Conservation of complex DNA recognition domains between families of restriction enzymes

One polypeptide, designated S, confers sequence-specificity to the multisubunit type I restriction enzymes. Two families of such enzymes, K and A, include members that recognize diverse, bipartite, target sequences. The S polypeptides of the K family, while having areas of near identity, also contain two extensive regions of variable sequence. We now show that one of these, comprising the N-terminal 150 amino acids, specifies recognition of one component of the bipartite target sequence. We have determined the sequence recognized by EcoE, a member of the A family. This sequence, 5'GAG(N7)ATGC, has the trinucleotide GAG in common with EcoA and with StySB of the K family. We determined the nucleotide sequences of the S genes of EcoA and EcoE, and compared their predicted amino acid sequences with each other and with those of the five members of the K family. There is no general sequence similarity between families, but the domain of the S polypeptide of StySB, which specifies GAG, shows nearly 50 per cent identity with the amino variable region of the S polypeptides of EcoA and EcoE. A complex domain that recognizes and directs methylation of GAG is therefore common to enzymes of generally dissimilar amino acid sequence.     

Type I Restriction–Modification Loci Reveal High Allelic Diversity in Clinical Helicobacter pylori Isolates

Background: A remarkable variety of restriction‐modification (R‐M) systems is found in Helicobacter pylori. Since they encompass a large portion of the strain‐specific H. pylori genes and therefore contribute to genetic variability, they are suggested to have an impact on disease outcome. Type I R‐M systems comprise three different subunits and are the most complex of the three types of R‐M systems. Aims: We investigated the genetic diversity and distribution of type I R‐M systems in clinical isolates of H. pylori. Material and methods: Sixty‐one H. pylori isolates from a Swedish hospital based case‐control study and 6 H. pylori isolates of a Swedish population‐based study were analyzed using polymerase chain reaction for the presence of the three R‐M systems' subunits. Representative gene variants were sequenced. Results: Although the hsdM and hsdR genes appeared conserved in our clinical H. pylori isolates, the sequences of the hsdS loci were highly variable. Despite their sequence diversity, the genes per se were present at high frequencies. We identified a number of novel allelic hsdS variants, which are distinct from corresponding hsdS loci in the sequenced H. pylori strains 26695, J99 and HPAG1. In analyses of paired H. pylori isolates, obtained from the same individuals with a 4‐year interval, we observed genetic modifications of hsdS genes in patients with atrophic gastric mucosa. Discussion: We propose that the genetic variability of hsdS genes in a bacterial population will give rise to new specificities of these enzymes, which might lead to adaptation to an ever‐changing gastric environment.     

Genomic Subtraction Recovers Rye-Specific DNA Elements Enriched in the Rye Genome

Repetitive DNA sequence families have been identified in methylated relic DNAs of rye. This study sought to isolate rye genome-specific repetitive elements regardless of the level of methylation, using a genomic subtraction method. The total genomic DNAs of rye-chromosome-addition-wheat lines were cleaved to short fragments with a methylation-insensitive 4-bp cutter, MboI, and then common DNA sequences between rye and wheat were subtracted by annealing with excess wheat genomic DNA. Four classes of rye-specific repetitive elements were successfully isolated from both the methylated and non-methylated regions of the genome. Annealing of the DNA mixture at a ratio of the enzyme-restricted fragments:the sonicated fragments (1:3–1:5) was key to this success. Two classes of repetitive elements identified here belong to representative repetitive families: the tandem 350-family and the dispersed R173 family. Southern blot hybridization patterns of the two repetitive elements showed distinct fragments in methylation-insensitive EcoO109I digests, but continuous smear signals in the methylation-sensitive PstI and SalI digests, indicating that both of the known families are contained in the methylated regions. The subtelomeric tandem 350-family is organized by multimers of a 380-bp-core unit defined by the restriction enzyme EcoO109I. The other two repetitive element classes had new DNA sequences (444, 89 bp) and different core-unit sizes, as defined by methylation-sensitive enzymes. The EcoO109I recognition sites consisting of PyCCNGGPu-multi sequences existed with high frequency in the four types of rye repetitive families and might be a useful tool for studying the genomic organization and differentiation of this species.     

