Transposon-mediated site-specific recombination in vitro: DNA cleavage and protein-DNA linkage at the recombination site

Resolvase, the product of the tnpR gene of the transposable element gamma delta, mediates a site-specific recombination between two copies of the element directly repeated on the same replicon. The resolution site, res, at which resolvase acts lies in the intercistronic region between the tnpA and tnpR genes. We have studied this site-specific recombination in vitro. In the absence of Mg2+, a resolvase-res complex is formed, which contains DNA molecules that have been cleaved at res. Our data suggest that in this complex resolvase is covalently attached to the 5' ends of the cleaved DNA, leaving free 3' hydroxyl groups. DNA cleavage is stimulated by the interaction of two res sites on the same substrate molecule and appears to be an intermediate step in normal res site recombination. We show that the DNA is cut within a region previously identified as containing the crossover point at the palindromic sequence 5'- (see formula in text) to generate 3' extensions of two bases.     

Sites of reaction of Escherichia coli DNA gyrase on pBR322 in vivo as revealed by oxolinic acid-induced plasmid linearization

pBR322 DNA, linearized by lysis of an oxolinic acid-treated culture of Escherichia coli strain DK6recA- (pBR322) with sodium dodecyl sulfate, was purified, treated with DNA polymerase in the presence of the four deoxynucleoside triphosphates, and ligated to DNA linkers containing the XhoI recognition sequence. Most of the drug-resistant colonies resulting from transformation of E. coli with this material bore plasmids that appeared by restriction enzyme analysis to differ from pBR322 only by the introduction of an XhoI site. The XhoI sites in plasmids from 93 transformants were distributed unevenly around the pBR322 map. Maxam-Gilbert DNA sequence analysis of 36 of these plasmids, labeled at the 5' termini of the XhoI sites, revealed that 29 of them contained, in addition to the XhoI linker, a duplication of four base-pairs of the pBR322 sequence surrounding the linker. Therefore, oxolinic acid-induced linearization must have resulted in 5'-terminal extensions of four bases, the configuration known to result from oxolinic acid-induced DNA cleavage by DNA gyrase in vitro. The sequence data thus allowed the determination of the precise point at which linearization occurred, apparently by the abortion of a gyrase-DNA covalent intermediate that existed in vivo. When the 19 different sites of the 29 plasmids were compared, the following set of rules could be derived: (formula; see text) where N is any nucleotide, R is a purine, and Y is a pyrimidine. Cleavage occurred at the line between the eighth and ninth positions from the left. The parenthetical G and T were preferred secondarily to T and G, respectively, whereas T and G in the 13th position from the left were equally preferred. Several of these rules are similar to those proposed previously based on several in vitro gyrase cleavage sites. Some of our rules show dyad symmetry around the axis midway between the cleavage points in the two strands, while others are distinctly asymmetric.     

DNA gyrase can cleave short DNA fragments in the presence of quinolone drugs.

We have analysed the DNA cleavage reaction of DNA gyrase using oligonucleotides annealed to a single-stranded M13 derivative containing a preferred gyrase cleavage site. We find that gyrase can cleave duplexes down to approximately 20 bp in size in the presence of the quinolone drugs ciprofloxacin and oxolinic acid. Ciprofloxacin shows a variation in its site specificity with an apparent preference for G bases adjacent to the cleavage sites, whereas oxolinic acid stimulates cleavage predominantly at the previously determined site. With either drug, cleavage will not occur within 6 bases from the end of a DNA duplex or a nick. We suggest that cleavage site specificity with short DNA duplexes is determined by drug-DNA interactions whereas with longer fragments the positioning effect of the DNA wrap around gyrase prescribes the site of cleavage.     

