Localization of a DNA-binding determinant in the bacteriophage P22 Erf protein

Four amber fragments of the recombination-promoting P22 Erf protein were characterized. The intact Erf monomer contains 204 amino acids. The amber mutations produce fragments of 190, 149, 130 and 95 amino acid residues, all of which are inactive in vivo. The 190 residue fragment is more susceptible to proteolysis in cell extracts than is intact Erf. It breaks down to a stable remnant that is slightly larger than the 149 residue fragment. The 149 and 130 residue fragments are stable; electron microscopy of the purified fragments reveals that they have similar morphologies, retaining the ring-like oligomeric structure, but lacking the tooth-like protruding portions of intact Erf. Intact Erf and the 149 residue fragment have similar affinities for single-stranded DNA; the affinity of the 130 residue fragment is 40-fold lower in low salt at pH 6.0. The 95 residue fragment is unstable in vivo. These observations, combined with previous observations, are interpreted as suggesting that the boundary of the amino-terminal domain of the protein lies between residues 96 and 130, that certain residues between 131 and 149 form part of an interdomain DNA-binding segment of the protein, that the boundary of the carboxy-terminal domain lies to the C-terminal side of residue 149, and that the carboxy-terminal domain is not necessary for assembly of the ring oligomer, although it is essential for Erf activity in vivo.     

Increase of the DNA strand assimilation activity of recA protein by removal of the C terminus and structure-function studies of the resulting protein fragment

A proteolytic fragment of recA protein, missing about 15% of the protein at the C terminus, was found to promote assimilation of homologous single-stranded DNA into duplex DNA more efficiently than intact recA protein. This difference was not found if Escherichia coli single-stranded DNA binding protein was present. The ATPase activity of both intact recA protein and the fragment was identical. The difference in strand assimilation activity cannot be due to differences in single-stranded DNA affinity, since both the fragment and intact proteins bind to single-stranded DNA with nearly identical affinities. However, the fragment was found to bind double-stranded DNA more tightly and to aggregate more extensively than recA protein; both of these properties may be important in strand assimilation. Aggregation of the fragment was extensive in the presence of duplex DNA under the same condition where recA protein did not aggregate. The double-stranded DNA binding of both recA protein and the fragment responds to nucleotide cofactors in the same manner as single-stranded DNA binding, i.e. ADP weakens and ATP gamma S strengthens the association. The missing C-terminal region of recA protein includes a very acidic region that is homologous to other single-stranded DNA binding proteins and which has been implicated in DNA binding modulation. This C-terminal region may serve a similar function in recA protein, possibly inhibiting double-stranded DNA invasion. The possible role of the enhanced double-stranded DNA affinity of the fragment protein in the mechanism of strand assimilation is discussed.     

Studies of the strand-annealing activity of mammalian hnRNP complex protein A1.

A1 is a major core protein of the mammalian hnRNP complex, and as a purified protein of approximately 34 kDa, A1 is a strong single-stranded nucleic acid binding protein. Several lines of evidence suggest that the protein is organized in discrete domains consisting of an N-terminal segment of approximately 22 kDa and a C-terminal segment of approximately 12 kDa. Each of these domains as a purified fragment is capable of binding to both ssDNA and RNA. We report here that A1 and its C-terminal domain fragment are capable of potent strand-annealing activity for base-pair complementary single-stranded polynucleotides of both RNA and DNA. This effect is not stimulated by ATP. Compared with A1 and the C-terminal fragment, the N-terminal domain fragment has negligible annealing activity. These results indicate that A1 has biochemical activity consistent with a strand-annealing role in relevant reactions, such as pre-mRNA splicing.     