KpnBI is the prototype of a new family (IE) of bacterial type I restriction-modification system

KpnBI is a restriction-modification (R-M) system recognized in the GM236 strain of Klebsiella pneumoniae. Here, the KpnBI modification genes were cloned into a plasmid using a modification expression screening method. The modification genes that consist of both hsdM (2631 bp) and hsdS (1344 bp) genes were identified on an 8.2 kb EcoRI chromosomal fragment. These two genes overlap by one base and share the same promoter located upstream of the hsdM gene. Using recently developed plasmid R-M tests and a computer program RM Search, the DNA recognition sequence for the KpnBI enzymes was identified as a new 8 nt sequence containing one degenerate base with a 6 nt spacer, CAAANNNNNNRTCA. From Dam methylation and HindIII sensitivity tests, the methylation loci were predicted to be the italicized third adenine in the 5′ specific region and the adenine opposite the italicized thymine in the 3′ specific region. Combined with previous sequence data for hsdR, we concluded that the KpnBI system is a typical type I R-M system. The deduced amino acid sequences of the three subunits of the KpnBI system show only limited homologies (25 to 33% identity) at best, to the four previously categorized type I families (IA, IB, IC, and ID). Furthermore, their identity scores to other uncharacterized putative genome type I sequences were 53% at maximum. Therefore, we propose that KpnBI is the prototype of a new ‘type IE’ family.     

Conservation of organization in the specificity polypeptides of two families of type I restriction enzymes

We have identified the recognition sequence for the Citrobacter freundii restriction endonuclease CfrA, a member of the A-family of type I R-M enzymes. This bipartite target sequence differs in both its components from those of other type I enzymes. We determined the nucleotide sequence of its specificity gene (hsdS) and a comparison of this with its relative EcoA identifies two extensive variable regions, an organization analogous to that found in the K-family of type I R-M enzymes. The specificity polypeptides of the A-family, unlike those of K, have an N-terminal conserved region, and this includes a sequence repeated within the central conserved region. A second repeat sequence, identified at the amino acid level, coincides with the only sequence similarity common to all type I S polypeptides. Sequences immediately downstream from the hsdS genes of EcoA, CfrA, EcoK, B and D are almost identical, consistent with an allelic chromosomal location.     

Gene structure and molecular analysis of the laccase-like multicopper oxidase (LMCO) gene family in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis>

Completed genome sequences have made it clear that multicopper oxidases related to laccase are widely distributed as multigene families in higher plants. Laccase-like multicopper oxidase (LMCO) sequences culled from GenBank and the Arabidopsis thaliana genome, as well as those from several newly cloned genes, were used to construct a gene phylogeny that clearly divided plant LMCOs into six distinct classes, at least three of which predate the evolutionary divergence of angiosperms and gymnosperms. Alignments of the predicted amino acid sequences highlighted regions of variable sequence flanked by the highly conserved copper-binding domains that characterize members of this enzyme family. All of the predicted proteins contained apparent signal sequences. The expression of 13 of the 17 LMCO genes in A. thaliana was assessed in different tissues at various stages of development using RT-PCR. A diversity of expression patterns was demonstrated with some genes being expressed in a constitutive fashion, while others were only expressed in specific tissues at a particular stage of development. Only a few of the LMCO genes were expressed in a pattern that could be considered consistent with a major role for these enzymes in lignin deposition. These results are discussed in the context of other potential physiological functions for plant LMCOs, such as iron metabolism and wound healing.     