DNA site recognition and reduced specificity of the Eco RI endonuclease

It has been shown previously (Polisky, B., Green, P., Garfin, D. E., McCarthy, B. J., Goodman, H. M., and Boyer, H. W. (1975) Proc. Natl. Acad. Sci. U. S. A. 72, 3310-3314; Hsu, M., and Berg, P. (1978) Biochemistry 17, 131-138) that the cleavage sequence specificity of Eco RI endonuclease can be "relaxed" by various means. In this paper this phenomenon is explored in detail, in order to obtain further insight into the nature and selectivity of sequence recognition patterns between proteins and double-stranded nucleic acids. Using conditions of low ionic strength and alkaline pH, we have mapped the positions of potentially cleavable sites in the (completely sequenced) replicative form of the bacteriophage phi X174 genome, and have deduced their sequence. The time course of digestion of phi X174 DNA suggests that double-stranded sequences reading GGATTT, AAATTT, GAATTT, and GAATTA (only "top" strands, written 5' leads to 3', are shown) are cleaved readily under these conditions, while sequences reading CAATTN (N = A, T, G) resist attack. Cleavages at (at least) the more labile sites result in cohesive ends that are religatable. End group analysis of cleaved phi X174 DNA fragments indicates the presence of a 5'-terminal adenine residue on most of the fragments; some fragments may carry a 5'-terminal guanine residue, consistent with the cleavage site sequences suggested above. Addition of Mn2+ to cleavage reactions carried out at moderate salt concentrations and near-neutral pH induces the same pattern of cleavage seen at low ionic strength and alkaline pH. These results are combined with those from other studies, and are interpreted in terms of a model for the site-specific interaction of the Eco RI endonuclease with its substrate, considering both the effects of changes in DNA sequence and of environmental alterations. The resulting model is compared with data developed on similar grounds for Eco RI methylase (see Woodbury, C. P., Downey, R. L., and von Hippel, P. H. (1980) J. Biol. Chem. 255, 11526-11533), and attempts are made to define both common and differing molecular facets of the DNA recognition specificity of these companion (but genetically distinct) enzymes.     

In vivo restriction. Sequence and structure of endonuclease II-dependent cleavage sites in bacteriophage T4 DNA.

Endonuclease II of bacteriophage T4 is required for in vivo restriction of cytosine-containing DNA from its host, Escherichia coli, (as well as from phage mutants lacking cytosine modification), normally the first step in the reutilization of host DNA nucleotides for synthesis of phage DNA in infected cells. The phage cytosine-DNA is fragmented incompletely to yield genetically defined fragments. This restriction is different from that of type I, II, or III restriction enzymes. We have located seven major endonuclease II-dependent restriction sites in the T4 genome, of which three were analyzed in detail; in addition, abundant sites were cleaved in less than or equal to 5% of all molecules. Sites I, II, and III shared the sequence 5'-CCGNNTTGGC-3' and were cleaved in about 25% (I and III) and 65% (II) of all molecules, predominantly staggered around the first or second of the central unspecified base pairs to yield fragments with one 5' base. The less frequently cleaved sites I and III deviated from site II in predicted helical structure when viewed from the consensus strand, and in sequence when viewed from the opposite strand. Thus, interaction with a particular helical structure as well as recognition of the bases in DNA appears important for efficient cleavage.     

Sequence specificity of Bacillus subtilis DNA gyrase in vivo

Linearization of pBG0 (a hydrid between Escherichia coli plasmid pBR322 and Staphylococcus aureus plasmid pUB110) was performed by lysis of the oxolinic acid treated Bacillus subtilis protoplasts with sodium dodecyl sulfate. This plasmid DNA linearization was used both for a detailed mapping of DNA gyrase cleavage sites of various strength and for the nucleotide sequence determinations at the points of gyrase-mediated scission by introducing the XhoI linker DNA. A total of 40 plasmids carrying inserted XhoI linker were sequenced by labeling 3' termini of XhoI sites; 38 of them were found to contain a duplication of four base-pairs of the plasmid sequence flanking the linker, which were characteristic of the oxolinic acid-induced DNA cleavage by E. coli DNA gyrase in vitro and in vivo. The relative strength of these sequenced sites was established by comparing their positions to the sites mapped on the appropriate plasmid genome. This allowed us to propose a consensus sequence of B. subtilis DNA gyrase in vivo cleavage site:GNAT GATCATNC% MathType!MTEF!2!1!+-% feaafeart1ev1aaatCvAUfeBSjuyZL2yd9gzLbvyNv2CaerbuLwBLn% hiov2DGi1BTfMBaeXafv3ySLgzGmvETj2BSbqefm0B1jxALjhiov2D% aebbfv3ySLgzGueE0jxyaibaiiYdd9qrFfea0dXdf9vqai-hEir8Ve% ea0de9qq-hbrpepeea0db9q8as0-LqLs-Jirpepeea0-as0Fb9pgea% 0lrP0xe9Fve9Fve9qapdbaqaaeGacaGaaiaabeqaamaabaabcaGcba% GaaeikaiaabsfacaqGPaGaaeiiaiaabccacaqGGaGaaeiiaiaabcca% caqGOaGaae4raiaabMcacaqGGaGaaeiiaiaabccacaqGGaGaaeiiai% aabccacaqGGaGaaeiiaiaabccacaqGGaGaaeiiaiaabccacaqGGaGa% aeiiaiaabccacaqGOaGaaeyqaiaabMcaaaa!4E92!\[{\rm{(T) (G) (A)}}\]where N is any nucleotide. The bases in parentheses were preferred secondarily. The involvement of DNA gyrase in illegitimate recombination events in Bacillus subtilis is discussed.     