Spectroscopic studies of the structural domains of mammalian DNA beta-polymerase

The 8- and 31-kDa fragments of beta-polymerase, prepared by controlled proteolysis as described (Kumar, A., Widen, S. G., Williams, K. R., Kedar, P., Karpel, R. L., and Wilson, S. H. (1990) J. Biol. Chem. 265, 2124-2131), constitute domains that are structurally and functionally dissimilar. There is little disruption of secondary structure upon proteolysis of the intact enzyme, as suggested from CD spectra of the fragments. beta-Polymerase is capable of binding both single- and double-stranded nucleic acids: the 8-kDa fragment binds specifically to single-stranded lattices, whereas the 31-kDa domain displays affinity exclusively for double-stranded polynucleotides. These domains are connected by a highly flexible protease-hypersensitive segment that may allow the coordinate functioning of the two binding activities in the intact protein. beta-Polymerase binds to poly(ethenoadenylic acid) with higher affinity, similar cooperativity, but lesser salt dependence than the 8-kDa fragment. Under physiological conditions, the intact enzyme displays greater binding free energy for single-stranded polynucleotides than the 8-kDa fragment, suggesting that the latter may carry a truncated binding site. Binding of double-stranded calf thymus DNA brings about a moderate quenching of the Tyr and Trp fluorescence emission of both the 31-kDa fragment and beta-polymerase and induces a 6-nm blue shift in the Trp emission maximum of the intact enzyme, but not in the fragment. This latter result is likely due to a change in the relative orientation of the 8- and 31-kDa domains in the intact protein upon interaction with double-stranded DNA; alternatively, the binding mode of intact protein may differ from that of the fragment. Simultaneous interaction of both domains with polynucleotides most likely does not occur since double-stranded DNA binding to the 31-kDa domain of intact beta-polymerase induces the displacement of single-stranded polynucleotides from the 8-kDa domain. These results are evaluated in light of the role of beta-polymerase in DNA repair.     

Mammalian heterogeneous nuclear ribonucleoprotein A1. Nucleic acid binding properties of the COOH-terminal domain

A1 is a core protein of the eukaryotic heterogeneous nuclear ribonucleoprotein complex and is under study here as a prototype single-stranded nucleic acid-binding protein. A1 is a two-domain protein, NH2-terminal and COOH-terminal, with highly conserved primary structure among vertebrate homologues sequenced to date. It is well documented that the NH2-terminal domain has single-stranded DNA and RNA binding activity. We prepared a proteolytic fragment of rat A1 representing the COOH-terminal one-third of the intact protein, the region previously termed COOH-terminal domain. This purified fragment of 133 amino acids binds to DNA and also binds tightly to the fluorescent reporter poly(ethenoadenylate), which is used to access binding parameters. In solution with 0.41 M NaCl, the equilibrium constant is similar to that observed with A1 itself, and binding is cooperative. The purified COOH-terminal fragment can be photochemically cross-linked to bound nucleic acid, confirming that COOH-terminal fragment residues are in close contact with the polynucleotide lattice. These binding results with isolated COOH-terminal fragment indicate that the COOH-terminal domain in intact A1 can contribute directly to binding properties. Contact between both COOH-terminal domain and NH2-terminal domain residues in an intact A1:poly(8-azidoadenylate) complex was confirmed by photochemical cross-linking.     

Regulation of dnaB function in DNA replication in Escherichia coli by dnaC and lambda P gene products

