FokI method of gene synthesis

An accurate, fast and simple method is presented for synthesis of a gene, or any DNA fragment with a defined sequence. The method is based on the observation that large (approx. 100 bp long) inserts can be cloned into a plasmid using a technique of oligodeoxynucleotide (oligo)-directed double-strand (ds) break repair. The procedure involves transformation of Escherichia coli with a denatured mixture of an insert-carrying oligo and linearized plasmid DNA [Mandecki, Proc. Natl. Acad. Sci. USA 83 (1986) 7177-7181]. The nucleotide (nt) sequences are inserted between two FokI restriction nuclease sites in one of four pUC-derived plasmids. Since FokI makes a staggered ds break at a DNA site 9 and 13 nt away from its recognition site, upon cleavage of the plasmid DNA with FokI, a restriction fragment is liberated that by design contains unique 4-nt-long 5'-protruding ends. The uniqueness of ends permits efficient and directed simultaneous ligation of several restriction fragments to form a gene. The method offers flexibility due to the modular-type assembly and does not require any restriction sites within the constructed gene. The sequence error rate is low: about one error per 4000 bp of DNA cloned. Synthetic DNA for only one DNA strand needs to be provided. The method was applied to the synthesis of a gene fragment encoding the N-terminal 143 amino acid residues of the human immunodeficiency virus transmembrane protein (p41).     

Tandem repeats within the inverted terminal repetition of vaccinia virus DNA

A tandemly repeated sequence within the genome of vaccinia virus is cut to fragments of approximately 70 bp by Hinf I, Taq I or Mbo II. The 70 bp repetition was localized within the much larger (10,300 bp) inverted terminal repetition by restriction analysis of cloned DNA fragments and by hybridization of the purified 70 bp repeat to vaccinia virus DNA restriction fragments. The molar abundance of the 70 bp fragment corresponds to a 30 fold repetition at each end of the genome. The repeating restriction endonuclease sites were mapped by agarose gel electrophoresis of partial Hinf I digests of the terminally labeled cloned DNA fragment. The first of 13 repetitive Hinf I sites occurred approximately 150 bp from the end of the cloned DNA. After an intervening sequence of approximately 435 bp, a second series of 17 repetitive Hinf I sites occurred. The DNA between the two blocks of repetitions has a unique sequence containing single Dde I, Alu I and Sau 3A sites. Tandem repeats within the inverted terminal repetition could serve to accelerate self-annealing of single strands of DNA to form circular structures during replication.     

An MboII/FokI trimming plasmid allowing consecutive cycles of precise 1- to 12-base-pair deletions in cloned DNA

A novel trimming plasmid has been designed which allows, in a preprogrammed fashion, the precise deletion of up to 12 bp per cleavage cycle, from one end of a cloned fragment. The plasmid, which carries the dhfr gene, contains unique recognition sites for two class-IIS restriction enzymes, MboII and FokI, which are arranged in the form of a cassette, so that consecutive cleavages with these endonucleases, followed by blunting with mung bean nuclease (MB), will precisely delete 12 bp of adjacent cloned DNA. When either MboII or FokI is used alone (followed by MB), 1 or 4 bp are removed, respectively. The final step in the trimming cycle is religation of the plasmid with T4 ligase. After required number of cycles, plasmids were transformed into Escherichia coli C600, and transformants selected by resistance to trimethoprim. Since the MboII/FokI cassette remains intact during these operations, one can repeat the cycle, consisting of cleaving, MB blunting and religation, several times, each time removing up to 12 bp from the cloned target DNA. Examples are provided of one-, two- and three-cycle trimmings.     

Nonrandom DNA sequencing of exonuclease III-deleted complementary DNA

The nonrandom DNA sequence analysis procedure of Poncz et al. [Proc. Natl. Acad. Sci. USA 79, 4298-4302 (1982)] was extensively modified to permit the determination of complementary DNA (cDNA) sequences containing G-C homopolymer regions. The recombinant cDNA plasmid was cleaved at a unique restriction enzyme site close to the cDNA and treated with Exonuclease III under controlled conditions to generate a set of overlapping fragments having deletions 50-1500 bases in length at the free 3' termini. After removal of single-stranded DNA regions by Bal31 and DNA polymerase I large fragment, the unique restriction enzyme site was recreated by blunt end ligation of synthetic oligonucleotides to the deleted DNA fragments and restriction enzyme digestion. The cDNA fragment was excised from the cloning vector using a second different restriction enzyme having a unique site that flanks the cDNA fragment and subsequently force-cloned into either M13 mp10 or mp11. This method should also be particularly useful for the sequencing of other types of DNA molecules with lengths 1500 bp or smaller.     

