Cleavage maps of the filamentous bacteriophages M13, fd, fl, and ZJ/2.

The replicative form DNAs of bacteriophage M13, fd, f1, and ZJ/2 were found to be sensitive to cleavage by the restriction endonucleases endoR-HapII, endoR-HaeII, endoR-HaeIII, endoR-HindII, endoR-AluI, endoR-Hha, and endoR-Hinf. With respect to M13 DNA the number of cleavage sites varied from 21 for endoR-Hinf, 18 for endoR-AluI, 15 for endoR-Hha, 13 for endoR-HapII, 10 for endoR-HaeIII, 3 for endoR-HaeII, to only a single site for endoR-HindII. In contrast to M13, fd and f1, the ZJ/2 DNA molecule was not cleaved by the endoR-HindII endonuclease. No cleavage site on either phage DNA was detected for the endonucleases endoR-Hsu, endoR-EcoRI and endoR-Sma. When compared with M13 DNA, several differences were noted in the number and size of cleavage products obtained with DNA of phage fd, f1, and ZJ/2. From the results of these analyses, using the M13 enzyme cleavage maps as a reference, the endoR-HapII, endoR-HaeII, endoR-HaeIII, endoR-HindII and endoR-AluI maps of phage fd, f1, and ZJ/2 could be constructed. As is expected for very closely related phages, the enzyme cleavage patterns exhibit a high degree of homology. Phage f1 and ZJ/2 are most related since an identical pattern was obtained with seven different restriction endonucleases. Evidence is provided also that f1 is more similar to M13 than to fd. Furthermore, characteristic differences exist within the endoR-Hinf enzyme cleavage pattern of all the four phages tested. Digestion of phage DNA with this enzyme, therefore, provides a new and sensitive method of distinguishing these closely related filamentous coliphages .     

Cloning of a functional replication origin of phage G4 into the genome of phage M13.

A chimeric single-stranded DNA phage, M13Gori1, has been formed as a result of the in vitro insertion of a 2216 base-pair HaeII fragment of bacteriophage G4 replicative form DNA into the replicative form DNA of bacteriophage M13. The inserted G4 DNA carries the dnaG-dependent origin for G4 complementary strand synthesis. The cloned G4 origin functions both in vivo and in vitro in the conversion of M13Gori1 single-stranded viral DNA to the duplex replicative form by a rifampicin-resistant mechanism. Labelling of the 3′ terminus of the single discontinuity in M13Gori1 replicative form II molecules synthesized in crude extracts and subsequent restriction analysis indicate that M13Gori1 complementary strand synthesis can be initiated at either the RNA polymeraseprimed M13 origin or at the dnaG-primed G4 origin. The M13Gori1 complementary strand initiated at the G4 origin terminates in the vicinity of the G4 origin after progressing around the circular template and traversing the M13 origin region, indicating the absence of a specific nucleotide sequence in the M13 origin for termination of the newly formed complementary strand. The ability of this chimeric phage to utilize the cloned G4 origin in vivo even in the presence of the presumed M13 pilot protein (gene 3 protein) indicate that the nucleotide sequence of the replication origin is sufficient for recognizing the appropriate initiation enzymes. Since decapsidation of M13 is tightly coupled to replicative form formation, initiation at the G4 origin, located over 1000 nucleotides from the M13 complementary strand origin, indicates that widely separated nucleotide sequences contained in the filamentous virion can be exposed to the cell cytoplasm during eclipse.     

Location of the cooperative melting regions in bacteriophage fd DNA

Differential melting profiles of the linear replicative form (RF-III) DNA of bacteriophage fd, of the fragments obtained by the restriction endonuclease R.HinHI and of those obtained by R.Hga were investigated. With these results a physical map which locates the cooperative melting regions on the DNA was constructed, and compared with the genetic map.     

Single-Molecule Analysis of Restriction DNA Fragments Using Fluorescence Correlation Spectroscopy

The cleavage of fluorescence-labeled M13DNA (7250 bp) usingHaeIII,HgaI,BsmAI, andBspMI was analyzed by fluorescence correlation spectroscopy (FCS) in a small volume (1.5 × 10⁻¹⁵liters). The digestion process can be monitored by the decrease in amplitude of the fluorescence correlation function while the original DNA molecule is divided into several fragments by the enzymes. To analyze this reaction by FCS, we derived a practical equation for estimating the number of molecules in the FCS measurements. Under standard enzymatic conditions,HaeIII andBsmAI digested fluorescence-labeled DNA to completion in the range of 8 h, whereasHgaI andBspMI digested the DNA after 40 h. The comparison of recognition sequences suggested that some tagged nucleotides could be inserted between the recognition site and the cleavage site of the slow enzyme group. The decrease in amplitude in the fluorescence correlation function quantitatively monitors the hydrolysis of DNA during the digestion process.     

