Membrane association and role in DNA uptake of the Bacillus subtilis PriA anaiogue ComF1

The late competence protein ComF1 is required for genetic transformation in Bacillus subtilis. Because of the sequence similarities of ComF1 to known ATP-dependent DNA helicases and translocases, we have hypothesized that this protein either unwinds bound double-stranded DNA or helps in the translocation of the transforming single-stranded DNA across the cell membrane. Two important implications of this hypothesis (the association of ComF1 with the membrane and its specific requirement for DNA uptake) have been tested in this report. Using cell fractionation techniques and Western blotting analysis, we show that ComF1 is located almost exclusively on the cell membrane and that it is membrane-targeted independently of other competence proteins. Moreover, ComF1 behaves like an integral membrane protein in extractability and detergent partition assays. We also show that this protein is required for the DNA-uptake step during transformation but not for DNA binding to the ceil surface. DNA uptake is blocked in strains with null mutations or in-frame deletions in comF1 but also in strains that overproduce the ComF1 protein under competence conditions. This last observation suggests that ComF1 expression must be balanced with that of other competence proteins, with which it may interact to form a multisubunit complex for DNA uptake.     

Multiple interactions among the competence proteins of Bacillus subtilis

Proteins required for transformation of Bacillus subtilis and other competent bacteria are associated with the membrane or reside in the cytosol. Previous work has shown that RecA, ComGA, ComFA and SsbB are directed to the cell poles in competent cells, and that the uptake of transforming DNA occurs preferentially at the poles. We show that ComGA, ComFA, DprA (Smf), SsbB (YwpH), RecA and YjbF (CoiA) are located at the cell poles, where they appear to colocalize. Using fluorescence resonance energy transfer, we have shown that these six competent (Com) proteins reside in close proximity to one another. This conclusion was supported by the effects of com gene knockouts on the stabilities of Com proteins. Data obtained from the com gene knockout studies, as well as information from other sources, extend the list of proteins in the transformation complex to include ComEC and ComEA. Because ComGA and ComFA are membrane-associated, while DprA, SsbB, RecA and YjbF are soluble, a picture emerges of a large multiprotein polar complex, involving both cytosolic and membrane proteins. This complex mediates the binding and uptake of single-stranded DNA, the protection of this DNA from cellular nucleases and its recombination with the recipient chromosome.     

Calcium-requiring step in the uptake of deoxyribonucleic acid molecules through the surface of competent pneumococci.

The conversion of surface-adsorbed deoxyribonucleic acid (DNA) molecules to a state in which they are inaccessible to exogenous deoxyribonuclease requires specifically calcium ions; magnesium ions cannot replace calcium ions. Virtually maximal levels of nuclease-resistant DNA binding and genetic transformation can be obtained in media free from magnesium and containing only calcium ions. It is suggested that the calcium-requiring process is the transport of DNA molecules across the plasma membrane. Magnesium ions stimulate both the loss of surface-adsorbed DNA to the medium and the extracellular degradation of DNA.     

Membrane location of a deoxyribonuclease implicated in the genetic transformation of Diplococcus pneumoniae.

The cellular localization of enzymes in Diplococcus pneumoniae was examined by fractionation of spheroplasts. A deoxyribonuclease implicated in the entry of deoxyribonucleic acid (DNA) into the cell during genetic transformation was located in the cell membrane. This enzyme, the major endonuclease of the cell (endonuclease I), which is necessary for the conversion of donor DNA to single strands inside the cell and oligonucleotides outside, thus could act at the cell surface. Another enzyme, the cell wall lysin (autolysin), was also found in the membrane fraction. Other enzymes, including amylomaltase, two exonucleases, and adenosine triphosphate-dependent deoxyribonuclease, and a restriction type endonuclease, were located in the cytosol within the cell. None of the enzymes examined were predominantly periplasmic in location. Spheroplasts were obtained spontaneously on incubation of pneumococcal cells in concentrated sugar solutions. The autolytic enzyme appears to be involved in this process. Cells that were physiologically competent to take up DNA formed osmotically sensitive spheroplasts two to three times faster than cells that were not in the competent state. Although some genetically incompetent mutants also formed spheroplasts more slowly, other such mutants formed them at the faster rate.     