A novel multistep method for generating precise unidirectional deletions using BspMI, a class-IIS restriction enzyme

A novel approach is described that permits the introduction of unidirectional deletions into a cloned DNA fragment, in a precisely controlled manner. The method is based on the use of a special vector and a class-IIS restriction endonuclease, BspMI, which produces staggered cuts 4 and 8 nucleotides (nt) to the 3' from its recognition site 5'-ACCTGC-3'. The DNA fragment is inserted into the pUC19-based plasmid, which contains a unique BspMI recognition site, and the appropriate number of cleavage-and-deletion cycles is performed, each cycle removing 4 bp. Since the recognition site is not affected by the BspMI cleavage, no recloning of the DNA fragment is necessary. Each cycle consists of BspMI cleavage, removal of the 4-nt single-stranded cohesive ends with mung bean nuclease (MB), and blunt-end ligation to recircularize the plasmid. The shortened plasmid is reintroduced into the host, after one or after several such 4-bp deletion cycles. When DNA is inserted into the multiple cloning site in the lacZ alpha gene, the progress of 4-bp removal can be followed by determining the Lac phenotype, since removal of multiples of 3 bp retains the reading frame while other kinds of deletions distort (or restore) the reading frame. Loss of pre-existing restriction sites or creation of new ones also permits monitoring the progress of the deletion process.(ABSTRACT TRUNCATED AT 250 WORDS)     

On the sequence determinants and flexibility of the kinetoplast DNA fragment with abnormal gel electrophoretic mobilities

A 410 base-pair (bp) Sau3A restriction fragment derived from a Leishmania tarentolae kinetoplast DNA minicircle, which is known to have slower than expected electrophoretic mobilities in polyacrylamide gels, has been cloned in a plasmid and deletions from one end of the cloned segment have been constructed. Analysis of the gel electrophoretic mobility data of a large number of restriction fragments derived from the kinetoplast DNA clone and its deletion subclones has led to the conclusion that two sequences, one in the region bp 100 to 170 and the other bp 190 to 250, both numbered from one end of the 410 bp kinetoplast DNA segment, are important for the abnormal gel electrophoretic behavior of the kinetoplast DNA fragment. One common feature of these sequences is the periodic presence of short runs of A residues (3 to 6 As in each); auto-correlation analysis of these runs of A residues shows a strong harmonic component with a period around 11 bp. These results support and extend the previous analysis of Wu & Crothers (1984). The abnormal electrophoretic behavior is accentuated at low temperature and by the addition of Mg2+ to the electrophoresis buffer; addition of Na+ has the opposite effect. Insertion of sequences derived from the kinetoplast DNA fragment into nicked circular DNA causes no unexpected change in its electrophoretic mobility in agarose gel, suggesting that the 410 bp sequence, or segments of it, has no significant spatial writhe. Abnormal shifts in agarose gel mobilities are observed, however, when certain segments of the kinetoplast DNA are inserted into positively or negatively supercoiled DNA topoisomers. These results are consistent with a bent structure of the kinetoplast DNA in which the bend has zero writhe in its undistorted form but is easily distorted.     

Construction of a cloning site near one end of Tn917 into which foreign DNA may be inserted without affecting transposition in Bacillus subtilis or expression of the transposon-borne erm gene

A 1.3-kb restriction fragment carrying a cat gene derived from Staphylococcus aureus was inserted by ligation in both possible orientations into a HpaI restriction site located less than 300 bp from one end of Tn917. The resulting transposon derivatives were unimpaired in their ability to make and resolve transpositions into the chromosome of Bacillus subtilis and they displayed no detectable defect in expression of the inducible erm gene carried by the transposon. This demonstrates that the HpaI site itself, and perhaps the entire 250- to 300-bp region between the HpaI site and the nearest transposon terminal inverted repeat consists of nonessential DNA, and is there fore available to be modified or used as a cloning site with the expectation that the resulting transposon derivatives should be capable of normal transposition activity. To facilitate such manipulations, the HpaI site was "replaced" by a 24-bp DNA segment which contains a BamHI site flanked on either side by SmaI sites; these BamHI and SmaI sites are unique to the transposon. Several of the plasmid constructions undertaken in the course of this work illustrate ways in which homologous recombination may be used in conjunction with ligation in B. subtilis (and other bacteria, such as Streptococcus pneumoniae, which have similar mechanisms for DNA uptake during competence) to facilitate significantly the recovery of certain kinds of recombinant molecules.     