Construction of a bacterial artificial chromosome library containing large Eco RI and Hin dIII genomic fragments of lettuce

 Existing bacterial artificial chromosome (BAC) vectors were modified to have unique EcoRI cloning sites. This provided an additional site for generating representative libraries from genomic DNA digested with a variety of enzymes. A BAC library of lettuce was constructed following the partial digestion of genomic DNA with HindIII or EcoRI. Several experimental parameters were investigated and optimized. The BAC library of over 50,000 clones, representing one to two genome equivalents, was constructed from six ligations; average insert sizes for each ligation varied between 92.5 and 142 kb with a combined average insert size of 111 kb. The library was screened with markers linked to disease resistance genes; this identified 134 BAC clones from four regions containing resistance genes. Hybridization with low-copy genomic sequences linked to resistance genes detected fewer clones than expected from previous estimates of genome size. The lack of hybridization to chloroplast and mitochondrial sequences demonstrated that the library was predominantly composed of nuclear DNA. The unique EcoRI site in the BAC vector should allow the integration of BAC cloning with other technologies that utilize EcoRI digestion, such as AFLP^TM markers and RecA-assisted restriction endonuclease (RARE) cleavage, to clone specific large EcoRI fragments from genomic DNA. Received: 5 August 1996 / Accepted: 23 August 1996     

Overproduction of the hsd subunits leads to the loss of temperature-sensitive restriction and modification phenotype

The geneshsdM andhsdS for M.EcoKI modification methyltrasferase and the complete set ofhsdR,hsdM andhsdS genes coding for R.EcoKI restriction endonuclease, both with and without a temperature-sensitive (ts) mutation inhsdS gene, were cloned in pBR322 plasmid and introduced intoE. coli C (a strain without a natural restriction-modification (R-M) system). The strains producing only the methyltransferase, or together with the endonuclease, were thus obtained. ThehsdS _ts-1 mutation, mapped previously in the distal variable region of thehsdS gene with C^{1 245}-T transition has no effect on the R-M phenotype expressed from cloned genes in bacteria grown at 42°C. In clones transformed with the wholehsd region an alleviation of R-M functions was observed immediately after the transformation, but after subculture the transformants expressed the wild-type R-M phenotype irrespective of whether the wild-type or the mutanthsdS allele was present in the hybrid plasmid. Simultaneous overproduction of HsdS and HsdM subunits impairs the ts effect of thehsdS _ts-1 mutation on restriction and modification.     

EcoA and EcoE: alternatives to the EcoK family of type I restriction and modification systems of Escherichia coli

The genes (hsd A) encoding EcoA, a restriction and modification system first identified in Escherichia coli 15T-, behave in genetic crosses as alleles of the genes (hsd K) encoding the archetypal type I restriction and modification system of E. coli K12. Nevertheless, molecular experiments have failed to detect relatedness between the A and K systems. We have cloned the hsd A genes and have identified, on the basis of DNA homology, related genes (hsd E) conferring a new specificity to a natural isolate of E. coli. We show that the overall organization of the genes encoding EcoA and EcoE closely parallels that for EcoK. Each enzyme is encoded by three genes, of which only one, hsdS, confers the specificity of DNA interaction. The three genes are in the same order as those encoding EcoK, i.e. hsdR, hsdM and hsdS and, similarly, they include a promoter between hsdR and hsdM from which the M and S genes can be transcribed. The evidence indicates that EcoA and EcoE are type I restriction and modification enzymes, but they appear to identify an alternative family to EcoK. For both families, the hsdR polypeptide is by far the largest, but the sizes of the other two polypeptides are reversed, with the smallest polypeptide of EcoK being the product of hsd S, and the smallest for the EcoA family being the product of hsdM. Physiologically, the A restriction and modification system differs from that of K and its relatives, in that A-specific methylation of unmodified DNA is particularly effective.     

Study of restriction fragment length polymorphisms at the human phenylalamine hydroxylase locus and evaluation of its potential application in prenatal diagnosis of phenylketonuria in Chinese

Summary Using a human phenylalanine hydroxylase cDNA probe, the restriction fragment length polymorphisms at the human phenylalanine hydroxylase locus have been determined with the restriction enzymes BglII, PvuII, EcoRI+BamHI, MspI, XmnI, HindIII and EcoRV. The frequency of the observed heterozygosity of the restriction site polymorphisms at this locus in a Chinese population is approximately 54%, which is significantly lower than that in Caucasians. No DNA rearrangement or deletion of the phenylalanine hydroxylase locus was detected among mutant phenylalanine hydroxylase genes in seven Chinese classical phenylketonuria (PKU) families. Haplotype analysis of these seven families revealed that the mutant alleles belonged to five different haplotypes, i.e. haplotype 4, 11 and three unreported haplotypes. The majority of normal and mutant phenylalanine hydroxylase genes are confined to hyplotype 4. These results indicate that approximately 42% of Chinese PKU families are informative for prenatal diagnosis of PKU when eight restriction sites linked to the phenylalanine hydroxylase locus are examined.     