The dnaB protein of Escherichia coli, a multifunctional DNA-dependent ribonucleotide triphosphatase and dATPase, cross-links to ATP on ultraviolet irradiation under conditions that support rNTPase and dATPase activities of dnaB protein. The covalent cross-linking to ATP is specifically inhibited by ribonucleotides and dATP. Tryptic peptide mapping demonstrates that ATP cross-links to only the 33-kDa tryptic fragment (Fragment II) of dnaB protein. The presence of single-stranded DNA alters the covalent labeling of dnaB protein by ATP, suggesting a possible role of DNA on the mode of nucleotide binding by dnaB protein. Present studies demonstrate that the dnaC gene product binds ribonucleotides independent of dnaB protein. On dnaB-dnaC protein complex formation, covalent incorporation of ATP to dnaB protein decreases approximately 70% with a concomitant increase of ATP incorporation to dnaC protein by approximately 3-fold. The mechanism of this phenomenon has been analyzed in detail by titrating dnaB protein with increasing amounts of dnaC protein. The binding of dnaC protein to dnaB protein appears to be a noncooperative process. The lambda P protein, which interacts with dnaB protein in the bacteriophage lambda DNA replication, does not bind ATP in the presence or absence of dnaB protein. However, lambda P protein enhances the covalent incorporation of ATP to dnaB protein approximately 4-fold, suggesting a direct physical interaction between lambda P and dnaB proteins with a probable change in the modes of nucleotide binding to dnaB protein. The lambda P protein likely forms a lambda P-dnaB-ATP dead-end ternary complex. The implications of these results in the E. coli and bacteriophage lambda chromosomal DNA replication are discussed.     

Structural and functional studies of the dnaB protein using limited proteolysis. Characterization of domains for DNA-dependent ATP hydrolysis and for protein association in the primosome

Two separable structural domains were identified in the Escherichia coli dnaB protein (Mr = 52,000) by partial proteolytic cleavage under nondenaturing conditions. The hydrolysis of dnaB protein by trypsin proceeded in two distinct stages in the presence of ATP or ADP. In the first stage, 14 amino acid residues at the NH2-terminal end were removed and dnaB protein was converted into a fragment with a molecular weight of 50,000 (Fragment I). Fragment I retained about 60% of the original activity in priming DNA replication and was fully active in DNA-dependent ATPase activity. In the second stage, Fragment I was further cleaved into two separable polypeptides with molecular weights of 33,000 (Fragment II) and 12,000 (Fragment III), respectively. Fragment II, as a hexamer, retained DNA-dependent ATPase activity comparable to the intact protein but was totally inactive in priming DNA replication. No known activity of dnaB protein was detected in Fragment III alone. NH2 termini of Fragments I and III and COOH termini of dnaB protein and Fragment II were identical indicating that Fragments III and II were located at the NH2 and COOH termini of Fragment I, respectively. These results indicate that dnaB protein is composed of at least two distinct domains. 1) Fragment III, the rigid domain, is essential for protein interaction, i.e. association with dnaC protein and primase in priming DNA replication in the primosome. 2) A 14-amino acid residue fragment, at the NH2-terminal end adjacent to Fragment III, probably required to stabilize the protein interaction involved in priming DNA replication. 3) Fragment II, the flexible COOH-terminal domain, contains the active sites for DNA binding, ATP binding, and protein oligomerization. Fragment II is cleaved by trypsin at many sites in the absence of ATP or ADP ligands. The rate of conversion of Fragment I into the yield of Fragments II and III was decreased approximately by 2 orders of magnitude by changing the ligand from ADP to the nonhydrolyzed ATP analog, adenosine 5'-O-(3-thiotriphosphate). These results indicate that the conformation of the COOH-terminal domain in the dnaB protein is stabilized by ATP or ADP. Such a nucleotide-induced conformational change was also demonstrated by circular dichroism spectroscopy. Moreover, the data suggest that the conformation of the dnaB protein complexed with adenosine 5'-O-(3-thiotriphosphate) is different from that complexed with ADP.(ABSTRACT TRUNCATED AT 400 WORDS)     

Purification and characterization of the bacteriophage T7 gene 2.5 protein. A single-stranded DNA-binding protein.