Formation of MboII vectors and cassettes using asymmetric MboII linkers

Class-IIS restriction endonucleases such as MboII cleave DNA at a specified distance away from their recognition sequences. This feature was exploited to cleave DNA at previously inaccessible locations by preparing special asymmetric linker/adapters containing the MboII recognition sequence. These could be joined to DNA fragments and subsequently cleaved by MboII. Attachment of a 3' phosphate to one of the two different oligodeoxynucleotides comprising the asymmetric duplex prevented ligation at the improper end of the linker. Plasmids were constructed containing a unique BamHI or BclI site between the recognition and cleavage site of MboII. These sites were used to introduce a foreign fragment into the plasmid at a position permitting MboII to cleave within the newly inserted fragment. Once cleaved at the unique MboII site, another DNA fragment was inserted. DNA was thus inserted at a sequence not previously accessible to specific cleavage by a restriction enzyme. A cassette containing an identifiable marker, the lac operator, between two oppositely oriented MboII/BamHI linkers was made and tested in a random insertion linker mutagenesis experiment.     

A family of high-copy-number plasmid vectors with single end-label sites for rapid nucleotide sequencing

A set of plasmid vectors was developed which allows fast sequencing by the chemical degradation method. These high-copy-number vectors are derivatives of the plasmid pUC8 containing different multiple-purpose cloning sites flanked by unique recognition sequences for the restriction enzymes BstEII, Tth111I and Eco81I as sites for end-labelling DNA. Due to their partially asymmetric recognition sequences, each of these three restriction sites can be singly end-labelled by a filling-in reaction with selected nucleotides. This allows easy single end-labelling of any cloned DNA fragment for sequencing by the chemical degradation method without any isolation and purification step after the labelling reaction. In addition, the nucleotide sequence of the complementary strand from the same end can be determined by the dideoxy chain termination procedure using the universal M13 primers. In most of the new vectors, the reading frame of the lacZ' gene is retained, allowing identification of cloned fragments.     

Rolling-Circle Plasmid pKYM Re-initiates DNA Replication

It is believed that rolling-circle plasmids are incapable ofre-initiation since they have to maintain their copy numberand this is one of the difierences between plasmids and phagesas phi-x174. To examine whether a rolling-circle plasmid pKYMis incapable of re-initiating DNA replication, we constructeda plasmid that carries both the pKYM origin (fragment 13, 173bp) and its truncated origin (fragment 32, 56 bp) in the sameorientation. This plasmid yielded two smaller plasmids in thepresence of RepK, an initiator protein. We showed that RepKcan bind to the fragment 13 but not to fragment 32 which lacksthe 3'-moiety of fragment 13. These results imply that RepKinitiates DNA replication from fragment 13 and terminates atfragment 32, then the same RepK is used for re-initiation ofreplication from the fragment 32 region. pKYM is likely to bea unique plasmid that re-initiates DNA replication like a phagephi-x174.     

Construction and characterization of new cloning vehicles. IV. Deletion derivatives of pBR322 and pBR325

In vitro recombinant DNA experiments involving restriction endonuclease fragments derived from the plasmids pBR322 and pBR325 resulted in the construction of two new cloning vehicles. One of these plasmids, designated pBR327, was obtained after an EcoRII partial digestion of pBR322. The plasmid pBR327 confers resistance to tetracycline and ampicillin, contains 3273 base pairs (bp) and therefore is 1089 bp smaller than pBR322. The other newly constructed vector, which has been designated pBR328, confers resistance to chloramphenicol as well as the two former antibiotics. This plasmid contains unique HindIII, BamHI and SalI sites in the tetracycline resistance gene, unique PvuI and PstI sites in the ampicillin resistance gene and unique EcoRI, PvuII and BalI sites in the chloramphenicol resistance gene. The pBR328 plasmid contains approx. 4900 bp.     

Plasmid vehicles for direct cloning of Escherichia coli promoters.