Recognition sites of eukaryotic DNA topoisomerase I: DNA nucleotide sequencing analysis of topo I cleavage sites on SV40 DNA.

Eukaryotic DNA topoisomerase I introduces transient single-stranded breaks on double-stranded DNA and spontaneously breaks down single-stranded DNA. The cleavage sites on both single and double-stranded SV40 DNA have been determined by DNA sequencing. Consistent with other reports, the eukaryotic enzymes, in contrast to prokaryotic type I topoisomerases, links to the 3'-end of the cleaved DNA and generates a free 5'-hydroxyl end on the other half of the broken DNA strand. Both human and calf enzymes cleave SV40 DNA at the identical and specific sites. From 827 nucleotides sequenced, 68 cleavage sites were mapped. The majority of the cleavage sites were present on both double and single-stranded DNA at exactly the same nucleotide positions, suggesting that the DNA sequence is essential for enzyme recognition. By analyzing all the cleavage sequences, certain nucleotides are found to be less favored at the cleavage sites. There is a high probability to exclude G from positions -4, -2, -1 and +1, T from position -3, and A from position -1. These five positions (-4 to +1 oriented in the 5' to 3' direction) around the cleavage sites must interact intimately with topo I and thus are essential for enzyme recognition. One topo I cleavage site which shows atypical cleavage sequence maps in the middle of a palindromic sequence near the origin of SV40 DNA replication. It occurs only on single-stranded SV40 DNA, suggesting that the DNA hairpin can alter the cleavage specificity. The strongest cleavage site maps near the origin of SV40 DNA replication at nucleotide 31-32 and has a pentanucleotide sequence of 5'-TGACT-3'.     

Base mutation analysis of topoisomerase II-idarubicin-DNA ternary complex formation. Evidence for enzyme subunit cooperativity in DNA cleavage.

Antitumor drugs, such as anthracyclines, interfere with mammalian DNA topoisomerase II by forming a ternary complex, DNA-drug-enzyme, in which DNA strands are cleaved and covalently linked to the enzyme. In this work, a synthetic 36-bp DNA oligomer derived from SV40 and mutated variants were used to determine the effects of base mutations on DNA cleavage levels produced by murine topoisomerase II with and without idarubicin. Although site competition could affect cleavage levels, mutation effects were rather similar among several cleavage sites. The major sequence determinants of topoisomerase II DNA cleavage without drugs are up to five base pairs apart from the strand cut, suggesting that DNA protein contacts involving these bases are particularly critical for DNA site recognition. Cleavage sites with adenines at positions -1 were detected without idarubicin only under conditions favouring enzyme binding to DNA, showing that these sites are low affinity sites for topoisomerase II DNA cleavage and/or binding. Moreover, the results indicated that the sequence 5'-(A)TA/(A)-3' (the slash indicates the cleaved bond, parenthesis indicate conditioned preference) from -3 to +1 positions constitutes the complete base sequence preferred by anthracyclines. An important finding was that mutations that improve the fit to the above consensus on one strand can also increase cleavage on the opposite strand, suggesting that a drug molecule may effectively interact with one enzyme subunit only and trap the whole dimeric enzyme. These findings documented that DNA recognition by topoisomerase II may occur at one or the other strand, and not necessarily at both of them, and that the two subunits can act cooperatively to cleave a double helix.     

The cleavage of DNA at phosphorothioate internucleotidic linkages by DNA gyrase.

We have constructed a plasmid which contains 22 copies of a 147 bp DNA fragment which contains the major DNA gyrase cleavage site from plasmid pBR322 (located at base-pair 990). We have found that this fragment is efficiently bound and cleaved by gyrase. The selectivity for the sequence corresponding to position 990 in pBR322 is maintained even when this site is located only 15 bp from one end of the 147 bp fragment. A strategy for the specific incorporation of a single thiophosphoryl linkage into the 147 bp fragment has been developed, and gyrase has been shown to catalyse efficient cleavage of fragments bearing phosphorothioate linkages at the gyrase cleavage site in one or both strands.     

