some 15 years ago and at the electron microscopic DNA heteroduplex level the genes for both systems are still apparently identical. We have shown that the DNA sequences recognized by the two systems are GAA(N6)RTCG for EcoR124 and GAA(N7)RTCG for EcoR124/3. The sequences thus differ only in the length of the non-specific spacer. This difference nevertheless places the two specific domains of the EcoR124/3 recognition sequence 0.34 nm further apart and rotates them 36 degrees with respect to those of EcoR124, which implies major structural differences in the proteins recognizing these sequences. We have now determined the nucleotide sequences of the hsdS and hsdM genes of both systems and of the hsdR gene of EcoR124/3. The hsdS gene products provide DNA sequence specificity in both restriction and modification, the hsdM gene products are necessary for modification and all three hsd gene products are required for restriction. The only difference that we have detected between the two systems is that a 12 base-pair sequence towards the middle of the hsdS gene is repeated twice in the EcoR124 gene and three times in the EcoR124/3 gene. We have deleted one of the repeats in the EcoR124/3 gene and shown that this changes the specificity to that of EcoR124. Thus, the extra four amino acids in the middle of the EcoR124/3 hsdS gene product, which in an alpha-helical configuration would extend 0.6 nm, are sufficient to explain the differences in sequence recognition. We suggest that the EcoR124/3 system was generated by an unequal crossing over and argue that this kind of specificity change should not be rare in Nature.

High-level expression of the cloned genes encoding the subunits of and intact DNA methyltransferase, M.EcoR124.

We have cloned the genes coding for the two subunits (HsdM and HsdS) of the type-I DNA methyltransferase (MTase), M.EcoR124, into the specially constructed expression vector, pJ119. These subunits have been synthesized together as an intact MTase. We have also cloned the individual subunit-encoding genes under the control of the T7 gene 10 promoter or the lacUV5 promoter. High levels of expression have been obtained in all cases. While HsdM was found to be soluble, HsdS was insoluble. However, in the presence of the co-produced HsdM subunit, HsdS was found in the soluble fraction as part of an active MTase. We have partially purified the cloned multi-subunit enzyme and shown that it is capable of DNA methylation both in vivo and in vitro.

Two temperature-sensitive mutations in the DNA binding subunit of EcoKI with differing properties.

Two temperature-sensitive mutations in the hsdS gene, which encodes the DNA specificity subunit of the type IA restriction-modification system EcoKI, designated Sts1 (Ser(340)Phe) and Sts2 (Ala(204)Thr) had a different impact on restriction-modification functions in vitro and in vivo. The enzyme activities of the Sts1 mutant were temperature-sensitive in vitro and were reduced even at 30 degrees C (permissive temperature). Gel retardation assays revealed that the Sts1 mutant had significantly decreased DNA binding, which was temperature-sensitive. In contrast the Sts2 mutant did not show differences from the wild-type enzyme even at 42 degrees C. Unlike the HsdSts1 subunit, the HsdSts2 subunit was not able to compete with the wild-type subunit in assembly of the restriction enzyme in vivo, suggesting that the Sts2 mutation affects subunit assembly. Thus, it appears that these two mutations map two important regions in HsdS subunit responsible for DNA-protein and protein-protein interactions, respectively.

Breast uptake of Ga-67 in a neonate.

A 6-day-old baby boy showed concentration of Ga-67 citrate in both breasts and an abdominal neuroblastoma. The breast uptake was most likely caused by estrogen and prolactin production and passage from the maternal to the fetal circulation.

Restriction endonucleases R.EcoKI and R.EcoR124I are probably located in different environments within the bacterial cell.

We describe the phenomenon of a transient state of R124I restriction deficiency after long-term storage of the E. coli[pCP1005] strain at 4 degrees C, or after growth of the culture in synthetic M9 medium with the nonmutagenic solvent dimethyl sulfoxide. The unusual high reversion from the R+ 124 to the R- 124 phenotype was observed only in E. coli strain transformed with the high-copy number plasmid pCP1005 carrying EcoR124I hsdR, M and S genes cloned, but not with strains carrying the natural conjugative plasmid R124. The effect of both treatments on the expression of EcoR124I phenotype in relation to the possible location of R.EcoR124I restriction endonuclease in E. coli is discussed.

Characterization of an EcoR124I restriction-modification enzyme produced from a deleted form of the DNA-binding subunit, which results in a novel DNA specificity.