Relationship Between Competence for Transformation of Bacillus subtilis with Native and Single-Stranded Deoxyribonucleic Acid

The response of populations of Bacillus subtilis to both native deoxyribonucleic acid (DNA) and denatured DNA was investigated at maximal competence and at various times during the development of compentency. The results indicate that competence for transformation with native and denatured DNA increases and decreases simultaneously. Competition occurs between native and single-stranded DNA during transformation, and the same cells in a population can be doubly transformed by DNA molecules of both configurations.     

Genetic basis for colonial variation in Neisseria gonorrhoeae.

When the piliated colony types of Neisseria gonorrhoeae, which predominate in recent isolates, were nonselectively subcultured in vitro, they gave rise to large numbers of nonpiliated, avirulent colonial variants. Evidence is presented to show that most of this variation occurs after active growth has ceased and that the variation is sensitive to the action of deoxyribonuclease. We suggest that this variation is a result of transformation. A second variation in colonial morphology involved differing levels of "colony opacity-associated proteins" in the outer membrane. This variation was also inhibited by the presence of deoxyribonuclease, but the genetic basis for it is not as yet clear.     

Isolation and characterization of mutants of Haemophilus influenzae deficient in an adenosine 5''-triphosphate-dependent deoxyribonuclease activity.

By a direct assay approach, mutants of Haemophilus influenzae Rd that are deficient in adenosine 5'-triphosphate-dependent deoxyribonuclease activity (add-) were isolated and characterized. A large proportion (50 to 90%) of the cells in cultures of these mutants failed to produce visible colonies when plated. An extensive analysis of the recombination proficiency of these strains revealed that the transformation frequency (transformants per competent cell) in the mutants was similar to that found in the wild type, but that the transformation efficiency (transformants per microgram of irreversibly bound deoxyribonucleic acid [DNA]) was reduced approximately fourfold. Sensitivities of the mutants to gamma rays, ultraviolet radiation, and methyl methane sulfonate were only slightly greater than wild-type levels. The rate of degradation of host DNA after ultraviolet irradiation was significantly reduced in the mutants. It is suggested that the adenosine 5'-triphosphate-dependent deoxyribonuclease in H. influenzae plays a nonessential role in DNA recombination and repair.     

RNA-Dependent DNA Polymerase Activity of RNA Tumor Viruses I. Directing Influence of DNA in the Reaction

The template requirements and deoxyribonucleic acid (DNA) products of the DNA polymerases isolated from Rauscher leukemia and avian myeloblastosis viruses have been examined. All DNA preparations or synthetic polydeoxynucleotides which are active as primers possess a duplex structure containing single-stranded regions with a 3'-hydroxyl terminus. Native DNA and fully single-stranded DNA are inactive; moreover, their activity is not enhanced by sonic oscillation or treatment with micrococcal nuclease, Neurospora nuclease, or low levels of deoxyribonuclease I. Poor DNA templates are activated by treatment with exonuclease III, large amounts of deoxyribonuclease I, or an endonuclease isolated from Rauscher viral preparations. In reactions primed with deoxyadenylate-deoxythymidylate copolymer, the product formed is covalently attached to primer strands, indicating that no new strands are initiated. DNA polymerase products formed with exonuclease III- or deoxyribonuclase I-treated DNA are duplex structures. Short single-stranded regions are completely filled in, whereas long single-stranded regions are only partly repaired. DNA preparations containing extensive single-stranded regions are poorly utilized as templates.     