Analysis of DNA cleavage by reverse gyrase from Sulfolobus shibatae B12.

Reverse gyrase is a type I-5' topoisomerase, which catalyzes a positive DNA supercoiling reaction in vitro. To ascertain how this reaction takes places, we looked at the DNA sequences recognized by reverse gyrase. We used linear DNA fragments of its preferred substrate, the viral SSV1 DNA, which has been shown to be positively supercoiled in vivo. The Sulfolobus shibatae B12 strain, an SSV1 virus host, was chosen for production of reverse gyrase. This naturally occurring system (SSV1 DNA-S. shibatae reverse gyrase) allowed us to determine which SSV1 DNA sequences are bound and cleaved by the enzyme with particularly high selectivity. We show that the presence of ATP decreases the number of cleaved complexes obtained whereas the non-hydrolyzable ATP analog adenosine 5'-[beta, gamma-imido]triphosphate increases it without changing the sequence specificity.     

Mechanistic study of E. coli DNA topoisomerase I: cleavage of oligonucleotides.

E. coli DNA topoisomerase I catalyzes DNA topoisomerization by transiently breaking and rejoining single DNA strands (1). When an enzyme-DNA incubation mixture is treated with alkaline or detergent, DNA strand cleavage occurs, and the enzyme becomes covalently linked to the 5'-phosphoryl end of the cleaved DNA (2). Using oligonucleotides of defined length and sequence composition, this cleavage reaction is utilized to study the mechanism of E. coli DNA topoisomerase I. dA7 is the shortest oligonucleotide tested that can be cleaved by the enzyme. dT8 is the shortest oligo(dT) that can be cleaved. The site of cleavage in both cases is four nucleotides from the 3' end of the oligonucleotide. No cleavage can be observed for oligo(dC) and oligo(dG) of length up to eleven bases long. dC15 and dC16 are cleaved at one tenth or less the efficiency of oligo(dA) and oligo(dT) of comparable length.     

In the presence of subunit A inhibitors DNA gyrase cleaves DNA fragments as short as 20 bp at specific sites.

A key step in the supercoiling reaction is the DNA gyrase-mediated cleavage and religation step of double-stranded DNA. Footprinting studies suggest that the DNA gyrase binding site is 100-150 bp long and that the DNA is wrapped around the enzyme with the cleavage site located near the center of the fragment. Subunit A inhibitors interrupt this cleavage and resealing cycle and result in cleavage occurring at preferred sites. We have been able to show that even a 30 bp DNA fragment containing a 20 bp preferred cleavage sequence from the pBR322 plasmid was a substrate for the DNA gyrase-mediated cleavage reaction in the presence of inhibitors. This DNA fragment was cleaved, although with reduced efficiency, at the same sites as a 122 bp DNA fragment. A 20 bp DNA fragment was cleaved with low efficiency at one of these sites and a 10 bp DNA fragment was no longer a substrate. We therefore propose that subunit A inhibitors interact with DNA at inhibitor-specific positions, thus determining cleavage sites by forming ternary complexes between DNA, inhibitors and DNA gyrase.     

Novel symmetric and asymmetric DNA scission determinants for Streptococcus pneumoniae topoisomerase IV and gyrase are clustered at the DNA breakage site

