Isolation and characterization of a membrane-DNA complex in the mitochondria of Physarum polycephalum

A membrane-DNA complex was isolated by centrifugation of sheared lysate of isolated mitochondria in 20-60% sucrose step solution. Analyses using Hoechst 33258/CsCl density gradient centrifugation and restriction endonuclease treatment showed that DNA in the membrane-DNA complex was AT-rich compared with total mitochondrial DNA (mt DNA) and contained Eco RI fragments of E-4, 5 and 8, which were localized on the right hand of Physarum mitochondrial genome. Phenethyl alcohol (PEA) and ethidium bromide (EB) could disrupt the membrane-DNA complex to release DNA fragments from their complex in vitro. Addition of 0.5% or more PEA, which released 80-90% of the DNA from the membrane-DNA complex in vitro, inhibited not only mitochondrial nuclear division but also mitochondrial division in vivo. EB treatment at more than 1 mg/ml disrupted the membrane-DNA complex in vitro to release 77% of the total DNA in the complex. Addition of 10 micrograms/ml EB induced unequal mitochondrial nuclear division in the microplasmodia, e.g., a dividing dumbbell-shaped mitochondrion had the mt-nucleus in one side and as a result formed then one nucleated and one enucleated mitochondrion. From the EB-pretreated mitochondria, a lesser amount of the membrane-DNA complex was isolated than from the control. These findings mean than the unequal mt-nuclear division is due to dissociation of DNA and the membrane system in the membrane-DNA complex. They strongly suggested that the DNA region (E-4, 5 and 8), where the mitochondrial nucleus is associated with the mitochondrial membrane system plays an important role in mitochondrial nuclear division.     

DNA Replication by a membrane-DNA complex from rat liver mitochondria

The results presented here indicate that mitochondrial DNA (mtDNA) synthesis occurs on the inner mitochondrial membrane and that a membrane-DNA complex, enriched in newly synthesized DNA, can be isolated. The complex is able to synthesize DNA in vitro. Enrichment studies demonstrated that mtDNA synthesis occurs on an intact membrane-DNA complex in vitro and that pulse-labeled mtDNA could be chased from the membrane-DNA complex to the top fraction of the discontinuous sucrose gradient. The membrane-DNA complex was also shown to carry out replicative synthesis of mtDNA in vitro. Replication was shown to be asynchronous with heavy-strand synthesis preceding light-strand synthesis. The progression of mtDNA replication by the membrane-DNA complex was shown to be from small fragments (<13 S) to larger fragments (14–24 S) liberated from closed circular molecules, to a heat-stable 27 S molecule, and finally to a 38 S heat-stable molecule. The time estimated to progress from small fragments to the 38 S molecule is 120 min.     

An unstable donor-recipient DNA complex in transformation of Bacillus subtilis.

Summary In re-extracted DNA obtained shortly after uptake of transforming DNA by Bacillus subtilis, increased amounts of donor DNA radioactivity banding at the position of donor-recipient DNA complex (DRC) are observed in CsCl gradients, if the cells are irradiated with high doses of UV prior to reextraction of the DNA. Qualitatively, the same phenomenon is observed if lysates of transforming cells are irradiated. UV-irradiation of lysates of competent cells to which single-stranded DNA is added after lysis, does not result in linkage of this DNA to the chromosomal DNA. Two observations argue in favour of the formation of a specific labile complex between donor and resident DNA during transformation. Firstly, heterologous donor DNA from Escherichia coli, although being processed to single-stranded DNA in competent B. subtilis, does not seem to be linked to the recipient chromosome upon UV-irradiation, and secondly, the labile complex of donor and recipient DNA can be stabilized by means of treatment of the lysates of transforming cells with 4, 5¹, 8-trimethylpsoralen in conjuction with long-wave ultra violet light irradiation. This indicates that base-pairing is involved in the formation of the complex. On the basis of these results we assume that the unstable complex of donor and recipient DNA is an early intermediate in genetic recombination during transformation.     