Bacteriophage T7 gene 2.5 protein has been purified to homogeneity from cells overexpressing its gene. Native gene 2.5 protein consists of a dimer of two identical subunits of molecular weight 25,562. Gene 2.5 protein binds specifically to single-stranded DNA with a stoichiometry of approximately 7 nucleotides bound per monomer of gene 2.5 protein; binding appears to be noncooperative. Electron microscopic analysis shows that gene 2.5 protein is able to disrupt the secondary structure of single-stranded DNA. The single-stranded DNA is extended into a chain of gene 2.5 protein dimers bound along the DNA. In fluorescence quenching and nitrocellulose filter binding assays, the binding constants of gene 2.5 protein to single-stranded DNA are 1.2 x 10(6) M-1 and 3.8 x 10(6) M-1, respectively. Escherichia coli single-stranded DNA-binding protein and phage T4 gene 32 protein bind to single-stranded DNA more tightly by a factor of 25. Fluorescence spectroscopy suggests that tyrosine residue(s), but not tryptophan residues, on gene 2.5 protein interacts with single-stranded DNA.     

Complex of bacteriophage M13 single-stranded DNA and gene 5 protein

Lysates of bacteriophage M13-infected cells contain numerous unbranched filamentous structures approximately 1·1 μm long × 160 Å wide, that is, slightly longer and considerably wider than M13 virions. These structures are complexes of viral single-stranded DNA molecules with M13 gene 5 protein, a non-capsid protein required for single-stranded DNA production. All, or nearly all, of the single-stranded DNA from the infected cells and at least half to two-thirds of the gene 5 protein molecules are found as complex in the lysates. The complex contains about 1300 gene 5 protein molecules per DNA molecule but little if any of the two known capsid proteins. The complex is much less stable than virions in the presence of salt or ionic detergent solutions and in electron micrographs it appears to have a much looser and more open structure. If an excess of M13 single-stranded DNA is added to complex in a lysate, the gene 5 protein molecules from the complex redistribute onto all of the added as well as the original DNA, again suggesting a rather loose association of protein and DNA.By electron microscopy, the complex from infected cells appears to differ structurally from complex formed in vitro between purified single-stranded DNA and purified gene 5 protein. Because of this apparent structural difference and because previous experiments suggested the presence of complex in vivo, we presume that the complex which we have found in lysates of infected cells previously did exist as such inside the cells, but we have been unable to exclude that it formed during or after lysis. If it is assumed that complex does occur in vivo, the results of pulse-chase radioactive labeling experiments on infected cells can be interpreted as showing that with time the single-stranded DNA leaves complex, presumably to be matured into virions, while the gene 5 protein molecules are re-used to form more complex.     

Replication of bacteriophage M13. XII. In vivo cross-linking of a phage-specific DNA binding protein to the single-stranded DNA of bacteriophage M13 by ultraviolet irradiation.

Ultraviolet irradiation of bacteriophage M13-infected Escherichia coli induces the formation of a covalent crosslink between progeny single-stranded DNA and the M13 DNA binding protein, the product of gene 5. The crosslinked complex is readily isolated from detergent-treated lysates by sucrose-gradient velocity sedimentation and CsCl equilibrium sedimentation in the presence of detergent. The crosslinked complex produced with optimal levels of irradiation sediments 1.06 times faster than uncomplexed M13 single-stranded DNA, has a buoyant density of approximately 1.62 to 1.64 g/cm³ and a protein to DNA mass ratio of 2 mg protein per mg DNA. Cleavage of the crosslinked complex with cyanogen bromide or trypsin yields products similar to those produced by cleavage of purified M13 gene 5 protein. The crosslink is located close to the carboxyl terminus of the protein.     

Inhibition of RecA protein function by the RdgC protein from Escherichia coli

The Escherichia coli RdgC protein is a potential negative regulator of RecA function. RdgC inhibits RecA protein-promoted DNA strand exchange, ATPase activity, and RecA-dependent LexA cleavage. The primary mechanism of RdgC inhibition appears to involve a simple competition for DNA binding sites, especially on duplex DNA. The capacity of RecA to compete with RdgC is improved by the DinI protein. RdgC protein can inhibit DNA strand exchange catalyzed by RecA nucleoprotein filaments formed on single-stranded DNA by binding to the homologous duplex DNA and thereby blocking access to that DNA by the RecA nucleoprotein filaments. RdgC protein binds to single-stranded and double-stranded DNA, and the protein can be visualized on DNA using electron microscopy. RdgC protein exists in solution as a mixture of oligomeric states in equilibrium, most likely as monomers, dimers, and tetramers. This concentration-dependent change of state appears to affect its mode of binding to DNA and its capacity to inhibit RecA. The various species differ in their capacity to inhibit RecA function.     

