Cleavage of phi X174 single-stranded DNA by gene A protein and formation of a tight protein-DNA complex.

The gene A protein cleaves phi X174 single-stranded DNA (ssDNA). The cleavage appears to be stoichiometric, whereby a gene A protein molecule breaks a phosphodiester bond and binds to the 5' end. The enzyme introduces mostly a single break in a circular ssDNA molecule. However, at high enzyme-to-DNA ratios, more than one break in the DNA could be observed. The cleavage of the ssDNA by gene A protein renders the DNA sensitive to the action of terminal transferase to incorporate [alpha -32P]ATP. Thus, the 3'OH end is free. All attempts to label the 5' end by T4-induced polynucleotide kinase and [gamma-32P]ATP failed. The formation of a gene A-ssDNA complex was demonstrated directly by using 3H-labeled gene A protein and 32P-labeled ssDNA in the reaction. Such a complex is resistant to treatments with 0.2 M NaOH, banding in CsCl, and boiling in 2.5% sodium dodecyl sulfate. Only treatment with a nuclease released the bound protein. Also, after cleaving [32P]ssDNA by gene A protein, followed by either DNase I or micrococcal nuclease digestion, a fraction of the 32P label remained resistant to nuclease treatment and comigrated with gene A protein on polyacrylamide gels.     

Determination of the multiplicity of the silk fibroin gene and detection of fibroin gene-related DNA in the genome of Bombyx mori.

The number of silk fibroin genes per genome in the silkworm Bombyx mori has been determined by hybridization using fibroin [¹²⁵I]mRNA. The purified [¹²⁵I]mRNA had an oligonucleotide pattern after RNAase T₁ digestion which was characteristic of fibroin mRNA (Suzuki &; Brown, 1972) and it hybridized specifically to DNA with a G + C content expected for a fibroin gene. Thermal denaturations indicated that these hybrids were mismatched by about 3%, which probably indicates some variation among the sequences encoding the internal repetitions of the fibroin protein.The concentration of fibroin gene sequences in B. mori DNA was measured by saturation hybridization of [¹²⁵I]mRNA to filter bound DNA. The same saturation level of 1.8 × 10^?5 μg mRNA per μg DNA was calculated from data obtained with unfractionated DNA and with fibroin gene sequences which had been separated from bulk B. mori DNA by actinomycin $\text{D}\text{CsCl}$ centrifugation. Scatchard plots of the subsaturation data extrapolated to an identical saturation value. Internal reiteration of the fibroin mRNA molecule was apparent from the high association constant of hybridization. An exhaustive hybridization experiment showed that such repetitions comprise at least 90% of each mRNA molecule. The saturation value, in conjunction with the genome DNA content and the mRNA size, indicated the presence of only one fibroin gene per haploid B. mori genome.Hybridization of actinomycin $\text{D}\text{CsCl}$ fractionated DNA indicated that fibroin mRNA can form hybrids with DNA that bands with bulk B. mori DNA. These hybrids appear to involve DNA which is related to, but distinguishable from, true fibroin gene sequences. The fibroin gene-related sequences form mismatched hybrids with the mRNA, are much shorter than the fibroin gene and are dispersed in B. mori DNA of much lower G + C content, and there are many copies of these sequences per B. mori genome.     

Targeted disruption of the gene encoding DNA ligase IV leads to lethality in embryonic mice

DNA ligase IV is the most recently identified member of a family of enzymes joining DNA strand breaks in mammalian cell nuclei [1] and [2]. The enzyme occurs in a complex with the XRCC4 gene product [3], an interaction mediated via its unique carboxyl terminus [4] and [5]. Cells lacking XRCC4 are hypersensitive to ionising radiation and defective in V(D)J recombination [3] and [6], implicating DNA ligase IV in the pathway of nonhomologous end-joining (NHEJ) of DNA double-strand breaks mediated by XRCC4, the Ku70/80 heterodimer and the catalytic subunit of DNA-dependent protein kinase (DNA-PKcs) in mammalian cells (reviewed in [7]). The phenotype of a null mutant of the Saccharomyces cerevisiae DNA ligase IV homologue indicates that the enzyme is non-essential and functions in yeast NHEJ [8], [9] and [10]. Unlike other mammalian DNA ligases for which cDNAs have been characterised, DNA ligase IV is encoded by an intronless gene (LIG4). Here, we show that targeted disruption of LIG4 in the mouse leads to lethality associated with extensive apoptotic cell death in the embryonic central nervous system. Thus, unlike Ku70/80 and DNA-PKcs [11], [12], [13] and [14], DNA ligase IV has an essential function in early mammalian development.     