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     

Presynapsis and synapsis of DNA promoted by the STP alpha and single-stranded DNA-binding proteins from Saccharomyces cerevisiae

We previously purified an activity from meiotic cell extracts of Saccharomyces cerevisiae that promotes the transfer of a strand from a duplex linear DNA molecule to complementary circular single-stranded DNA, naming it Strand Transfer Protein alpha (STP alpha) (Sugino, A., Nitiss, J., and Resnick, M. A. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 3683-3687). This activity requires no nucleotide cofactor but is stimulated more than 10-fold by the addition of yeast single-stranded DNA-binding proteins (ySSBs). In this paper, we describe the aggregation and strand transfer of double-stranded and single-stranded DNA promoted by STP alpha and ySSB. There is a good correlation between the aggregation induced by various DNA-binding proteins (ySSBs, DBPs and histone proteins) and the stimulation of STP alpha-mediated DNA strand transfer. This implies that the stimulation by ySSBs and other binding proteins is probably due to the condensation of single-stranded and double-stranded DNA substrates into coaggregates. Within these coaggregates there is a higher probability of pairing between homologous double-stranded and single-stranded DNA, favoring the initiation of strand transfer. The aggregation reaction is rapid and precedes any reactions related to DNA strand transfer. We propose that condensation into coaggregates is a presynaptic step in DNA strand transfer promoted by STP alpha and that pairing between homologous double- and single-stranded DNA (synapsis) occurs in these coaggregates. Synapsis promoted by STP alpha and ySSBs also occurs between covalently closed double-stranded DNA and single-stranded linear DNA as well as linear double-stranded and linear single-stranded DNAs in the absence of any nucleotide cofactors.     

Effect of ribonuclease on the association of deoxyribonucleic acid with the membrane in Escherichia coli.

The Mg-2+-Sarkosyl crystals (M band) procedure was used to study the effect of ribonuclease (RNase) A on the association of Escherichia coli deoxyribonucleic acid (DNA) with membrane. Incubation of gently prepared cell extracts with RNase results in the release of DNA from membrane. This effect appears to result from the activation, by RNase, of endonuclease I and subsequent limited activity of this deoxyribonuclease. In support of this explanation, it is demonstrated (i) that the extent of the RNase-induced loss of DNA from membrane is directly correlated with the endogenous level of endonuclease I, and (ii) that endonucleolytic activity occurs when gently lysed cell preparations are incubated in the presence of RNase.     

Molecular reasons for the regulation of the enzymatic activity of bovine pancreatic deoxyribonuclease I as studied by dynamic light scattering and fluorescent spectroscopy

The effect of catalytic bivalent and inhibitory monovalent cations on the interactions of bovine pancreatic deoxyribonuclease I with the circle single-stranded DNA of M13 phase was studied. It was found that monovalent cations affect the site of binding to DNA and the active center of the enzyme; in their presence, a break of the formation of the enzyme-substrate complex occurs. The results provide evidence that conformational changes of the protein molecule in all cases are more substantial that it could be expected from X-ray data published earlier.     

How does plasmid DNA penetrate cell membranes in artificial transformation process of Escherichia coli?

Artificial transformation of Escherichia coli with plasmid DNA in presence of CaCl2 is a widely used technique in recombinant DNA technology. However, exact mechanism of DNA transfer across cell membranes is largely obscure. In this study, measurements of both steady state and time-resolved anisotropies of fluorescent dye trimethyl ammonium diphenyl hexatriene (TMA-DPH), bound to cellular outer membrane, indicated heat-pulse (0 degrees C42 degrees C) step of the standard transformation procedure had lowered considerably outer membrane fluidity of cells. The decrease in fluidity was caused by release of lipids from cell surface to extra-cellular medium. A subsequent cold-shock (42 degrees C0 degrees C) to the cells raised the fluidity further to its original value and this was caused by release of membrane proteins to extra-cellular medium. When the cycle of heat-pulse and cold-shock steps was repeated, more release of lipids and proteins respectively had taken place, which ultimately enhanced transformation efficiency gradually up to third cycle. Study of competent cell surface by atomic force microscope showed release of lipids had formed pores on cell surface. Moreover, the heat-pulse step almost depolarized cellular inner membrane. In this communication, we propose heat-pulse step had two important roles on DNA entry: (a) Release of lipids and consequent formation of pores on cell surface, which helped DNA to cross outer membrane barrier, and (b) lowering of membrane potential, which facilitated DNA to cross inner membrane of E. coli.     