The Escherichia coli preprimosome and DNA B helicase can form replication forks that move at the same rate

A DNA replication system was developed that could generate rolling-circle DNA molecules in vitro in amounts that permitted kinetic analyses of the movement of the replication forks. Two artificial primer-template DNA substrates were used to study DNA synthesis catalyzed by the DNA polymerase III holoenzyme in the presence of either the preprimosomal proteins (the primosomal proteins minus the DNA G primase) and the Escherichia coli single-stranded DNA binding protein or the DNA B helicase alone. Helicase activities have recently been demonstrated to be associated with the primosome, a mobile multiprotein priming apparatus that requires seven E. coli proteins (replication factor Y (protein n'), proteins n and n', and the products of the dnaB, dnaC, dnaG, and dnaT genes) for assembly, and with the DNA B protein. Consistent with a rolling-circle mechanism in which a helicase activity permitted extensive (-) strand DNA synthesis on a (+) single-stranded, circular DNA template, the major DNA products formed were multigenome-length, single-stranded, linear molecules. The replication forks assembled with either the preprimosome or the DNA B helicase moved at the same rate (approximately 730 nucleotides/s) at 30 degrees C and possessed apparent processivities in the range of 50,000-150,000 nucleotides. The single-stranded DNA binding protein was not required to maintain this high rate of movement in the case of leading strand DNA synthesis catalyzed by the DNA polymerase III holoenzyme and the DNA B helicase.     

Analysis of the unwinding activity of the dimeric RECQ1 helicase in the presence of human replication protein A

RecQ helicases are required for the maintenance of genome stability. Characterization of the substrate specificity and identification of the binding partners of the five human RecQ helicases are essential for understanding their function. In the present study, we have developed an efficient baculovirus expression system that allows us to obtain milligram quantities of recombinant RECQ1. Our gel filtration and dynamic light scattering experiments show that RECQ1 has an apparent molecular mass of 158 kDa and a hydrodynamic radius of 5.4 ± 0.6 nm, suggesting that RECQ1 forms dimers in solution. The oligomeric state of RECQ1 remains unchanged upon binding to a single-stranded (ss)DNA fragment of 50 nt. We show that RECQ1 alone is able to unwind short DNA duplexes (<110 bp), whereas considerably longer substrates (501 bp) can be unwound only in the presence of human replication protein A (hRPA). The same experiments with Escherichia coli SSB show that RECQ1 is specifically stimulated by hRPA. However, hRPA does not affect the ssDNA-dependent ATPase activity of RECQ1. In addition, our far western, ELISA and co-immunoprecipitation experiments demonstrate that RECQ1 physically interacts with the 70 kDa subunit of hRPA and that this interaction is not mediated by DNA.     

Characterization of the Single-Stranded DNA Binding Protein Encoded by the Vaccinia Virus I3 Gene

The 34-kDa protein encoded by the I3 gene of vaccinia virus is expressed at early and intermediate times postinfection and is phosphorylated on serine residues. Recombinant I3 has been expressed in Escherichia coli and purified to near homogeneity, as has the protein from infected cells. Both recombinant and endogenous I3 protein demonstrate a striking affinity for single-stranded, but not for double-stranded, DNA. The interaction with DNA is resistant to salt, exhibits low cooperativity, and appears to involve a binding site of approximately 10 nucleotides. Electrophoretic mobility shift assays indicate that numerous I3 molecules can bind to a template, reflecting the stoichiometric interaction of I3 with DNA. Sequence analysis reveals that a pattern of aromatic and charged amino acids common to many replicative single-stranded DNA binding proteins (SSBs) is conserved in I3. The inability to isolate viable virus containing an interrupted I3 allele provides strong evidence that the I3 protein plays an essential role in the viral life cycle. A likely role for I3 as an SSB involved in DNA replication and/or repair is discussed.     