Complete Sequence and Enhancer Function of the Homologous DNA Regions of Autographa californica Nuclear Polyhedrosis Virus

The nucleotide sequence of the five regions of homologous DNA in the genome of Autographa californica nuclear polyhedrosis virus DNA was determined. The homology of repeated sequences within a region was 65 to 87%, and the consensus sequences for each region were 88% homologous to each other. Sequences proximal to the EcoRI sites were most conserved, while the distal sequences were least conserved. The EcoRI sites formed the core of a 28-base-pair imperfect inverted repeat. All homologous regions functioned as enhancers in a transient expression assay. A single EcoRI minifragment located between EcoRI-Q and -L enhanced the expression of 39CAT as efficiently as the regions containing numerous EcoRI repeats did.     

The EcoDXX1 restriction and modification system: Cloning the genes and homology to type I restriction and modification systems

The Escherichia coli plasmid pDXX1 codes for a type I restriction and modification system, EcoDXX1. A 15.5-kb BamHI fragment from pDXX1 has been cloned and contains the hsdR, hsdM, and hsdS genes that encode the EcoDXX1 system. The EcoDXX1 hsd genes can complement the gene products of the EcoR124 and EcoR124/3 hsd systems, but not those of EcoK and Ecob. Hybridization experiments using EcoDXX1 hsd genes as a probe demonstrate homology between EcoDXX1 and EcoR124 and EcoR124/3 restriction-modification systems, but weak or no homology between EcoDXX1 and EcoK or EcoB systems.     

Families of restriction enzymes: an analysis prompted by molecular and genetic data for type ID restriction and modification systems

Current genetic and molecular evidence places all the known type I restriction and modification systems of Escherichia coli and Salmonella enterica into one of four discrete families: type IA, IB, IC or ID. StySBLI is the founder member of the ID family. Similarities of coding sequences have identified restriction systems in E.coli and Klebsiella pneumoniae as probable members of the type ID family. We present complementation tests that confirm the allocation of EcoR9I and KpnAI to the ID family. An alignment of the amino acid sequences of the HsdS subunits of StySBLI and EcoR9I identify two variable regions, each predicted to be a target recognition domain (TRD). Consistent with two TRDs, StySBLI was shown to recognise a bipartite target sequence, but one in which the adenine residues that are the substrates for methylation are separated by only 6 bp. Implications of family relationships are discussed and evidence is presented that extends the family affiliations identified in enteric bacteria to a wide range of other genera.     

Applicability of multigene family-specific antibodies toward studies of the subtilases in Arabidopsis thaliana

Polyclonal antibodies were made to two synthetic peptides with sequences patterned after conserved regions in a multigene family of 56 subtilisin-related proteolytic enzymes in Arabidopsis thaliana. GST-fusion proteins encompassing full-length or partial cDNAs bearing putative epitope regions were cloned and expressed in Escherichia coli. Immunoblots showed that the antibodies bound 12 of 13 fusion proteins tested. About 27 more subtilase genes code for regions with sequences very similar to the epitope regions of the subtilases that were visualized on the immunoblots. Subtilases in rosette and cauline leaves, stems, flowers, and siliques could be distinguished by the antibodies; some binding the two antibodies to similar extents, while others bind preferentially or almost exclusively to one or the other antibody. When antibodies were used to monitor ion-exchange fractionation of seedling extracts, one specific subtilase was identified by LC-MS-MS. The specificity of the antibodies extended to subtilases in soybean. These studies show that multigene family-specific antibodies can be applied to the study of gene families, where sequence similarities make it difficult to produce antibodies specific for each individual protein in the group.     