The genetic transformation machinery: composition, localization, and mechanism

Natural genetic transformation is widely distributed in bacteria. It is a genetically programmed process that is inherent to the species. Transformation requires a specialized membrane-associated machinery for uptake of exogenous double-stranded DNA. It also requires dedicated cytosolic proteins, some of which have been characterized only recently, for the processing of internalized single-stranded DNA fragments into recombination products. A series of observations made in Bacillus subtilis and Streptococcus pneumoniae led to the recent emergence of a picture of a unique, highly integrated machine localized at the cell poles. This dynamic machine, which we propose to name the transformasome, involves both membrane and cytosolic proteins, to internalize, protect, and process transforming DNA. This review attempts to summarize these recent observations with special emphasis on the early stages in DNA processing.     

Cell cycle regulated phosphorylation of RPA-32 occurs within the replication initiation complex.

The transition from G1 to S phase of the cell cycle may be regulated by modification of proteins which are essential for initiating DNA replication. One of the first events during initiation is to unwind the origin DNA and this requires a single-stranded DNA binding protein. RPA, a highly conserved multi-subunit single-stranded DNA binding protein, was first identified as a cellular protein necessary for the initiation of SV40 DNA replication. The 32 kDa subunit of RPA has been shown to be phosphorylated at the start of S phase. Using SV40 replication as a model, we have reproduced in vitro the S phase-dependent phosphorylation of RPA-32 and show that it occurs specifically within the replication initiation complex. Phosphorylated RPA-32 is predominantly associated with DNA. Phosphorylation is not a pre-requisite for association with DNA, but occurs after RPA binds to single-stranded DNA formed at the origin during the initiation phase. The protein kinase(s) which phosphorylates RPA-32 is present at all stages of the cell cycle but RPA-32 does not bind to the SV40 origin or become phosphorylated in extracts from G1 cells. Therefore, the cell cycle-dependent phosphorylation of RPA-32 may be regulated by its binding to single-stranded origin DNA during replication initiation.     

On the mechanism of pairing of single- and double-stranded DNA molecules by the recA and single-stranded DNA-binding proteins of Escherichia coli

The pairing of single- and double-stranded DNA molecules at homologous sequences promoted by recA and single-stranded DNA-binding proteins of Escherichia coli follows apparent first-order kinetics. The initial rate and first-order rate constant for the reaction are maximal at approximately 1 recA protein/3 and 1 single-stranded DNA-binding protein/8 nucleotides of single-stranded DNA. The initial rate increases with the concentration of duplex DNA; however, the rate constant is independent of duplex DNA concentration. Both the rate constant and extent of reaction increase linearly with increasing length of duplex DNA over the range 366 to 8623 base pairs. In contrast, the rate constant is independent of the size of the circular single-stranded DNA between 6,400 and 10,100 nucleotides. No significant effect on reaction rate is observed when a single-stranded DNA is paired with 477 base pairs of homologous duplex DNA joined to increasing lengths of heterologous DNA (627-2,367 base pairs). Similarly, heterologous T7 DNA has no effect on the rate of pairing. These findings support a mechanism in which a recA protein-single-stranded DNA complex interacts with the duplex DNA to produce an intermediate in which the two DNA molecules are aligned at homologous sequences. Conversion of the intermediate to a paranemic joint then occurs in a rate-determining unimolecular process.     