Adenine release is fast in MutY-catalyzed hydrolysis of G:A and 8-Oxo-G:A DNA mismatches

MutY, a DNA repair enzyme, is unusual in that it binds exceedingly tightly to its products after the chemical steps of catalysis. Until now it was not known whether the product being released in the rate-limiting step was DNA, adenine, or both. MutY hydrolyzes adenine from 8-oxo-G:A (OG:A) base pair mismatches as the first step in the base excision repair pathway, as well as from G:A mismatches. The products are adenine and DNA containing an apurinic (AP) site. Tight product binding may have a physiological role in preventing further damage at the OG:AP site. We developed a rate assay using [8-14C]adenine in OG:A or G:A mismatches that distinguishes between adenine hydrolysis and adenine release. [8-14C]Adenine was released quickly from the MutY.AP-DNA.[8-14C]adenine complex, with a rate constant greater than 5 min-1. This was much faster than the rate-limiting step, at 0.006-0.015 min-1. Gel retardation experiments showed that AP-DNA release was very slow, consistent with it being the rate-limiting step. Thus, the kinetic mechanism involves fast adenine release after hydrolysis followed by rate-limiting AP-DNA release. Adenine appears to be buried deep in the protein.DNA interface, but there is enough flexibility or open space for it to dissociate from the MutY.APDNA.adenine complex. These results have implications for the catalytic mechanism of MutY.     

Non-enzymatic ATP-mediated binding of hydroxymethyl derivatives of aromatic hydrocarbons to DNA

ATP mediates covalent binding of hydroxymethyl derivatives of aromatic hydrocarbons to DNA. This non-enzymatic reaction has been studied with 6-[14C]hydroxymethylbenzo[alpha]pyrene (]14C]BP-6-CH2OH) and 7-[14C]-hydroxymethylbenz[alpha]anthracene ([14C]BA-7-CH2OH) at 37 degrees C in Tris buffer (pH 7.0). While ADP mediates the reaction 25-50% as well as ATP, six other possible phosphate donors including AMP were inactive as cofactors. A complex response to ATP occurred in which low binding of BP-6-CH2OH or BA-7-CH2OH was observed at concentrations of ATP below 2.5 mM, but a greater than linear response to higher concentrations of ATP was observed until ATP was saturating. Binding of the substrates to RNA was much lower than to DNA. Fluorescence spectra of BP-6-CH2OH bound to DNA were almost identical to the spectra of 6-bromomethylbenzo[alpha]pyrene bound to DNA and free 6-methylbenzo]alpha]pyrene, indicating that ATP-mediated binding of BP-6-CH2OH to DNA occurs at the 6-methyl group. The fate of ATP and ADP in the binding reaction of BP-6-CH2OH was examined by thin layer chromatography. Loss of one phosphate group occurs during the reaction. With ATP the rate of loss is about 100-fold greater than the rate of binding of BP-6-CH2OH to DNA. This implies that the binding reaction proceeds through formation of a presumed reactive and unstable phosphate ester intermediate which then inefficiently binds to DNA.     

A protein covalently bound to ColE1 DNA

ColE1 DNA was isolated from Escherichia coli as a relaxation complex of supercoiled DNA and proteins. Treatment of the complex with either protein-denaturing agents (SDS, phenol etc.) or proteolytic enzymes converted the supercoiled DNA to an open-circular form (relaxation). The relaxation complex was separately labelled in vivo with [3H]Leu or [14C]Leu, [35S]Met or (32P)phosphate and extensively purified. Complete hydrolysis of the relaxed complex with DNase I and P1 nuclease produced a 36-kDa protein which, we believe, is covalently bound to ColE1 DNA. On the other hand, the relaxed complex was treated with tosylphenylalanylchloromethane-treated-trypsin and the DNA-peptide(s) produced was (were) isolated and digested with the nucleases as above. The resulting nucleotidylpeptide(s) was (were) isolated by DEAE-Sephadex chromatography. The only 5'-dCMP was released from the nucleotidylpeptide(s) by snake venom phosphodiesterase treatment. O-Phosphoserine was found in acid hydrolysates of the DNA-peptide(s). We suggest that in the relaxation event the 36-kDa protein becomes covalently linked to ColE1 DNA via a phosphodiester bond between dC and the serine residue.     