We purified and characterized both the methyltransferase and the endonuclease containing the HsdS delta 50 subunit (type I restriction endonucleases are composed of three subunits--HsdR required for restriction, HsdM required for methylation and HsdS responsible for DNA recognition) produced from the deletion mutation hsdS delta 50 of the type IC R-M system EcoR 124I; this mutant subunit lacks the C-terminal 163 residues of HsdS and produces a novel DNA specificity. Analysis of the purified HsDs delta 50 subunit indicated that during purification it is subject to partial proteolysis resulting in removal of approximately 1 kDa of the polypeptide at the C-terminus. This proteolysis prevented the purification of further deletion mutants, which were determined as having a novel DNA specificity in vivo. After biochemical characterization of the mutant DNA methyltransferase (MTase) and restriction endonuclease we found only one difference comparing with the wild-type enzyme--a significantly higher binding affinity of the MTase for the two substrates of hemimethylated and fully methylated DNA. This indicates that MTase delta 50 is less able to discriminate the methylation status of the DNA during its binding. However, the mutant MTase still preferred hemimethylated DNA as the substrate for methylation. We fused the hsdM and hsdS delta 50 genes and showed that the HsdM-HsdS delta 50 fusion protein is capable of dimerization confirming the model for assembly of this deletion mutant.

Isolation of a non-classical mutant of the DNA recognition subunit of the type I restriction endonuclease R.EcoR124I.

We have used deletion mutagenesis and PCR-based misincorporation mutagenesis to produce a collection of mutations in the central conserved region of the DNA binding subunit of the type IC restriction endonuclease EcoR124I. It has been proposed that this domain is involved in protein-protein interactions during the assembly of the endonuclease. While a large percentage of these mutations gave a classical Res- Mod- phenotype, one mutant was isolated with a nonclassical Res- Mod+ phenotype. The loss of restriction activity, but retention of the ability to modify indicates that this mutation cannot affect DNA binding and must alter the assembly of the endonuclease in such a way as to prevent DNA cleavage but allow methylation. This mutant resulted from a single amino acid change Trp212-->Arg. The location of the single amino acid change is at the border of the central conserved region and the second target recognition domain (TRD2) and suggests that this region is extremely important for the assembly of the methylase with the HsdR subunit into a functional restriction endonuclease.

Measuring motion on DNA by the type I restriction endonuclease EcoR124I using triplex displacement.

The type I restriction enzyme EcoR124I cleaves DNA following extensive linear translocation dependent upon ATP hydrolysis. Using protein-directed displacement of a DNA triplex, we have determined the kinetics of one-dimensional motion without the necessity of measuring DNA or ATP hydrolysis. The triplex was pre-formed specifically on linear DNA, 4370 bp from an EcoR124I site, and then incubated with endonuclease. Upon ATP addition, a distinct lag phase was observed before the triplex-forming oligonucleotide was displaced with exponential kinetics. As the distance between type I and triplex sites was shortened, the lag time decreased whilst the displacement reaction remained exponential. This is indicative of processive DNA translocation followed by collision with the triplex and oligonucleotide displacement. A linear relationship between lag duration and inter-site distance gives a translocation velocity of 400+/-32 bp/s at 20 degrees C. Furthermore, the data can only be explained by bi-directional translocation. An endonuclease with only one of the two HsdR subunits responsible for motion could still catalyse translocation. The reaction is less processive, but can 'reset' in either direction whenever the DNA is released.

Value of sonography including color Doppler in the diagnosis and management of long standing intussusception.

15 cases of intussusception with presenting symptoms of more than 24 h duration were studied by sonography and Doppler. The aim of the study was to determine the validity of the sonographic criteria of peritonitis and bowel ischaemia in order to reduce the risk of colonic perforation and to increase confidence in achieving a successful hydrostatic reduction. The results were reviewed retrospectively and cases divided into 2 groups. Cases in group 1 were reducible by barium enema while those in group 2 required surgical intervention. Sonographic features of peritonitis were absent in all cases of group 1 and 3 cases of group 2. These 3 cases were reduced manually at surgery while the other 5 cases in group 2 with positive features of peritonitis required bowel resection. Blood flow was documented by colour flow Doppler in all cases except the 3 cases with gangrenous bowel in group 2. When sonographic features of peritonitis and loss of blood flow to the intussusception are present in late intussusception, surgical intervention is required. On the other hand, enema reduction should be pursued when such features are absent.