Band 3 tyr-phosphorylation in normal and glucose-6-phospate dehydrogenase-deficient human erythrocytes

Artificial transformation of Escherichia coli with plasmid DNA in presence of CaCl₂ is a widely used technique in recombinant DNA technology. However, exact mechanism of DNA transfer across cell membranes is largely obscure. In this study, measurements of both steady state and time-resolved anisotropies of fluorescent dye trimethyl ammonium diphenyl hexatriene (TMA-DPH), bound to cellular outer membrane, indicated heat-pulse (0°C→42°C) step of the standard transformation procedure had lowered considerably outer membrane fluidity of cells. The decrease in fluidity was caused by release of lipids from cell surface to extra-cellular medium. A subsequent cold-shock (42°C→0°C) to the cells raised the fluidity further to its original value and this was caused by release of membrane proteins to extra-cellular medium. When the cycle of heat-pulse and cold-shock steps was repeated, more release of lipids and proteins respectively had taken place, which ultimately enhanced transformation efficiency gradually up to third cycle. Study of competent cell surface by atomic force microscope showed release of lipids had formed pores on cell surface. Moreover, the heat-pulse step almost depolarized cellular inner membrane. In this communication, we propose heat-pulse step had two important roles on DNA entry: (a) Release of lipids and consequent formation of pores on cell surface, which helped DNA to cross outer membrane barrier, and (b) lowering of membrane potential, which facilitated DNA to cross inner membrane of E. coli.     

Transformation of Escherichia coli with plasmid deoxyribonucleic acid: calcium-induced binding of deoxyribonucleic acid to whole cells and to isolated membrane fractions.

Plasmid deoxyribonucleic acid (DNA) was tightly bound to cells of Escherichia coli at 0 degrees C in the presence of divalent cations. During incubation at 42 degrees C, 0.1 to 1% of this DNA became resistant to deoxyribonuclease. Deoxyribonuclease-resistant DNA binding and the ability to produce transformants became saturated when transformation mixtures contained 1 to 2 micrograms of plasmid NTP16 DNA and about 5 X 10(8) viable cells. Under optimum conditions, between 1 and 2 molecule equivalents of 3H-labeled NTP16 DNA per viable cell became deoxyribonuclease resistant. Despite this, only 0.1 to 1% of viable cells became transformed by saturating amounts of the plasmid. The results suggest that transport of DNA across the inner membrane is a limiting step in transformation. After transformation the bulk of labeled plasmid DNA remained associated with outer membranes. However, in vitro assays indicated that plasmid DNA would bind equally well to preparations of inner or outer membranes provided divalent cations were present to preparations of inner or outer membranes provided divalent cations were present. Divalent cations promoted differing levels of binding to isolated inner and outer membranes in the order Ca2+ much greater than Ba2+ greater than Sr2+ greater than Mg2+. This parallels their relative efficiencies in promoting transformation. Binding of plasmid DNA was greatly reduced when outer membranes were treated with trypsin; this suggests that protein components may be required for the binding or transport of DNA (or both) during transformation.     

A mammalian DNA polymerase alpha holoenzyme functioning on defined in vivo-like templates.

In analogy to the Escherichia coli replicative DNA polymerase III we define two forms of DNA polymerase alpha: the core enzyme and the holoenzyme. The core enzyme is not able to elongate efficiently primed single-stranded DNA templates, in contrast to the holoenzyme which functions well on in vivo-like template. Using these criteria, we have identified and partially purified DNA polymerase alpha holoenzyme from calf thymus and have compared it to the corresponding homogeneous DNA polymerase alpha (defined as the core enzyme) from the same tissue. The holoenzyme is able to use single-stranded parvoviral DNA and M13 DNA with a single RNA primer as template. The core enzyme, on the other hand, although active on DNAs treated with deoxyribonuclease to create random gaps, is unable to act on these two long, single-stranded DNAs. E. coli DNA polymerase III holoenzyme also copies the two in vivo-like templates, while the core enzyme is virtually inactive. The homologous single-stranded DNA-binding proteins from calf thymus and from E. coli stimulate the respective holoenzymes and inhibit the core enzymes. These results suggest a cooperation between a DNA polymerase holoenzyme and its homologous single-stranded DNA-binding protein. The prokaryotic and the mammalian holoenzyme behave similarly in several chromatographic systems.