Characterization of Escherichia coli DnaAcos protein in replication systems reconstituted with highly purified proteins

Excessive initiation of chromosomal replication occurs in the dnaAcos mutant at 30°C. Whereas purified wild-type DnaA protein binds ATP and ADP tightly, DnaAcos protein is defective for such nucleotide binding. As initiation is a multistep reaction and DnaA protein functions at each step, activities of DnaAcos protein need to be examined precisely. DnaAcos protein specifically bound a DNA fragment containing the chromosomal replication origin with an affinity similar to that seen with the wild-type protein. In a system reconstituted with purified proteins at 30°C, the mutant protein initiated replication of single-stranded DNA that contains a DnaA-binding hairpin structure. Thus, DnaAcos protein basically sustains affinity to a DnaA-binding sequence and functions in the loading of DnaB helicase onto single-stranded DNA. Thermal stabilities of wild-type DnaA and DnaAcos activities were comparable. Unlike wild-type DnaA protein, DnaAcos protein was inactive for minichromosomal replication in systems reconstituted with purified proteins in which the ATP-bound form of DnaA protein is required for initiation. Taken together, the data indicate that the prominent defect in DnaAcos protein appears to be the inability to bind nucleotide.     

Electron microscopy of a eukaryotic single-stranded DNA binding protein-DNA complex

The single-stranded DNA binding protein of Ustilago maydis decreases the contour length of φX174 DNA. When DNA complexes were prepared with subsaturating amounts of the protein, its distribution on the DNA was markedly non-random, indicating a high degree of co-operativity in its binding to single-stranded DNA. The analagous Escherichia coli, Salmonella typhimurium and bacteriophage T7 binding proteins also reduced DNA contour lengths to a similar extent, whereas the bacteriophage T4 gene 32 protein, as shown previously, increased the contour length. Despite the fact that the U. maydis protein efficiently denatures poly[d(A-T) · d(A-T)], it appears to initiate denaturation of native bacteriophage λ DNA rather inefficiently.     

Characterization of the sperm receptor for acrosome reaction-inducing substance of the starfish,Asterias amurensis

Acrosome reaction-inducing substance (ARIS) in the jelly coat of starfish eggs is a highly sulfated proteoglycan-like molecule of an apparent molecular size over 10(4) kDa and plays a pivotal role in the induction of acrosome reaction in homologous spermatozoa. It is known in Asterias amurensis that ARIS binds to a restricted area of the anterior portion of sperm head, and that a glycan fragment of ARIS, named Fragment 1, consisting of 10 repeats or so of a pentasaccharide unit retains the biological activity of ARIS to an appreciable extent. In this report, we have shown the binding of Fragment 1, a relatively small pure glycan fragment of ARIS, to the putative ARIS receptor on the sperm surface by three independent methods. First, the specific binding of P-ARIS to isolated sperm membranes was monitored in real-time by using a surface plasmon resonance detector, namely a Biacore sensor system. The specific and quantitative binding of Fragment 1 to the intact sperm and to isolated sperm membranes was similarly monitored. Secondly, the binding of 125I-labeled Fragment 1 to the intact sperm was stoichiometrically measured, for which we had developed a unique procedure for radioiodination of saccharide chains. It is found that Fragment 1 competes with P-ARIS for the binding to ARIS-receptor, suggesting that Fragment 1 is a useful ligand in the search for ARIS receptor protein(s). Thirdly, the putative receptor molecules were specifically labeled by using Fragment 1 as a ligand for photoaffinity crosslink technique. Taking these results into account, we conclude that starfish sperm have the ARIS receptor, which consists most probably of 50 to 60 kDa proteins, of reasonably high affinity (for Fragment 1, Kd = 15 microM, Bmax = 8.4 x 10(4) per cell).     