A METHOD FOR the DETERMINATION of STRANDEDNESS of DNA FRAGMENTS CLONED IN PHAGE M13

Recombinant M13Hol phage containing Eco R1 restriction endonuclease fragments B, E, and F of adenovirus type 2 (Ad2) DNA were constructed by cloning into the unique Eco R1 site of the replicative form of the phage M13Hol176 DNA. Polarity of the adenovirus inserts in recombinant molecules was deduced by the following procedures: Viral DNA fragments obtained from Ad2 DNA molecules were purified, denatured, and subjected to electrophoresis. the separated DNA strands were transferred from agarose to nitrocellulose by the Southern procedure and hybridized with radioactive 3'-end labeled Hae III fragments of the recombinant phage DNAs. This procedure provided a rapid test for assaying strandedness of the cloned fragments.     

Studies on the structure of replicative intermediates in bacteriophage M13 single stranded DNA synthesis.

Pulse-labeled replicative intermediates in M 13 single stranded DNA synthesis can be separated by dye-buoyant density centrifugation into two major fractions: Supercoiled molecules (RI I) containing viral strands of more than one genome length, and "relaxed" molecules (RI II) with labeled DNA chains shorter than unit length. It is postulated that RI II molecules might be formed in vivo by site-specific nicking of RF I molecules.     

Design of molecules that specifically recognize and cleave apurinic sites in DNA

We have prepared a series of a tailor-made molecules that recognize and cleave DNA at apurinic sites in vitro. These molecules incorporate in their structure different units designed for specific function: an intercalator for DNA binding, an nucleic base for abasic site recognition and a linking chain of variable length and nature (including amino and/or amido functions). The cleavage efficiency of the molecules can be modulated by varying successively the nature of the intercalating agent, the nucleic base and the chain. All molecules bind to native calf thymus DNA with binding constants ranging from 10⁴ to 10⁶ M^?1. Their cleavage activity was determined on plasmid DNA (pBR 322) containing 1.8 AP-sites per DNA-molecule. The minimum requirements for cleavage are the presence of the three units, the intercalator, the nucleic base and at least one amino function in the chain. The most efficient molecules cleaved plasmid DNA at nanomolar concentrations. Enzymatic experiments on the termini generated after cleavage of AP-DNA suggest a strand break induced by a β-elimination reaction. In order to get insight into the mode of action (efficiency, selectivity, interaction), we have used synthetic oligonucleotides containing either a true abasic site at a determined position to analyse the cleavage parameters of the synthetic molecules by HPLC or a chemically stable along (tetrahydrofuran) of the abasic site for high field ¹H NMR spectrometry and footprinting experiments. All results are consistent with a β-elimination mechanism in which each constituent of the molecule exerts a specific function as indicated in the scheme: DNA targeting, abasic site nucleases and can be used advantageously as substitutes for the natural enzyme for in vitro cleavage of AP-sites containing DNA.     

Insertion of the Tn3 transposon into the genome of the single-stranded DNA phage M13.

The transposable genetic element Tn3, which carries an ampicillin (Ap) resistance determinant, has been translocated from a ColE1-Apr plasmid, RSF2124, to the genome of the filamentous single-stranded DNA phage M13. The site orientation of the inserted element has been determined for one such phage, M13::Tn3-15. The insertion is within the intergenic space separating genes 2 and 4 and containing both the viral strand and complementary strand origins. The lengths of both the filamentous phage and the duplex replicative form (RF) DNA are 1.7--1.8 times those of M13 phage and replicative form DNA. Both plaque formation and transduction of sensitive cells to ampicillin resistance by M13::Tn3-15 are sensitive to purified antibodies to the M13 major coat protein.     

Lack of repair of ultraviolet light damage in Mycoplasma gallisepticum

Molecules with single-stranded tails (rolling circles) were isolated as replicating intermediates in G4 progeny single-stranded DNA synthesis. Lysates from infected cells harvested late in infection during single-stranded DNA synthesis were not deproteinised but analysed directly in caesium chloride and propidium diiodide gradients. The gradient fractionated them on the basis of tail length. If the lysates were first deproteinised however, the tailed replicative intermediates banded as a peak at a density just greater than that of replicative form II DNA (RFII) and did not spread down the gradient. The origin of synthesis of the viral strand tail was mapped by electron microscopy as 55 to 60% away from the single EcoRI cleavage site. Termination molecules finishing a round of viral strand DNA synthesis have been identified as molecules consisting of a closed single-stranded DNA circle attached by a very small region to the parent double-stranded DNA circle.     