Topoisomerase (topo) IV and gyrase are bacterial type IIA DNA topoisomerases essential for DNA replication and chromosome segregation that act via a transient double-stranded DNA break involving a covalent enzyme-DNA "cleavage complex." Despite their mechanistic importance, the DNA breakage determinants are not understood for any bacterial type II enzyme. We investigated DNA cleavage by Streptococcus pneumoniae topo IV and gyrase stabilized by gemifloxacin and other antipneumococcal fluoroquinolones. Topo IV and gyrase induce distinct but overlapping repertoires of double-strand DNA breakage sites that were essentially identical for seven different quinolones and were augmented (in intensity) by positive or negative supercoiling. Sequence analysis of 180 topo IV and 126 gyrase sites promoted by gemifloxacin on pneumococcal DNA revealed the respective consensus sequences: G(G/c)(A/t)A*GNNCt(T/a)N(C/a) and GN4G(G/c)(A/c)G*GNNCtTN(C/a) (preferred bases are underlined; disfavored bases are in small capitals; N indicates no preference; and asterisk indicates DNA scission between -1 and +1 positions). Both enzymes show strong preferences for bases clustered symmetrically around the DNA scission site, i.e. +1G/+4C, -4G/+8C, and particularly the novel -2A/+6T, but with no preference at +2/+3 within the staggered 4-bp overhang. Asymmetric elements include -3G and several unfavored bases. These cleavage preferences, the first for Gram-positive type IIA topoisomerases, differ markedly from those reported for Escherichia coli topo IV (consensus (A/G)*T/A) and gyrase, which are based on fewer sites. However, both pneumococcal enzymes cleaved an E. coli gyrase site suggesting overlap in gyrase determinants. We propose a model for the cleavage complex of topo IV/gyrase that accommodates the unique -2A/+6T and other preferences.     

In vivo cleavage of Escherichia coli BIME-2 repeats by DNA gyrase: genetic characterization of the target and identification of the cut site

The Escherichia coli chromosome contains about 300 bacterial interspersed mosaic elements (BIMEs). These elements, located at the 3' end of genes, are composed of three types of alternating repetitive extragenic palindromes (REPs). Based on the type of REP they contain and on their ability to interact with the integration host factor (IHF), BIMEs are subdivided into two families: BIME-1 elements contain an IHF binding site flanked by converging Y and Z1 REPs, whereas BIME-2 elements contain a variable number of alternating Y and Z2 REPs without an IHF site. Although some BIMEs have been implicated in the protection of mRNA against 3' exonucleolytic degradation, the main role of elements belonging to both families remains to be elucidated. In this paper, we used oxolinic acid, a drug that reveals potential sites of DNA gyrase action, to demonstrate that DNA gyrase interacts in vivo with BIME-2 elements. The frequency of cleavage varied from one element to another, and the cleavage pattern observed in elements containing several REPs indicated that DNA gyrase cut DNA every two REPs. A single cleavage site has been identified in the Y REP in six out of seven instances, and the nucleotide sequence of a 44 bp fragment containing the scission point displayed conserved residues at six positions. The lack of one of the conserved residues accounted for the absence of cleavage in most of the Z2 REPs. Our results also showed that cleaved REPs were always associated with another REP, suggesting that a pair of diverging REPs constitutes the target of DNA gyrase. DNA gyrase cleavage at repetitive BIME-2 elements may have consequences for DNA topology and genomic rearrangements.     

DNA gyrase complex with DNA: determinants for site-specific DNA breakage.

DNA gyrase catalyses DNA supercoiling by making a transient double-stranded DNA break within its 120-150 bp binding site on DNA. Addition of the inhibitor oxolinic acid to the reaction followed by detergent traps a covalent enzyme-DNA intermediate inducing sequence-specific DNA cleavage and revealing potential sites of gyrase action on DNA. We have used site-directed mutagenesis to examine the interaction of Escherichia coli gyrase with its major cleavage site in plasmid pBR322. Point mutations have been identified within a short region encompassing the site of DNA scission that reduce or abolish gyrase cleavage in vitro. Mapping of gyrase cleavage sites in vivo reveals that the pBR322 site has the same structure as seen in vitro and is similarly sensitive to specific point changes. The mutagenesis results demonstrate conclusively that a major determinant for gyrase cleavage resides at the break site itself and agree broadly with consensus sequence studies. The gyrase cleavage sequence alone is not a good substrate, however, and requires one or other arm of flanking DNA for efficient DNA breakage. These results are discussed in relation to the mechanism and structure of the gyrase complex.     

DNA sequence recognition by a eukaryotic sequence-specific endonuclease, Endo.SceI, from Saccharomyces cerevisiae

A eukaryotic sequence-specific endonuclease, Endo.SceI, causes sequence-specific double-stranded scission of double-stranded DNA to produce cohesive ends with four bases protruding at the 3' termini. Unlike in the case of restriction enzymes, an asymmetric 26-base pair consensus sequence was found around the cleavage site for Endo.SceI instead of a common sequence. We analyzed the base pairs that interacted with Endo.SceI on the recognition of its cleavage sites. A region comprising -10 through +16 base pairs from the center of the cleavage site was shown to be essential and sufficient for the sequence-specific cutting with Endo.SceI by experiments involving synthesized DNAs. Methylation interference experiments indicate that bases in the region comprising the +7 through +14 base pairs is involved in close contact with Endo.SceI in its recognition of the cleavage site. This +7 through +14-base pair region overlaps the most stringently conserved sequence in the consensus sequence for the cleavage site, suggesting that this region constitutes the core for the recognition by Endo.SceI.     