The Escherichia coli cysG gene encodes S-adenosylmethionine-dependent uroporphyrinogen III methylase.

The Escherichia coli cysG gene was successfully subcloned and over-expressed to produce a 52 kDa protein that was purified to homogeneity. This protein was shown to catalyse the S-adenosylmethionine-dependent methylation of uroporphyrinogen III to give a product identified as sirohydrochlorin on the basis of its absorption spectra, incorporation of 14C label from S-adenosyl[Me-14C]methionine and mass and 1H-n.m.r. spectra of its octamethyl ester. Further confirmation of the structure was obtained from a 14C-n.m.r. spectrum of the methyl ester produced by incubation of the methylase with uroporphyrinogen III, derived from [4.6-13C2]porphobilinogen, and S-adenosyl[Me-13C]methionine.     

Analysis of bacteriophage phi X174 gene A protein-mediated termination and reinitiation of phi X DNA synthesis. II. Structural characterization of the covalent phi X A protein-DNA complex

In the preceeding paper (Brown, D. R., Roth, M. J., Reinberg, D., and Hurwitz, J. (1984) J. Biol. Chem. 259, 10545-10555), it was shown that following bacteriophage phi X174 (phi X) DNA synthesis in vitro using purified proteins, the phi X A protein could be detected covalently linked to nascent 32P-labeled DNA. This phi X A protein-[32P]DNA complex was the product of the reinitiation reaction. The phi X A protein-[32P]DNA complex could be trapped as a protein-32P-oligonucleotide complex by the inclusion of ddGTP in reaction mixtures. In this report, the structure of the phi X A protein-32P-oligonucleotide complex has been analyzed. The DNA sequence of the oligonucleotide bound to the phi X A protein has been determined and shown to be homologous to the phi X (+) strand sequence immediately adjacent (3') to the replication origin. The phi X A protein was directly linked to the 5' position of a dAMP residue of the oligonucleotide; this residue corresponded to position 4306 of the phi X DNA sequence. The phi X A protein-32P-oligonucleotide complex was exhaustively digested with either trypsin or proteinase K and the 32P-labeled proteolytic fragments were analyzed. Each protease yielded two different 32P-labeled peptides in approximately equimolar ratios. The two 32P-labeled peptides formed after digestion with trypsin (designated T1 and T2) and with proteinase K (designated PK1 and PK2) were isolated and characterized. Digestion of peptide T1 with proteinase K yielded a product which co-migrated with peptide PK2. In contrast, peptide T2 was unaffected by digestion with proteinase K. These results suggest that the phi X A protein contains two active sites that are each capable of binding covalently to DNA. The peptide-mononucleotide complexes T1-[32P]pdA and T2-[32P]pdA were isolated and subjected to acid hydrolysis in 6.0 N HCl. In each case, the major 32P-labeled products were identified as [32P] phosphotyrosine and [32P]Pi. This indicates that each active site of the phi X A protein participates in a phosphodiester linkage between a tyrosyl moiety of the protein and the 5' position of dAMP.     

Functions of gene C and gene D products of bacteriophage phi X 174.

Phage-related materials existing in cells infected with various mutants of bacteriophage phi chi 174 were investigated. A novel species of replicative-form (RF) DNA was found in cells infected with a phage mutant of gene B, C, D, F, or G. This species, called RFI, sedimented at a position between RFI and RFII in a neutral sucrose gradient. It was converted to RFI upon denaturation in alkali, denaturation in formamide and subsequent renaturation, or RNase treatment at low ionic strength. In cells infected with a phage mutant of gene C, RFI was derived from pulse-labeled RFII after a short chase. TLLS INFECTED WITH A MUTANT OF GENE B, D, or F. A possible function of the C gene product of phi chi 174 could be to prevent the conversion of RFII to RFI, thereby maintaining the availability of RFII to act as the template for single-stranded viral DNA synthesis. A protein complex containing no DNA, which sedimented with an S value of 108 in a sucrose gradient and contained virion proteins F, G, and H, and nonvirion protein D, was found in cells infected with the gene C mutant. A possible function of protein D was considered as a scaffolding protein for assembly of phage structural proteins.     