Transformation in Bacillus subtilis: properties of DNA-binding-deficient mutants

Transformation-deficient mutants of Bacillus subtilis were selected after replica plating on agar plates containing transforming DNA. Out of 24 mutants tested, 3 showed highly reduced abilities to bind donor DNA; the residual levels of binding were similar to those of noncompetent cells. Transformation and transfection were reduced to nondetectable levels in the mutants. However, transduction with phage SPP1 occurred at normal frequencies. The nuclease activities involved in entry of donor DNA were present in the mutants. Comparison of protein patterns by two-dimensional gel electrophoresis revealed the absence of one major protein in the mutants as compared with the wild-type strain. This protein (molecular weight, approximately 18,000; isoelectric point, 5.0) appeared to be membrane associated. The protein was specific for competent cells, suggesting that it is involved in the binding of donor DNA.     

Initiation of recombination during transformation of Bacillus subtilis requires no extensive homologous sequences

Summary Lysates obtained shortly after entry of transforming DNA to Bacillus subtilis contain donor-recipient DNA complexes, in which the donor moiety is associated with the recipient DNA in an unstable way. The complexes could be artificially stabilized by crosslinking with 4,5,8-trimethylpsoralen. The unstable complexes dissociated upon helix-destabilizing treatments, such as heating at 70°C, and CsCl gradient centrifugation at pH 11.2, but remained stable during CsCl gradient centrifugation at pH 10. Donor-recipient DNA complexes were not formed after entry of heterologous pUB110 DNA. These observations suggest that base-pairing is involved in the unstable association. The donor moiety of the unstable complexes was completely, or almost completely, digestible by nuclease S₁, indicating that the donor and recipient base-sequences are only paired over very short distances.The unstable donor-recipient DNA complexes are true recombination intermediates because (i) strain 7G224 (recE4) was impaired in the formation of the unstable complexes, and (ii) the unstable complexes were rapidly converted to stable complexes in recombination proficient strains, whereas their conversion was delayed in the recombination deficient strain 7G84.Unstable complexes were also formed with Escherichia coli donor DNA, but to a lesser extent. Apparently a limited degree of base-sequence homology is sufficient to initiate recombination.     

Involvement of single-strand breaks in complex formation between single-stranded DNA and nucleoids of Bacillus subtilis

Summary RNase-unfolded chromosomes of competent Bacillus subtilis are able to take up single-stranded homologous donor DNA fragments in vitro to form donor-recipient DNA complexes (Van Randen and Venema 1981). The unfolded chromosomes behave as supercoiled DNA molecules. X-irradiation increased the formation of unstable and stable complexes between donor and recipient DNA during incubation at 37° C. The complex-forming ability of the unfolded chromosomes increased linearly with increasing X-ray dose, even after complete relaxation of the unfolded chromosomes had occurred. Limited DNase I action increased the complex-forming ability of the chromosomes as effectively as X-irradiation.Unstable donor-recipient DNA complexes can be distinguished from stable ones by their dissociation upon density gradient centrifugation in CsCl at pH 11.2. They are stable at pH 10 (Van Randen et al. 1982a). At an intermediate pH value during isopycnic centrifugation, a fraction of the unstable complexes were stable, suggesting that a range of stabilities existed among the unstable complexes. The donor moiety of the stable donor-recipient DNA complexes was far more resistant to nuclease S1 treatment than that of the unstable ones.     

The character of protein-nucleic interaction in relation to the mtDNA-membrane complex

Summary Specific sites that interact with structural proteins of the mitochondrial inner membrane were found in mitochondrial DNA (mtDNA) of rat liver. Analysis of the isolated DNA fragments revealed their capacity to form a complex with membrane proteinsin vitro and allowed the detection of a protein with a molecular weight 40,000. The size of the fragments was found to be 12–18 nucleotide pairs with an average molecular weight 10,000 MtDNA sites recognized by membrane protein proved to be quite unique in having a secondary structure, a high content of AT sequences (82%) and oligopyrimidine blocks. It was shown that the light mtDNA strand, rich in adenine, is 60% more active in the binding with membrane mitochondria than the heavy one.     