A multicopy plasmid cloning vehicle, pGA22, which carries genes for ampicillin resistance (Apr), tetracycline resistance (Tcr), chloramphenicol resistance (Cmr), and kanamycin resistance (Kmr) has been constructed. This plasmid has five unique sites for restriction endonucleases EcoRI, PstI, XhoI, SmaI, and SalI within antibiotic resistance genes. pGA22, which is 5.1 megadaltons in size, has a low copy number (probably fewer than 10 per genome), is capable of relaxed replication, and is mobilized by F-factor at a frequency of 10(-5). A series of promoter-cloning vehicles, pGA24, pGA39, and pGA46, has been developed from pGA22. In these plasmids the natural promoter for Tcr has been removed and has been replaced by small deoxyribonucleic acid fragments carrying unique sites for several restriction endonucleases. Cells carrying these vectors are sensitive to tetracycline unless insertional activation of the Tcr occurs by cloning a promoter-carrying deoxyribonucleic acid fragment in one of the unique sites adjacent to the 5' end of Tcr. In this way, promoters carried on a HindIII-generated deoxyribonucleic acid fragment can be inserted at the HindIII site of plasmid pGA24, pGA39, or pGA46. A promoter in fragments generated by digestion with restriction endonuclease XmaI or PstI or by any restriction endonucleases which generate flush ends, such as SmaI, PvuII, HpaI, HincII, or HaeIII, can be clones in plasmid pGA39. Plasmid pGA46 can be used to detect a promoter fragment carried on a BglII, BamHI, MboI, or PstI fragment. We also describe a plasmid, pGA44, with a unique KpnI site in the rifampin resistance gene rpoB.     

Method for cloning restriction fragments containing the termini of BAC inserts

We have developed a method to isolate the termini of BAC clones. The method is based on the two unique NotI sites located approximately 300 bp on either side of the EcoRI cloning site of the BAC vector pECS-BAC4. Our strategy includes the following steps: (i) generation of Southern blots with BAC clones digested with NotI and a second restriction enzyme; (ii) identification of the termini attached to the NotI/EcoRI fragment of the BAC vector via hybridization with a probe derived from sequences located between one NotI site (left or right arm) and the cloning site; (iii) ligation of the doubly digested BAC clone (NotI and the selected second restriction enzyme) with an equally doubly digested cloning plasmid vector; and (iv) confirmation of the clone as a terminus. This strategy has allowed us to begin the construction of a contig near a common bean gene that controls resistance to a group of potyviruses.     

DNA supercoiling enables the type IIS restriction enzyme BspMI to recognise the relative orientation of two DNA sequences

Many proteins can sense the relative orientations of two sequences at distant locations in DNA: some require sites in inverted (head-to-head) orientation, others in repeat (head-to-tail) orientation. Like many restriction enzymes, the BspMI endonuclease binds two copies of its target site before cleaving DNA. Its target is an asymmetric sequence so two sites in repeat orientation differ from sites in inverted orientation. When tested against supercoiled plasmids with two sites 700 bp apart in either repeated or inverted orientations, BspMI had a higher affinity for the plasmid with repeated sites than the plasmid with inverted sites. In contrast, on linear DNA or on supercoiled DNA with sites 1605 bp apart, BspMI interacted equally with repeated or inverted sites. The ability of BspMI to detect the relative orientation of two DNA sequences thus depends on both the topology and the length of the intervening DNA. Supercoiling may restrain the juxtaposition of sites 700 bp apart to a particular alignment across the superhelical axis, but the juxtaposition of sites in linear DNA or far apart in supercoiled DNA may occur without restraint. BspMI can therefore act as a sensor of the conformational dynamics of supercoiled DNA.     

Specific deletion of DNA sequences between preselected bases.

Blunt-end ligation of a "filled-in" HindIII, Sal I, Ava I or Bcl I restriction site with a DNA fragment having A, G, C, or T as the terminal 3' nucleotide regenerates the corresponding restriction site. A combination of this property with the action of BAL 31 nuclease which progressively removes base-pairs from the ends of linear DNA, can generate deletions extending to desired pre-selected nucleotides, and introduces unique restriction sites at those positions. Similarly other restriction sites can be used to select for the deletion of sequences between specific di-, tri-, tetra- and penta-nucleotides. Using this method, 10 base pairs were deleted from the end of a restriction fragment carrying the late promoter for bacteriophage T7 gene 1.1, to create a molecule with a unique restriction site at the initiation codon for translation.     