Origin and direction of replication of the bacteriocinogenic plasmid Clo DF13.

Cairn's type replicative intermediates of both the wildtype Clo DF13 plasmid and the copy mutant CLO DF13 cop3 were isolated by dye-buoyant density centrifugation. Replicative intermediates were linearized at the HpaI or Sa1I cleavage site, and examined with the electron-microscope. The data show that replication of both the Clo DF13 wild type plasmid and the Clo DF13 cop3 plasmid, initiates at about 2.8% on the physical map. Replication proceeds unindirectionally and counterclockwise on this map.     

Effects of 2''-deoxy-2''-azidocytidine on polyoma virus DNA replication: evidence for rolling circle-type mechanism.

Rolling circle-type molecules were found in polyoma virus-infected cells after inhibition of DNA synthesis with 2'-deoxy-2'-azidocytidine. The circular DNA molecules were always relaxed and of polyoma length. Most of the attached tails were less than two times the length of the polyoma genome, but tails with a length of up to 4.75 times the genome were also found. After cleavage of the total pool of replicating molecules with either endo R.EcoRI or endo R.BamI, Y-shaped molecules with replicated portions of various lengths were generated from rolling circle-type molecules. Moreover, after cleavage, Y-shaped molecules with three unequal arms were found, which could be explained as derived from the tail in rolling circle-type molecules starting from the normal origin, i.e., 29% from the endo R.EcoRI cleavage site. Rolling circle-type molecules were also found during a normal, noninhibited infection cycle. In such cells, a relatively higher frequency of rolling circle-type molecules was observed late during infection. Compared with control cultures, cultures inhibited with 2'-deoxy-2'-azidocytidine showed a greater amount of rolling circle-type molecules relative to normal replicative intermediates. 2'-Deoxy-2'-azidocytidine has previously been shown to inhibit the initiation of new rounds of replication; thus, the result obtained here indicates that a rolling circle-type mechanism is independent of the reinitiation of DNA synthesis.     

Replication of bacteriophage M13. XV. Location of the specific nick in M13 replicative form II accumulated in Escherichia coli polAex1.

M13 replicative form II (RFII) DNA was prepared from Escherichia coli RS5052 (polAex1) cells in the late stage of infection, and the DNA sequence at the discontinuity was examined. The data presented here suggest that the single discontinuity in the late stage of infection RFII maps at the same position as the gene II protein nicking site on fd RFI which was determined in vitro (Meyer et al., Nature (London) 278:365-367, 1979) and has a 5' terminal nucleotide sequence identical to that at the nick produced by gene II protein in vitro. The discontinuity in the in vivo RFII appears to be a single break in the phosphodiester backbone, leaving a 3' OH terminus. RFII molecules containing a gap, i.e., missing nucleotides at the site of discontinuity, were not detected.     

Conjugative DNA synthesis: R1162 and the question of rolling-circle replication

Strand-replacement synthesis during conjugative mating has been characterized by introducing into donor cells R1162 plasmid DNA containing a base-pair mismatch. Conjugative synthesis in donors occurs in the absence of vegetative plasmid replication, but with a lag between rounds of transfer, and with most strands being initiated at the normal site within the replicative origin. These characteristics argue against the idea that multiple plasmid copies are generated for successive rounds of transfer by rolling-circle replication. However, the R1162 relaxase protein can process molecules containing multiple transfer origins in the manner expected for the conversion of single-strand multimers, generated by rolling-circle replication, to unit-length molecules. This capability appears to be the result of a secondary cleavage reaction carried out by the protein. The possibility is raised that the processing of molecules with more than one origin of transfer might be a repair mechanism directed against adventitious DNA synthesis during transfer.     

Deletion analysis of the cloned replication origin region from bacteriophage M13.