Five-stranded β-sheet sandwiched with two α-helices: A structural link between restriction endonucleases EcoRI and EcoRV

Examination of crystal structures of restriction endonucleases EcoRI and EcoRV complexes with their cognate DNA revealed a common structural element, which forms the core of both proteins. This element consists of a five-stranded β-sheet and two α-helices packed against it and could be described as α–β sandwich in which helices and β-strands lie in two stacked layers. While the spatial structure of this α–β sandwich is conserved in both enzymes, there are no detectable similarities between amino acid sequences except of a few residues involved in active site formation. Probably, other restriction endonucleases which have similar organization of the active site might possess similar structural element regardless of DNA sequence recognized and recognition elements in the enzyme used. © 1994 Wiley-Liss, Inc.     

Plant Photoreceptors: Phylogenetic Overview

Plants possess photoreceptors to perceive light which controls most aspects of their lives. Three photoreceptor families are well characterized: cryptochromes (crys), phototropins (phots), and phytochromes (phys). Two putative families have been identified more recently: Zeitlupes (ZTLs) and UV-B photoreceptors (ULI). Using Arabidopsis thaliana and Oryza sativa photoreceptor sequences as references, we have searched for photoreceptor encoding genes in the major phyla of plant kingdom. For each photoreceptor family, using a phylogenetic tree based on the alignment of conserved amino acid sequences, we have tried to trace back the evolution and the emergence of the diverse photoreceptor ancestral sequences. The green alga Chlamydomonas contains one cry and one phot sequence, probably close to the corresponding ancestral sequences, and no phy-related sequence. The putative UV-B photoreceptors seem to be restricted to the Brassicacae. Except for mosses and ferns, which contain divergent photoreceptor numbers, the composition of the diverse photoreceptor families is conserved between species. A high conservation of the residues within domains is observed in each photoreceptor family. The complete phylogenic analysis of the photoreceptor families in plants has confirmed the existence of crucial evolutionary nodes between the major phyla. For each photoreceptor class, a major duplication occurred before the separation between Mono- and Eudicotyledons. This allowed postulating on the putative ancestral function of the photoreceptors. [Reviewing Editor: Dr. Rudiger Cerff]     

Two different satellite DNAs in Beta vulgaris L.: evolution,quantification and distribution in the genus

Summary Two highly repeated EcoRI (0.45 × 10⁶) and BamHI (0.17 × 10⁶) fragments per haploid genome were found in sugar beet genomic DNA. Both fragments were located by 6% acrylamide-gel electrophoresis, purified and cloned in pUC18. Four of the inserts corresponding to each family were chosen for further study. Both fragment families display the main characteristics of the satellite DNA of animals and plants. The EcoRI and BamHI fragment families are arranged in long tandem arrays. Fragments of the EcoRI family (pBVE) were analyzed. They vary both in sequence and in length (158–160 nt) in comparison with the consensus sequence of 159nt. Both families are A-T rich; pBVE is 59% rich while pBVB is 69% rich. The BVESAT family is present in all the members of the section Vulgares. It is conserved in the section Procumbentes with 80% homology and the same length, but is not detectable in the Corollinae. The sequence variation rate and the variation in length (330±5 nt) are of the same order in comparison with those of the BVESAT family. However, the BVBSAT family is present in species of the section Vulgares only. As regards other plant satellite DNAs, the BVESAT family shares homology with Allium cepa satellite DNA, with three of the yeast centromeric sequences, and with three Arabidopsis thaliana sequences. The BVBSAT family is unique to the Vulgares and does not share any homology with other plant or animal satellite DNAs sequences so far.     

The construction in vitro of transducing derivatives of phage lambda

Summary Methods are described for the construction of plaque-forming, transducing derivatives of phage lambda, using appropriate receptor genomes and fragments of DNA generated by the restriction enzymes endo R.EcoRI and endo R.HindIII. The general properties of the transducing derivatives are described and discussed. Plaque-forming phages carrying the E. coli trp, his, cysB, thyA, supD, supE, supF, hsd, tna and lig genes have been isolated.