Characteristics of a complex formed by a nonintegrated fraction of transforming DNA and Bacillus subtilis recipient cell constituents.

Summary Nonintegrated transforming DNA was isolated from recipient cell lysates as a complex with cellular constituents (natural complex) and separated from free proteins on CsCl density gradients. Sensitivity of DNA in this complex to digestion with endonuclease S₁, liberation of denatured donor molecules by treatment of the cell lysates with phenol, as well as previously described liberation of single-stranded donor DNA by heating with detergents, pointed to the single-stranded nature of the donor DNA in the complex. About 1% of radioactive leucine or phenylalamine incorporated to cellular proteins were detected in the natural complex, with two associated enzymatic activities: one autolytic, the other endonucleolytic. The autolytic activity, known to be localized mainly in the cell wall and the endonucleolytic one, similar to the enzyme localized in cell membrane and periplasmic space of B. subtilis, suggest that donor DNA is complexed with a cell wall and/or a cell membrane fragment. Consideration of several characteristics of the natural complex: its density, protein content, and partial resistance of its DNA to DNase I, point to partial shielding of donor DNA in the cell fragment structure, and existence of a portion in a free uncovered form. Considerations on the possible role of the two enzymatic activities were based on the fact that they were not found in the complex formed by denatured DNA added to cells before lysis (reconstruction complex), and on hypotheses of their possible physioligical role.Part of the above results was presented in preliminary form at the Third European Meeting on Bacterial Transformation and Transfection, Granada, Spain, August 31–September 3, 1976     

Molecular fate of heterologous bacterial DNA in competent Bacillus subtilis: further characterization of unstable association between donor and recipient DNA and the involvement of the cellular membrane

Summary Although heterospecific transformation is extremely inefficient and very little heterologous donor DNA integrates into the recipient chromosome in a stable way, we have previously shown that B. pumilus DNA entering competent B. subtilis efficiently associates with the recipient chromosome in an unstable way. This association can be stabilized by photocrosslinking in the presence of 4,5,8-trimethylpsoralen; it depends on the recombination proficiency of the recipient strain and on strand-separation of the recipient chromosome (te Riele and Venema 1982b). The present study provides further evidence that the heterologous donor DNA and the recipient DNA are associated by regions of base-pairing. Based on the high sensitivity of the donor moiety in the complex to nuclease S1 (90%) and the high sensitivity of the complex to moderate denaturing conditions (Tm=48°C), we presume that donor and recipient DNA are associated either by several short sequences of 15–25 fairly well matched base pairs or by a region of base-pairing of about 200 bases, which contains 25% of mismatches. During incubation, the unstable complex disappears, probably due to nucleolytic degradation.The unstable heterologous donor-recipient complex (DRC) was found to be membrane-bound. However, in contrast to homologous DRC, the unstable heterologous DRC remains membrane bound during incubation. Apparently, the predominantly single-stranded character of the heterologous DRC prevents release of the complex from the membrane.Abbreviations DRC donor-recipient complex - TMP 4,5,8-trimethyl-psoralen - DNAase I deoxyribonuclease 1 - TCA trichloroacetic acid     

Fate of transforming DNA following uptake by competent Bacillus subtilis. I. Formation and properties of the donor-recipient complex

Following uptake by competent Bacillus subtilis, transforming DNA is converted to two distinct slowly sedimenting molecular forms which possess little transforming activity (eclipse). A few minutes after uptake is initiated, a physical complex of donor and recipient DNA begins to form. The recovery of donor transforming activity following eclipse, and the appearance of recombinant activity, previously reported by Venema, Pritchard &; Venema-Schröder (1965), is shown to be due to changes occurring in the donor—recipient complex. This complex exists transiently in a form with low recombinant-type transforming activity. This transient form may be one in which the donor and recipient components are joined non-covalently. The donor-recipient complex is shown to be a heteroduplex structure in which the donor moiety has an approximate molecular weight of 750,000.     