Mutations in the gene encoding the adenovirus early region 1B 19,000-molecular-weight tumor antigen cause the degradation of chromosomal DNA

The adenovirus mutant Ad2ts111 has been previously shown to contain a mutation in the early region 2A gene encoding the single-stranded-DNA-binding protein that results in thermolabile replication of virus DNA and a mutation in early region 1 that causes degradation of intracellular DNA. A recombinant virus, Ad2cyt106, has been constructed which contains the Ad2ts111 early region 1 mutation and the wild-type early region 2A gene from adenovirus 5. This virus, like its parent Ad2ts111, has two temperature-independent phenotypes; first, it has the ability to cause an enhanced and unusual cytopathic effect on the host cell (cytocidal [cyt] phenotype) and second, it induces degradation of cell DNA (DNA degradation [deg] phenotype). The mutation responsible for these phenotypes is a single point mutation in the gene encoding the adenovirus early region 1B (E1B) 19,000-molecular-weight (19K) tumor antigen. This mutation causes a change from a serine to an asparagine in the 20th amino acid from the amino terminus of the protein. Three other mutants that affect the E1B 19K protein function have been examined. The mutants Ad2lp5 and Ad5dl337 have both the cytocidal and DNA degradation phenotypes (cyt deg), whereas Ad2lp3 has only the cytocidal phenotype and does not induce degradation of cell DNA (cyt deg+). Thus, the DNA degradation is not caused by the altered cell morphology. Furthermore, the mutant Ad5dl337 does not make any detectable E1B 19K protein product, suggesting that the absence of E1B 19K protein function is responsible for the mutant phenotypes. A fully functional E1B 19K protein is not absolutely required for lytic growth of adenovirus 2 in HeLa cells, and its involvement in transformation of nonpermissive cells to morphological variants is discussed.     

Interaction of the photosensitization products of oestrone with DNA: comparison with the horseradish peroxidase catalyzed reaction

The interaction with DNA of [4-14C]oestrone upon photosensitization with hematoporphyrin (HP) as a photosensitizer has been investigated. By means of Sephadex LH-20 gel filtration and extraction with dichloromethane it was found that, after irradiation (lambda greater than 425 nm) of a solution of HP, DNA and [4-14C]oestrone 21% of the radiolabel was associated with DNA. If DNA was added after irradiation 23% was bound to DNA, whereas 25% of the oestrone remained after photoreaction under the conditions applied. The binding occurs via the reactive 10 beta-hydroperoxy-1,4-estradien-3,17-dione, which is the only product after photosensitization of oestrone. The hydroperoxide has a strong interaction with DNA compared with that of other steroids. By repeated precipitation with 5 M NaCl and ethanol the association can be broken. It is reported, that binding of oestrone to protein induced by both photosensitization and horseradish peroxidase (HRPO)/H2O2 is irreversible, but that the amount of binding to DNA is dependent on the method of determination. However, neither the hydroperoxide nor its reduced product, a p-quinol, is intermediate or product in the HRPO catalyzed reaction of oestrogens. The tight association of the hydroperoxide product of oestrone with DNA, which may proceed via hydrogen bonding between the -OOH group and oxygen atoms of the backbone phosphate groups or of the furanose ring, might be a cause of chemical modification of DNA and of mutagenic effects.     

Evidence for the existence of a stable association between nascent DNA and the nuclear membrane of HeLa cells.