A cloned 270-nucleotide fragment from the origin region of the M13 duplex replicative form DNA confers an M13-dependent replication mechanism upon the plasmid vector pBR322. This M13 insert permits M13 helper-dependent replication of the hybrid plasmid in polA cells which are unable to replicate the pBR322 replicon alone. Using in vitro techniques, we have constructed several plasmids containing deletions in the M13 DNa insert. The endpoints of these deletions have been determined by DNA sequence analysis and correlated with the transformation and replication properties of each plasmid. Characterization of these deletion plasmids allows the following conclusions. (i) The initiation site for M13 viral strand replication is required for helper-dependent propagation of the chimeric plasmid. (ii) A DNA sequence in the M13 insert, localized between 89 and 129 nucleotides from the viral strand initiation site, is necessary for efficient transformation of polA cells. A chimeric plasmid containing the viral strand initiation site, but lacking this additional 40 nucleotide M13 sequence, transforms helper-infected cells at a frequency approximately 10(4)-fold less than that of plasmids containing this additional DNA segment. (iii) The entire M13 complementary strand origin can be deleted without affecting M13-dependent transformation by the hybrid plasmids. We propose a model in which replication of one strand of duplex chimera initiates by nicking at the gene II protein nicking site in the viral strand of the M13 insert, followed by asymmetric single-strand synthesis. Initiation of the complementary strand possibly occurs within plasmid sequences.     

Electron microscopic visualization of restriction sites on DNA molecules.

DNA molecules were adsorbed to a polylysine-treated carbon film and digested directly on the film by restriction enzymes. After washing the film with 1 M NaCl, 0.4% Kodak Photo-Flo and 9% formamide, each cleavage site introduced was visualized as a gap under the electron microscope. By measuring the gapped positions on linear DNA molecules induced by other enzymes, a single EcoRI site on a lambda dv1 molecule and three HinHI sites on an fd1RF molecule were mapped at the positions expected from the cleavage maps, respectively. This electron-microscopic procedure may be useful for the construction of a cleavage map.     

Multiple structures of adeno-associated virus DNA: analysis of terminally labeled molecules with endonuclease R-Hae III.

The double-stranded form of adeno-associated virus (AAV) DNA has about 20 sites sensitive to endonuclease R.Hae III from Haemophilus aegypitus; the fragments produced fall into about 13 size classes, 8 of which contain single fragments. The location of the Hae III-produced AAV fragments relative to the three EcoR1 fragments was determined. Using revised figures for the molecular weights of the Hae III cleavage products of phiX174 replicative form DNA, we calculated that AAV DNA contains about 4,000 nucleotides. After Hae III digestiion of duplex DNA terminally labeled with 32P using polynucleotide kinase, the majority of fragments containing a 5' 32P label were about 40 nucleotides in length, and fragments of similar size were generated from each end, suggesting that the Hae site closest to the end is within the terminal repetition. Two more-slowly-migrating cleavage products also bore 5' 32P end label. These three terminally labeled species were also generated from single-stranded AAV DNA by digestion with Hae III, and evidence that one may have a nonlinear ("rabbit-ear") structure is presented. The predominant 5' terminal base was identified as thymine for both the plus and minus strands of AAV. Single-stranded AAV molecules could not be efficiently covalently circularized by incubation with polynucleotide ligase or ligase plus T4 DNA polymerase.     

Degradation of small leucine-rich repeat proteoglycans by matrix metalloprotease-13: identification of a new biglycan cleavage site

A major and early feature of cartilage degeneration is proteoglycan breakdown. Matrix metalloprotease (MMP)-13 plays an important role in cartilage degradation in osteoarthritis (OA). This MMP, in addition to initiating collagen fibre cleavage, acts on several proteoglycans. One of the proteoglycan families, termed small leucine-rich proteoglycans (SLRPs), was found to be involved in collagen fibril formation/interaction, with some members playing a role in the OA process. We investigated the ability of MMP-13 to cleave members of two classes of SLRPs: biglycan and decorin; and fibromodulin and lumican. SLRPs were isolated from human normal and OA cartilage using guanidinium chloride (4 mol/l) extraction. Digestion products were examined using Western blotting. The identities of the MMP-13 degradation products of biglycan and decorin (using specific substrates) were determined following electrophoresis and microsequencing. We found that the SLRPs studied were cleaved to differing extents by human MMP-13. Although only minimal cleavage of decorin and lumican was observed, cleavage of fibromodulin and biglycan was extensive, suggesting that both molecules are preferential substrates. In contrast to biglycan, decorin and lumican, which yielded a degradation pattern similar for both normal and OA cartilage, fibromodulin had a higher level of degradation with increased cartilage damage. Microsequencing revealed a novel major cleavage site (... G₁₇₇/V₁₇₈) for biglycan and a potential cleavage site for decorin upon exposure to MMP-13. We showed, for the first time, that MMP-13 can degrade members from two classes of the SLRP family, and identified the site at which biglycan is cleaved by MMP-13. MMP-13 induced SLRP degradation may represent an early critical event, which may in turn affect the collagen network by exposing the MMP-13 cleavage site in this macromolecule. Awareness of SLRP degradation products, especially those of biglycan and fibromodulin, may assist in early detection of OA cartilage degradation.