Involvement of single-strand breaks in complex formation between single-stranded DNA and nucleoids of Bacillus subtilis

Molecular Genetics and Genomics - RNase-unfolded chromosomes of competent Bacillus subtilis are able to take up single-stranded homologous donor DNA fragments in vitro to form donor-recipient DNA...     

Transformation in Bacillus subtilis: involvement of the 17-kilodalton DNA-entry nuclease and the competence-specific 18-kilodalton protein.

A protein complex, consisting of a 17-kilodalton (kDa) nuclease and an 18-kDa protein, is believed to be involved in the binding and entry of donor DNA during transformation of Bacillus subtilis (H. Smith, K. Wiersman, S. Bron, and G. Venema, J. Bacteriol. 156:101-108, 1983). In this paper, the nucleotide sequences of the genes encoding both the nuclease and the 18-kDa protein are presented. The genes are encoded by a 904-base-pair PstI-HindIII fragment. The open reading frames encoding both proteins are partly overlapping. A B. subtilis mutant was constructed by insertion of a Cmr marker into the gene encoding the nuclease. This mutant lacked the competence-specific nuclease activity and the 18-kDa protein but retained 5% residual transformation. The total DNA association of the mutant was higher than that of the wild-type cells, and DNA entry was reduced to 30% of the wild-type level. These results suggest that an alternative pathway exists for the internalization of transforming DNA. A mutant, exclusively deficient for the 18-kDa protein, previously suggested to be involved in the binding of transforming DNA, was constructed by insertion of a kanamycin resistance gene into the coding sequence of the gene. Since the mutant showed wild-type DNA-binding activity, the 18-kDa protein is probably not involved in the binding of donor DNA to competent cells. The transforming activity of the mutant was reduced to 25% of the wild-type level, indicating that the 18-kDa protein has a function in the transformation process. In vitro experiments showed that the 18-kDa protein is capable of inhibiting the activity of the competence-specific nuclease. Its possible role in transformation is discussed.     

Quaternary structure of coronavirus spikes in complex with carcinoembryonic antigen-related cell adhesion molecule cellular receptors

Oligomeric spike (S) glycoproteins extend from coronavirus membranes. These integral membrane proteins assemble within the endoplasmic reticulum of infected cells and are subsequently endoproteolyzed in the Golgi, generating noncovalently associated S1 and S2 fragments. Once on the surface of infected cells and virions, peripheral S1 fragments bind carcinoembryonic antigen-related cell adhesion molecule (CEACAM) receptors, and this triggers membrane fusion reactions mediated by integral membrane S2 fragments. We focused on the quaternary structure of S and its interaction with CEACAMs. We discovered that soluble S1 fragments were dimers and that CEACAM binding was entirely dependent on this quaternary structure. However, two differentially tagged CEACAMs could not co-precipitate with the S dimers, suggesting that binding sites were closely juxtaposed in the dimer (steric hindrance) or that a single CEACAM generated global conformational changes that precluded additional interactions (negative cooperativity). CEACAM binding did indeed alter S1 conformations, generating alternative disulfide linkages that were revealed on SDS gels. CEACAM binding also induced separation of S1 and S2. Differentially tagged S2 fragments that were free of S1 dimers were not co-precipitated, suggesting that S1 harbored the primary oligomerization determinants. We discuss the distinctions between the S.CEACAM interaction and other virus-receptor complexes involved in receptor-triggered entry.     

A sensitive and rapid gel retention assay for nuclear factor I and other DNA-binding proteins in crude nuclear extracts.

The paper describes a rapid and sensitive assay for DNA binding proteins which interact with specific and defined binding sites. It exploits the observation that complexes of proteins and small synthetic DNA fragments (40 bp) containing the protein/DNA binding site can enter native polyacrylamide gels and remain stably associated during electrophoresis under non-denaturing conditions. The assay was applied to nuclear factor I, to its identification and purification from porcine liver, to an analysis of its binding site on adenovirus type 5 DNA and to an exploration of other potential binding sites for DNA binding proteins within the inverted terminal repetition of adenovirus DNA. The extreme sensitivity of the assay which surpasses that of conventional footprint assays by at least two orders of magnitude permitted the identification of nuclear factor I-like activities in Saccharomyces cerevisiae.     