Nascent DNA-nuclear membrane complexes isolated from HeLa cells and solubilized in a sodium dodecyl sulfate-urea solution were examined by gel electrophoresis, column chromatography, isopycnic centrifugation, and by extraction with chloroform/methanol. Radioactivity attributable to [3H]DNA co-migrated with three protein peaks during electrophoresis. This radioactivity was eliminated by prior treatment with DNAase. In addition, all of the radioactivity attributable to nascent DNA eluted with a specific protein on Sepharose 4B columns. This DNA - protein complex banded at a density of 1.58 gm/cm3 in sucrose-CsCl gradients. Treatment with DNAase, phospholipase A and C, and dilute alkali disrupted the complex. Moreover, 93% of the radioactivity attributable to protein and 70% of that attributable to DNA could be extracted from the complex with a chloroform/methanol solution. The results suggest that nascent DNA may be in a stable association with a proteolipid moiety of the nuclear membrane.     

Identification of bacteriophage T4 gene 60 product and a role for this protein in DNA topoisomerase

Bacteriophage T4 DNA topoisomerase has been isolated and shown to contain the proteins coded by the DNA-delay genes 39 and 52 (Liu, L. F., Liu, C.-C., and Alberts, B. M. (1979) Nature (Lond.) 281, 456-461 and Stetler, G. L., King, G. J., and Huang, W. M. (1979) Proc. Natl. Acad. Sci. U. S. A. 76, 3737-3741). From complementation measurements in vitro and from earlier genetic evidence, these workers suggested that the product of gene 60 (p60) was also a component of the DNA topoisomerase complex. This paper now establishes the identity of p60 and unequivocally shows that this protein is a component of the enzyme complex. T4 DNA topoisomerase was purified by a simplified two-column procedure and found to be a stable complex of p39, p52, and a protein with a relative molecular weight of 18,000. The 18,000-dalton chain has been unambiguously shown to be the product of gene 60 through the use of an amber mutant of gene 60 with Sup+ and Sup- hosts and analyses by two-dimensional gel electrophoresis. While p39 and p52 were tightly associated in the wild type enzyme complex, they were readily separated on a hydroxylapatite column from extracts of cells infected by an amber mutant of gene 60. These findings suggest that p60 plays a structural/functional role in the enzyme complex by holding the larger p39 and p52 in juxtaposition.     

A new DNA polymerase species from Drosophila melanogaster: a probable mus308 gene product.

Harris et al. [P.V. Harris, O.M. Mazina, E.A. Leonhardt, R.B. Case, J.B. Boyd, K.C. Burtis, Molecular cloning of Drosophila mus308, a gene involved in DNA cross-link repair with homology to prokaryotic DNA polymerase I genes, Mol. Cell. Biol., 16 (1996) 5764-5771.] reported the molecular cloning of Drosophila mus308 gene, and its nucleotide and protein sequences similar to DNA polymerase I. In the present study, we attempted to find and isolate the gene product by purifying a DNA polymerase fraction not present in mus308 flies. A new DNA polymerase with properties different from those of any known polymerase species was identified and partially purified from the wild-type fly embryos through ten column chromatographies. The enzyme was resistant to aphidicolin, but sensitive to ddTTP and NEM. Human proliferating cell nuclear antigen (PCNA) and Drosophila replication protein A (RP-A) did not affect the polymerase activity. It preferred poly(dA)/oligo(dT) as a template-primer. The molecular mass was about 230 kDa with a broad peak region of 200 to 300 kDa in HiPrep16/30 Sephacryl S-300 gel filtration. These properties a different from those of all reported Drosophila polymerase classes such as alpha, beta, gamma, delta, epsilon and zeta and closely resemble those of the gene product expected from the nucleotide sequence. The new polymerase species appears to have ATPase and 3'-5' exonuclease activities as shown by the chromatographies.     

Rooster comb hyaluronate-protein, a non-covalently linked complex.