Restriction fragment length polymorphisms in the D7S1 region of human chromosome 7

Summary A restriction fragment length polymorphism in the D7S1 region of chromosome 7 is detected by hybridizing the recombinant plasmid pA2H3 to HindIII- or HinfI-digested human DNA. Three HindIII and two HinfI alleles were detected, and it was found that all individuals carrying the variant HinfI allele also had the commoner of the two variant HindIII alleles. All variants seem to result from point mutation in restriction enzyme recognition sites. Restriction mapping of the D7S1 region revealed that the associated HindIII and HinfI alleles are defined by sites 300 base-pairs (bp) apart, and it is suggested that the close proximity of these sites is sufficient to account for the strong phenotype association observed.     

Preferential uptake of restriction fragments from a gonococcal cryptic plasmid by competent Neisseria gonorrhoeae

Factors involved in the specificity of DNA uptake by competent Neisseria gonorrhoeae were examined. Host-controlled modification did not affect uptake. Certain restriction fragments of the 4.2 kb gonococcal cryptic plasmid pFA1 and of the replicative form of the bacteriophage M13 were taken up in preference to others, independent of differences in fragment size. A 600 bp fragment from the 4.2 kb plasmid was cloned into pLES2, a gonococcal-Escherichia coli shuttle vector; the 600 bp fragment was taken up into a DNAase-I-resistant state in preference to the vector fragment. A second 370 bp fragment in pFA1 was also taken up preferentially. The 600 bp and 370 bp fragments share a 10 bp sequence, which is found in pFA1 only on fragments that were taken up readily. However, a fragment from M13 which was efficiently taken up did not contain this 10 bp sequence. In addition, this sequence was not sufficient to direct preferential DNA uptake by gonococci, since a recombinant plasmid containing this 10 bp sequence was not taken up appreciably better than the vector plasmid or another recombinant plasmid containing an unrelated 10 bp sequence. Sequence comparisons of the three restriction fragments which were preferentially taken up did not yield any consensus sequences greater than 7 bp. Although it is likely that efficient uptake of DNA by gonococci is determined by DNA structure, a single short sequence could not be found that accounted for specific uptake.     

大肠杆菌青霉素G酰化酶基因及其邻近区域的核苷酸全序列

Some of microorganisms have been known to possess penicillin G acylase activity. The E. coli derived penicillin G acylase (PGA) can catalyze the conversion of penicillin G into phenylacetic acid and 6-amino-penicillanic acid, the latter is used as the starting compound for the industrial formation of semi-synthetic penicillins. Apart from its industrial importance, the enzyme PGA displays a number of interesting properties. Catalytically active enzyme is localized in the periplasmic space of E. coli cells and composed of two dissimilar subunits. The two subunits are apparently produced from a precursor protein, via a processing pathway hitherto unique in its features for a prokaryotic enzyme. The studies on processing of the precursor and on the relationship between structure and function of the mature enzyme are important theoretically. Previously we cloned a 3.5 kb DNA fragment from a strain (E. coli AS 1.76), which displays PGA activity. In this paper, we report a nucleotide sequence of the 3.5 kb DNA fragment containing PGA gene. After insertion of the DNA fragment into EcoR I and Hind III sites in pWR 13, pPGA 20 had been obtained. We subcloned the Hind III and Bg1 II treated fragment of 1.6 kb in length from pPGA 20 into Hind III and BamH I sites of pWR 13 to get a pPGA 1.6, and Bg1 II and EcoR I treated fragment of 1.9 kb in length into BamH I and EcoR I sites of pWR 13 to get a pPGA 1.9. The linearized pPGA 1.9 which were digested with appropriate restriction enzymes were progressively shortened from both ends respectively by digestion with Bal 31 nuclease, followed by cleavage of shortened target DNA off vector DNA molecules with appropriate restriction enzymes. The series of the DNA fragments shortened from EcoR I end were then cloned into plasmid pWR 13 which had previously digested with Hind III and Sma I enzymes (Fig. 1). The DNA fragment cloned in pWR 13 were directly sequenced on the resulted plasmids by using primer I and primer II. Thus we have obtained the complete nucleotide sequence of the 3.5 kb DNA fragment. The 3.5 kb fragment contains an intact PGA gene which is 2.6 kb.(ABSTRACT TRUNCATED AT 400 WORDS)