A 10S particle released from deoxyribonuclease-sensitive regions of HeLa cell nuclei contains the 86-kilodalton-70-kilodalton protein complex

Digestion of HeLa cell nuclei with micrococcal nuclease or deoxyribonuclease I (DNase I) released the 86-kilodalton-70-kilodalton (kDa) protein complex in particles sedimenting at approximately 10 S in sucrose density gradients. Immunoaffinity-purified 32P-labeled complexes contained 86- and 70-kDa polypeptides with phosphorylated serine residues and DNA fragments, of which the largest was 110 base pairs long. Digestion of nick-translated nuclei with micrococcal nuclease released 32P-labeled 10S particles that were immunoaffinity-purified; they contained labeled 110-base-pair DNA fragments. The micrococcal nuclease digests were analyzed by two-dimensional electrophoresis, which separated nucleosomes in the first dimension and the associated proteins in the second. Western blots of the separated proteins showed that the 86-kDa-70-kDa complex was associated with the mono-, di-, and trinucleosomes. A more extensive electrophoretic separation revealed that the 10S particle from nick-translated nuclei migrated with a subfraction of the mononucleosomes that lacked H1 histones. These results suggest that the 10S particle which contains the 86-kDa-70-kDa complex is associated with an unfolded nucleosome that is present in DNase I sensitive regions.     

Transformation in Bacillus subtilis: a 75,000-dalton protein complex is involved in binding and entry of donor DNA.

A 75,000-dalton protein complex involved in DNA binding during transformation was purified from membranes of competent Bacillus subtilis cells. Previous results (Smith et al., J. Bacteriol. 156:101-108, 1983) showed that the complex contained two polypeptides, polypeptide a (molecular weight, 18,000; isoelectric point, 5.0) and polypeptide b (molecular weight, 17,000; isoelectric point, 4.7) in approximately equal amounts. In the present experiments the two polypeptides were extracted from two-dimensional gels and studied separately and in combination with respect to DNA binding and nuclease activities. For DNA binding the interaction of both polypeptides was required. DNA binding occurred efficiently in the presence of EDTA. Nuclease activity was restricted to polypeptide b. The nucleolytic properties of b were identical to those of the native 75,000-dalton complex. Polypeptide a affected b by reducing its nuclease activity. Analysis of the nuclease subunit b on DNA-containing polyacrylamide gels revealed nuclease activities at four different molecular weight positions. These activities were identical to the major competence-specific nuclease activities which were previously implicated in the entry of donor DNA during transformation (Mulder and Venema, J. Bacteriol. 152:166-174, 1982). These results indicate that the 75,000-dalton protein complex is composed of two different competence-specific polypeptides involved in both binding and entry of donor DNA. The possible roles of the two polypeptides in the transformation of B. subtilis are discussed.     

Restriction Enzyme Mapping of Carcinogen Binding Regions on pBR322

Abstract

Previous equilibrium binding experiments (S.A. Winkle and T.R. Krugh, Nucleic Acids Res. 9, 3175–3186 (1981)) suggested that the carcinogen N-hydroxy-N-acetyl-2-aminofluorene might exhibit preferential binding to a small number of sites on phiXl 74 DNA To examine whether the covalently binding analogue N-acetoxy-N-acetyl-2-aminofluorene (acetoxyAAF) also possesses high affinity sites, the plasmid pBR322 was reacted with 3H labeled acetoxyAAF to give one to sixteen adducts per DNA molecule. Thus only higher affinity sites would be affected. The DNA was subsequently cleaved with either Alu I, Hae III, Hha I, Hinf I or Hpa II restriction endonuclease and the restriction fragments isolated by gel electrophoresis. Examination of the distribution of 3H acetoxyAAF among the fragments was not random but, rather, with each enzyme, the acetoxyAAF was found predominantly in a few fragments. The locations of the bands containing the acetoxyAAF for each enzyme overlap - suggesting that there are regions on pBR 322 which contain high affinity sites for acetoxyAAF binding.     