Recognition sequence of restriction endonuclease KpnI from Klebsiella pneumoniae.

We have determined the recognition sequence of the restriction endonuclease KpnI, previously isolated from Klebsiella pneumoniae. The enzyme cleaves the twofold rotationally symmetric sequence (see book for formula) at the positions indicated by the arrows, producing 3' protruding cohesive ends, four nucleotides in length. The specific cleavage site was unambiguously deduced using both 3' and 5' end analyses of KpnI generated restriction fragments of simian-virus 40 (SV40) DNA (1 site), adenovirus-2 (Ad-2) DNA (8 sites), and a plasmid (pCRI) DNA (2 sites).     

DNA gyrase on the bacterial chromosome. Oxolinic acid-induced DNA cleavage in the dnaA-gyrB region

Oxolinic acid forms complexes with gyrase and DNA in such a way that subsequent denaturation of gyrase reveals DNA cleavage. Cleavage sites were mapped in a 10,000 base-pair region of the Escherichia coli chromosome containing the dnaA, dnaN, recF, and gyrB genes. Twenty-four cleavage sites were identified. The sites were cleaved at different frequencies, with the most frequent cleavage occurring within gyrB. Not all sites were equally sensitive to oxolinic acid concentration, some sites exhibited an altered cleavage frequency when the gyrB225 delta topA mutant strain DM800 was compared with wild-type cells, and coumermycin selectively changed the cleavage frequency at a few sites in the mutant strain DM800. These perturbations appear to alter the frequency of cleavage at a site but not the location of the site. The availability of many sites of differing strengths may be an important factor in the ability of gyrase to fine-tune the level of supercoiling or provide local swivels in bacterial DNA.     

A new class of site-specific endodeoxyribonucleases. Endo.Sce I isolated from a eukaryote, Saccharomyces cerevisiae

We had found that yeasts had intracellular endodeoxyribonucleases that cut phage DNA into a set of double-stranded fragments with discrete chain lengths. We purified one of them to apparent homogeneity from Saccharomyces cerevisiae and designated it Endo.Sce I. Sequence analysis around 5 cleavage sites in plasmid DNA and phage DNA revealed that Endo.Sce I cuts a defined phosphodiester bond in each strand of double helix at the cleavage sites and produces free cohesive ends consisting of 4 nucleotides protruding at 3'-termini. However, unlike in the case of prokaryotic type II-restriction endonucleases, (i) Endo.Sce I seems to consist of two nonidentical subunits, (ii) no common palindrome or consensus sequence including more than 5 base pairs is detected at or near these cleavage sites, and (iii) Endo.Sce I can cut the DNA isolated from the cells that produced Endo.Sce I. All of the 5 cleavage sites are included in inverted repeats, but these inverted repeats are variable in size, nucleotide sequence, and distance between repeating units. An inverted repeat itself is not a structure recognized by Endo.Sce I. This study shows that Endo.Sce I is the first example of eukaryotic site-specific endonuclease and has properties, as described above, which distinguish it from prokaryotic restriction endonucleases.     

Characterization of the genome of the Rhodococcus rhodochrous bacteriophage NJL.

Temperate bacteriophage NJL of Rhodococcus rhodochrous has a 49-kb linear double-stranded DNA with cohesive ends (cos). NJL DNA has unique target sites for HindIII and SspI, two target sites each for NheI and ScaI, and no cleavage site for AxyI, DraI, EcoRI, SacI, and SphI. The single-stranded regions of cos ends were ligated to each other with T4 DNA ligase, removed with mung bean nuclease, or blunted with the Klenow large fragment of DNA polymerase I; then the sequences of the cos ends were determined. Comparison of these sequences revealed that the single-stranded regions are complementary and 18 bases long and protrude at the 3' ends; they have the following sequences: 5'-TTGGCACCGTGGGAGGAG-3' and 3'-AACCGTGGCAC CCTCCTC-5'. A physical map of NJL was constructed by a cos mapping method based on information about the structure of the cohesive ends and multiple digestions with restriction endonucleases.