Estimation of Förster's distance between two ends of Dps protein from mycobacteria: distance heterogeneity as a function of oligomerization and DNA binding

Dps protein (DNA binding Protein from Starved Cells) from Mycobacterium smegmatis (Ms-Dps) is known to undergo an in vitro irreversible oligomeric transition from trimer to dodecamer. This transition helps the protein to provide for bimodal protection to the bacterial DNA from the free radical and Fenton mediated damages in the stationary state. The protein exists as a stable trimer, when purified from E. coli cells transformed with an over-expression plasmid. Both trimer as well as dodecamer are known to exhibit ferroxidation activity, thus removing toxic hydroxyl radicals in vivo, whereas iron accumulation and non-sequence specific DNA binding activity are found in dodecamer only. This seems to be aided by the positively charged long C-terminal tail of the protein. We used frequency domain phase-modulation fluorescence spectroscopy and Förster Resonance Energy Transfer (FRET) to monitor this oligomeric switch from a trimer to a dodecamer and to elucidate the structure of DNA–Dps dodecamer complex. As Ms-Dps is devoid of any Cysteine residues, a Serine is mutated to Cysteine (S169C) at a position adjacent to the putative DNA binding domain. This Cysteine is subsequently labeled with fluorescent probe and another probe is placed at the N-terminus, as crystal structure of the protein reveals several side-chain interactions between these two termini, and both are exposed towards the surface of the protein. Here, we report the Förster's distance distribution in the trimer and the dodecamer in the presence and absence of DNA. Through discrete lifetime analysis of the probes tagged at the respective regions in the macromolecule, coupled with Maximum Entropy Method (MEM) analysis, we show that the dodecamer, upon DNA binding shows conformational heterogeneity in overall structure, perhaps mediated by a non-specific DNA–protein interaction. On the other hand, the nature of DNA–Dps interaction is not known and several models exist in literature. We show here with the help of fluorescence anisotropy measurements of labeled DNA having different length and unlabeled native dodecameric protein that tandem occupation of DNA binding sites by a series of Dps molecules perhaps guide the tight packing of Dps over DNA backbone.     

Arrangement of the single-stranded fragments in E. coli bacteriophage BF23 DNA

Bacteriophage BF23st(0) DNA was denatured with alkali and fractionated by agarose gel electrophoresis. Seven single-stranded fragments (designated Fragments I--VII) were identified as the major constituents of the phage DNA. The presence of several minor fragments which represent minor populations of the phage genome was also observed. The largest fragment (Fragment I) represents the intact strand of phage DNA, whereas the other fragments form the complementary strand. Thus, BF23st(0) DNA carries single-strand interruptions in only one strand. The arrangement of the major fragments in the nicked strand was determined by use of gamma-exonuclease and agarose gel electrophoresis. From the mode of action of this nuclease, and from the kinetics of release or disappearance of the fragments, the polarity of the fragments in BF23st(0) DNA was specified. In addition, the presence of two types of major phage populations differing in their composition of the fragments was demonstrated. One type has an additional nick (yielding Fragment IV and Fragment V) in a specific fragment (Fragment II) of other type.     

Morphology and Physical Properties of Staphylococcus Bacteriophage P11-M15

The Group B Staphylococcus phage P11-M15 is shown to be 51% protein and 49% deoxyribonucleic acid (DNA). The intact virion has a molecular weight of 66.7 x 10(6) daltons. The purified viral DNA has a molecular weight of 32.7 x 10(6) daltons. The intact virion is shown to be composed of a polyhedral head which is attached at one of its vertices to a flexible tail having helical symmetry. The tail structure is terminated by a complex baseplate which has sixfold symmetry. The virion contains a single molecule of double-stranded DNA which has no apparent single-strand nicks or single-stranded terminal redundancies.