A cell surface receptor complex for collagen type I recognizes the Arg- Gly-Asp sequence

To isolate collagen-binding cell surface proteins, detergent extracts of surface-iodinated MG-63 human osteosarcoma cells were chromatographed on affinity matrices of either type I collagen-Sepharose or Sepharose carrying a collagen-like triple-helical peptide. The peptide was designed to be triple helical and to contain the sequence Arg-Gly-Asp, which has been implicated as the cell attachment site of fibronectin, vitronectin, fibrinogen, and von Willebrand factor, and is also present in type I collagen. Three radioactive polypeptides having apparent molecular masses of 250 kD, 70 kD, and 30 kD were distinguishable in that they showed affinity toward the collagen and collagen-like peptide affinity columns, and could be specifically eluted from these columns with a solution of an Arg-Gly-Asp-containing peptide, Gly-Arg-Gly-Asp-Thr-Pro. These collagen-binding polypeptides associated with phosphatidylcholine liposomes, and the resulting liposomes bound specifically to type I collagen or the collagen-like peptide but not to fibronectin or vitronectin or heat-denatured collagen. The binding of these liposomes to type I collagen could be inhibited with the peptide Gly-Arg-Gly-Asp-Thr-Pro and with EDTA, but not with a variant peptide Gly-Arg-Gly-Glu-Ser-Pro. We conclude from these data that these three polypeptides are membrane molecules that behave as a cell surface receptor (or receptor complex) for type I collagen by interacting with it through the Arg-Gly-Asp tripeptide adhesion signal. The lack of binding to denatured collagen suggests that the conformation of the Arg-Gly-Asp sequence is important in the recognition of collagen by the receptor complex.     

Characterization of a full-length petunia cDNA encoding a polypeptide of the light-harvesting complex associated with photosystem I

We have isolated and characterized a full-length cDNA clone (LHCI-15) which specifies a new chlorophyll-binding protein. This protein is associated with the light-harvesting complex of photosystem I (LHCI). The DNA sequence predicts a precursor protein of 270 amino acids, which shares significant homology with the amino acid sequence of another chlorophyll-binding protein; the chlorophyll a/b-binding (Cab) protein of the photosystem II light-harvesting complex (LHCII). There are two extensive regions of homology (at least 45 residues each) which have approximately 50% amino acid sequence identity. These regions coincide with two of the proposed membrane-spanning alpha helices in the Cab proteins of the LHCII and probably include conserved chlorophyll-binding sites. The LHCI-15 cDNA hybridizes to at least 7 genomic EcoRI DNA fragments, which are very closely related at the nucleotide sequence level.     

Ligand-induced formation of the leukotriene B4 receptor-G protein complex of human polymorphonuclear leukocytes.

The components of the polymorphonuclear leukocyte (PMNL) receptor for leukotriene B4 (LTB4) were examined by Sephacryl S-300 exclusion chromatography of PMNL membrane proteins, which were solubilized before and after the binding of [3H] LTB4. When the PMNL membranes were solubilized in 3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonate (CHAPS) and filtered on Sephacryl S-300 prior to addition of [3H] LTB4, the binding activity was associated with a 65 kD protein. In contrast, the radioactivity of [3H] LTB4 bound to PMNL membranes prior to solubilization was recovered predominantly with a 140 kD protein. When PMNL membranes had been pretreated with pertussis toxin, but not cholera toxin, before the addition of LTB4 and subsequent solubilization, radioactivity was recovered predominantly with the 65 kD protein. The addition of guanylylimidodiphosphate (GMP-PNP), a nonhydrolyzable derivative of guanosine triphosphate (GTP), to PMNL membrane receptors bearing [3H] LTB4 either prior to or after CHAPS solubilization reduced the yield of the 140 kD presumed LTB4 receptor protein-G protein complex. That the maximum specific binding of [35S] guanosine-5'-0-3-thiotriphosphate (GTP-gammaS) to LTB4-binding proteins in the Sephacryl S-300 effluent corresponded to the 140 kD protein supported the presence of a G protein in the LTB4 receptor complex.