Hyaluronate from rooster comb was isolated by ion-exchange chromatography on DEAE-cellulose from tissue extracts and papain digests. The preparations were labelled with [14C]acetic anhydride and subjected to CsCl-density-gradient centrifugation in 4 M-guanidinium chloride in the presence and absence of 4% ZwittergentTM 3-12. A radioactive protein fraction was separated from the hyaluronate when the zwitterionic detergent was also present. The protein could also be separated from the glycosaminoglycan by chromatography on Sepharose CL-6B eluted with the same solvent mixture. The protein fraction contained three protein bands of Mr 15,000-17,000 as assessed by polyacrylamide-gel electrophoresis in 0.1% SDS, and seemed to lack lysozyme activity. No evidence of other protein or amino acid(s) covalently linked with the hyaluronate was obtained. The hyaluronate-protein complex may be re-formed upon mixing the components, the extent of its formation depending on the conditions used. The results show that, as in chondrosarcoma [Mason, d'Arville, Kimura & Hascall (1982) Biochem. J. 207, 445-457] and teratocarcinoma cells [Prehm (1983) Biochem. J. 211, 191-198] the rooster comb hyaluronate also is not linked covalently to a core protein.     

Role of polymeric forms of the bacteriophage phi X174 coded gene A protein in phi XRFI DNA cleavage.

Gene A of the phi X174 genome codes for two proteins, A and A* (Linney, E.A., and Hayashi, M.N. (1973) Nature New Biol. 245, 6-8) of molecular weights 60,000 and 35,000, respectively. The phi X A* protein is formed from a natural internal initiator site within the A gene cistron while the phi X A protein is the product of the entire A gene. These two proteins have been purified to homogeneity as judged by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Previous studies have shown that the phi X A protein is an endonuclease which specifically introduces a discontinuity in the A cistron of the viral strand of supertwisted phi XRFI DNA. In addition to this activity, the phi X A protein also causes relaxation of supertwisted phi XRFI DNA and formation of a phi XRFH DNA . phi X A protein complex which has a discontinuity in the A cistron of the viral strand. This isolatable complex supports DNA synthesis when supplemented with extracts of uninfected Escherichia coli which lack phi X A protein and phi XRFI DNA. The phi XRFII DNA . phi X A protein complex can be attacked by exonuclease III but is not susceptible to attack by E. coli DNA polymerase I, indicating that the 5'-end of the complex is blocked. Attempts to seal the RFII structure generated from the phi XRFII DNA . phi X A protein complex with T4 DNA ligase in the presence or absence of DNA polymerase were unsuccessful. The phi X A protein does not act catalytically in the cleavage of phi XRFI DNA. Under conditions leading to the quantitative cleavage of phi XRFI DNA, the molar ratio of phi XRFI DNA to added phi X A protein was approximately 1:10. At this molar ratio, cross-linking experiments with dimethyl suberimidate yielded 10 distinct protein bands which were multiples of the monomeric phi X A protein. In the absence of DNA or in the presence of inactive DNA (phi XRFII DNA) no distinct protein bands above a trimer were detected. We found it possible in vitro to form a phi XRFII DNA . phi X A protein complex with wild-type phi XRFI DNA (phi X A gene+) and with phi XRFI DNA isolated from E. coli (su+) infected with phage phi X H90 (an am mutant in the phi X A gene). Thus, in vitro, in contrast to in vivo studies, phi X A protein is not a cis acting protein. The purified phi X A* protein does not substitute for the phi X A protein in in vitro replication of phi XRFI DNA nor does it interfere with the action of the phi X A protein which binds only to supertwisted phi XRFI DNA. In contrast, the phi X A* protein binds to all duplex DNA preparations tested. This property prevents nucleases of E. coli from hydrolyzing duplex DNAs to small molecular weight products.     

Receptor-mediated gene delivery and expression in vivo

A soluble DNA carrier system was used to target a foreign gene specifically to liver in vivo via asialoglycoprotein receptors. The DNA carrier was prepared consisting of a galactose-terminal (asialo-)glycoprotein, asialoorosomucoid (AsOR), covalently linked to poly-L-lysine. The conjugate was complexed in a 2:1 molar ratio (based on AsOR content of the conjugate) to the plasmid, pSV2 CAT, containing the gene for the bacterial enzyme chloramphenicol acetyltransferase (CAT). Intravenous injection of [32P]plasmid DNA complexed to the carrier demonstrated specific hepatic targeting with 85% of the injected counts taken up by the liver in 10 min compared to only 17% of the counts when the same amount of [32P]DNA alone was injected under identical conditions. Targeted pSV2 CAT DNA was detected at a level of 1.0 ng/g liver by hybridization of a [32P]pSV2 CAT cDNA probe to rat liver DNA extracted 24 h after intravenous injection of AsOR-poly-L-lysine-DNA complex containing 1.0 mg of DNA. Homogenates of livers taken 24 h after injection of the complex revealed that the targeted CAT gene was functional as reflected by the detection of CAT activity (approximately 4 microunits/mg protein). Livers from control animals that received individual constituents of the complex produced no CAT activity. Simultaneous injection of excess AsOR to compete with the AsOR-poly-L-lysine-DNA complex for uptake by the liver inhibited CAT gene expression. Assays for CAT activity in other organs (spleen, kidney, lungs) failed to demonstrate any activity in these organs. This new soluble DNA carrier system can permit targeted delivery of foreign genes specifically to liver with resultant foreign gene expression in vivo.     