Ultrasound of intussusception with lead points.

Ultrasonography of 4 cases of intussusception in children with proven lead points were reviewed retrospectively. The lead points were due to lymphosarcoma, inverted Meckel's diverticulum, jejunal polyps and an inverted appendiceal stump. The lead points form a complex mass in the centre of the intussusception in both transverse and longitudinal sections, distinct from primary intussusception. The presence of such ultrasonographic findings are suggestive of secondary intussusception with a lead point and surgical reduction rather than hydrostatic reduction should be considered.

Localization of the type I restriction-modification enzyme EcoKI in the bacterial cell.

To localise the type I restriction-modification (R-M) enzyme EcoKI within the bacterial cell, the Hsd subunits present in subcellular fractions were analysed using immunoblotting techniques. The endonuclease (ENase) as well as the methylase (MTase) were found to be associated with the cytoplasmic membrane. HsdR and HsdM subunits produced individually were soluble, cytoplasmic polypeptides and only became membrane-associated when coproduced with the insoluble HsdS subunit. The release of enzyme from the membrane fraction following benzonase treatment indicated a role for DNA in this interaction. Trypsinization of spheroplasts revealed that the HsdR subunit in the assembled ENase was accessible to protease, while HsdM and HsdS, in both ENase and MTase complexes, were fully protected against digestion. We postulate that the R-M enzyme EcoKI is associated with the cytoplasmic membrane in a manner that allows access of HsdR to the periplasmic space, while the MTase components are localised on the inner side of the plasma membrane.

The EcoR124 and EcoR124/3 restriction and modification systems: cloning the genes.

The Escherichia coli plasmid R124 codes for a type I restriction and modification system EcoR124 and carries genetic information, most probably in the form of a "silent copy," for the expression of a different R-M specificity R124/3. Characteristic DNA rearrangements have been shown to accompany the switch in specificity from R124 to R124/3 and vice versa. We have cloned a 14.2-kb HindIII fragment from R124 and shown that it contains the hsdR, hsdM, and hsdS genes which code for the EcoR124 R-M system. An equivalent fragment from the plasmid R124/3 following the switch in R-M specificity has also been cloned and shown to contain the genes coding for the EcoR124/3 R-M system. These fragments, however, lack a component present on the wild-type plasmid essential for the switch in specificity. Restriction fragment maps and preliminary heteroduplex analysis indicate the near identity of the genes that encode the two different DNA recognition specificities. Transposon mutagenesis was used to locate the positions of the hsdR, hsdM, and hsdS genes on the cloned fragments in conjunction with complementation tests for gene function. Indirect evidence indicates that hsdR is expressed from its own promoter and that hsdM and hsdS are expressed from a single promoter, unidirectionally.

Indonesian type of metaphyseal dysplasia.

The authors describe two Indonesian siblings affected by a hitherto undocumented form of metaphyseal dysplasia that simulates enchondromatosis. The notable clinical features were short stature and lateral bowing of the lower extremities. These features were readily recognizable at birth. The radiographic examinations showed that the metaphyseal anomalies were localized predominantly in the lower extremities, the hip joints being the most severely affected. The upper extremities showed only minimal abnormalities. The name "Indonesian type of metaphyseal dysplasia" is suggested for this autosomal recessive bone disorder.

Purification and biochemical characterisation of the EcoR124 type I modification methylase.

Large scale purification of the type I modification methylase EcoR124 has been achieved from an over-expressing strain by a two step procedure using ion-exchange and heparin chromatography. Pure methylase is obtained at a yield of 30 mg per gm of cell paste. Measurements of the molecular weight and subunit stoichiometry show that the enzyme is a trimeric complex of 162 kDa consisting of two subunits of HsdM (58 kDa) and one subunit of HsdS (46 kDa). The purified enzyme can methylate a DNA fragment bearing its cognate recognition sequence. Binding of the methylase to synthetic DNA fragments containing either the EcoR124 recognition sequence GAAN6RTCG, or the recognition sequence GAAN7RTCG of the related enzyme EcoR124/3, was followed by fluorescence competition assays and by gel retardation analysis. The results show that the methylase binds to its correct sequence with an affinity of the order 10(8) M-1 forming a 1:1 complex with the DNA. The affinity for the incorrect sequence, differing by an additional base pair in the non-specific spacer, is almost two orders of magnitude lower.