Molecular cloning and characterization of an alkalophilic Bacillus sp. C125 gene homologous to Bacillus subtilis sec Y.

A 1.8 kb HindIII DNA fragment containing the secY gene of alkalophilic Bacillus sp. C125 has been cloned into plasmid pUC119 using the B. subtilis secY gene as a probe. The complete nucleotide sequence of the cloned DNA indicated that it contained one complete ORF and parts of two other ORFs. The similarity of these ORFs to the sequences of the B. subtilis proteins indicated that they were the genes for ribosomal protein L15-SecY-adenylate kinase, in that order. The gene product of the alkalophilic Bacillus sp. C125 secY homologue was composed of 431 amino acids and its M(r) value has been calculated to be 47,100. The distribution of hydrophobic amino acids in the gene product suggested that the protein was a membrane integrated protein with ten transmembrane segments. The total amino acid sequence of alkalophilic Bacillus sp. C125 secY homologue showed 69.7% homology with that of B. subtilis secY. Regions of remarkably high homology (78% identity) were present in transmembrane regions, and cytoplasmic domains (73% identity) with less homologous regions present in extracellular domains (43% identity).     

Analysis of bacteriophage phi X174 gene A protein-mediated termination and reinitiation of phi X DNA synthesis. I. Characterization of the termination and reinitiation reactions

The phi X174 (phi X) gene A protein-mediated termination and reinitiation of single-stranded circular (SS(c] phi X viral DNA synthesis in vitro were directly and independently analyzed. Following incubation together with purified DNA replication enzymes from Escherichia coli, ATP, [alpha-32P]dNTPs, and either the phi X A protein and phi X replicative form I (RF I) DNA, or the purified RF II X A complex, the phi X A protein was detected covalently linked to newly synthesized 32P-labeled DNA. Formation of the phi X A protein-[32P]DNA covalent complex required all the factors necessary for phi X (+) SS(c) DNA synthesis in vitro. Thus, it was a product of the reinitiation reaction and an intermediate of the replication cycle. Identification of this complex provided direct evidence that reinitiation of phi X (+) strand DNA synthesis involved regeneration of the RF II X A complex. Substitution of 2',3'-dideoxyguanosine triphosphate (ddGTP) for dGTP in reaction mixtures resulted in the formation of covalent phi X A protein 32P-oligonucleotide complexes; these complexes were trapped analogues of the regenerated RF II X A complex. They could not act catalytically due to the presence of ddGMP residues at the 3'-termini of the oligonucleotide moieties. Reaction mixtures containing ddGTP also yielded nonradioactive (+) SS(c) DNA products derived from circularization of the displaced (+) strand of the input parental template DNA. The formation of the phi X A protein-32P-oligonucleotide complexes and nonradioactive (+) SS(c) DNA were used to assay both reinitiation and termination reactions, respectively. Both reactions required DNA synthesis from the 3'-hydroxyl primer at nucleotide residue 4305 which was formed by cleavage of phi X RF I DNA by the phi X A protein. Elongation of this primer by 18, but not 11 nucleotides was sufficient to support each reaction. Reinitiation reactions proceeded rapidly and were essentially complete after 90 s. In contrast, when ddGTP was replaced with dGTP in reaction mixtures, DNA synthesis proceeded with linear kinetics for up to 10 min. These results suggested that in the presence of all four dNTPs, active templates supported more than 40 rounds of DNA synthesis.