Interactions of bacteriophage T4-coded gene 32 protein with nucleic acids: II. Specificity of binding to DNA and RNA

In this paper we examine the specificity of the co-operative binding (in the polynucleotide mode) of bacteriophage T4-coded gene 32 protein to synthetic and natural single-stranded nucleic acids differing in base composition and sugar type. It is shown by competition experiments in a tight-binding (low salt) environment that there is a high degree of binding specificity under these (protein-limiting) conditions, with one type of nucleic acid lattice binding gene 32 protein to saturation before any binding to the competing lattice takes place; it is also shown that the same differential specificities apply at high salt concentrations. Procedures developed in the preceding paper (Kowalczykowski et al., 1980) are used to measure the net binding affinities (Kω) of gene 32 protein to a variety of polynucleotides, as well as to determine individual values of K and ω for some systems. For all polynucleotides, virtually the entire specificity and salt dependence of binding of Kω appears to be in K. In ~0.2 m-NaCl, the net binding affinities (Kω) range from ~10⁶ to ~10¹¹m^?1; in order of increasing affinities we find: poly(rC) < poly(rU) < poly(rA) < poly(dA) < poly(dC) < poly(dU) < poly(rI) < poly(dI) < poly-(dT). In general, Kω for a particular homopolyribonucleotide at constant salt concentration is 10¹ to 10⁴smaller than Kω for the corresponding homopoly-deoxyribopolynucleotide. Values of Kω for randomly copolymerized polynucleotides and for natural DNA fall at the compositionally weighted average of the values for the individual homopolynucleotides (except for poly(dT), which appears to bind somewhat tighter), indicating that the net affinity represents the sum of the binding free energy contributions of the individual nucleotides. It is shown that these results, on a competition basis under physiological salt conditions, can account quantitatively for the autogenous regulation of the synthesis of gene 32 protein at the translational level (Russel et al., 1976; Lemaire et al., 1978). In addition, these results suggest possible mechanisms by which gene 32 messenger RNA might be specifically recognized (by gene 32 protein) and functionally discriminated from the other mRNAs of phage T4.     

Interactions of bacteriophage T4-coded gene 32 protein with nucleic acids: I. Characterization of the binding interactions

In this paper we examine molecular details of the interaction of bacteriophage T4-coded gene 32 protein with oligo- and polynucleotides. It is shown that the binding affinity (K_oligo) of oligonucleotides of length (l) from two to eight nucleotide residues for gene 32 protein is essentially independent of base composition or sugar type. This binding also shows little dependence on salt concentration and on oligonucleotide length; even the expected statistical length factor in K_oligo is not observed, suggesting that binding occurs at the end of the oligonucleotide lattice and that the oligonucleotide is not free to move across the binding site. Co-operative (contiguous) or isolated binding of gene 32 protein to polynucleotides is very different; here binding is highly salt dependent ($\text{? log Kω}\text{? log}\text{[NaCl]}\text{～- ?7}\text{)}$ and essentially stoichiometric at salt concentrations less than ~0.2 m (for poly(rA)). Binding becomes much weaker and the binding isotherms appear typically co-operative (sigmoid) in protein concentration at higher salt concentrations. We demonstrate, by fitting the co-operative binding isotherms to theoretical plots at various salt concentrations and also by measuring binding at very low protein binding density (ν), that the entire salt dependence of Kω is in the intrinsic binding constant (K); the co-operativity parameter (ω) is essentially independent of salt concentration. Furthermore, by determining titration curves in the presence of salts containing a series of different anions and cations, it is shown that the major part of the salt dependence of the gene 32 protein-polynucleotide interaction is due to anion (rather than to cation) displacement effects. Binding parameters of oligonucleotides of length sufficient to bind two or more gene 32 protein monomers show behavior intermediate between the oligonucleotide and the polynucleotide binding modes. These different binding modes probably reflect different conformations of the protein; the results are analyzed to produce a preliminary molecular model of the interactions of gene 32 protein with nucleic acids in its different binding modes.     

Nucleic binding affinity of bacteriophage T4 gene 32 protein in the cooperative binding mode

This study reports on various parameters which affect the binding stoichiometry for complexes of bacteriophage T4 gene 32 protein (P32) and single stranded polynucleotides (determined by UV absorbance and fluorescence quenching) and presents results of a quantitative electron spin resonance assay to determine physiologically effective binding affinity differences of nucleic acid binding proteins. The assay employs macromolecular spin probes (spin-labeled nucleic acids) which are used to determine the fraction of saturation in competition experiments with unlabeled nucleic acids. It was found that the fraction of complexed spin-labeled polynucleotides can be directly monitored by ESR with a two-component analysis approach when ligands such as poly(L-lysine), gene 5 protein (P5) of filamentous bacteriophage fd, and gene 32 protein (P32) of bacteriophage T4 are used. The ESR data unequivocally show that: 1) the binding stoichiometry for poly(L-lysine), P5 and P32 is nucleotide/lysine, 4 nucleotides/P5 monomer, and 10 nucleotides/P32 monomer, respectively; and 2) under physiologically relevant buffer conditions the relative affinity of P32 in the cooperative binding mode for polythymidylic acid is about 4 times greater than for polydeoxyinosinic acid and about 12 times greater than for polyinosinic acid, and the relative affinity of P32 for polydeoxyinosinic acid is about 3 times greater than for polyinosinic acid.     

The function of zinc in gene 32 protein from T4

Gene 32 protein (g32P), the single-stranded DNA binding protein from bacteriophage T4, contains 1 mol of Zn(II) bound in a tetrahedral complex to -S- ligands, proposed on spectral evidence to include Cys-77, Cys-87, and Cys-90 [Giedroc, D. P., Keating, K. M., Williams, K. R., Konigsberg, W. H., & Coleman, J. E. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 8452]. The Zn(II) can be completely removed by treatment with the mercurial reagent p-(hydroxymercuri)benzenesulfonate and ethylenediaminetetraacetic acid. The resultant apo-g32P is rapidly digested by trypsin in contrast to the zinc protein which undergoes specific limited proteolysis to yield a resistant DNA-binding core. Rebinding of Zn(II) to the apoprotein restores the same limited susceptibility to proteolysis displayed by the native Zn(II) protein. In the presence of 150 mM NaCl, Zn(II) g32P reduces the melting temperature Tm of poly[d(A-T)] by 47 degrees C, while apo-g32P is unable to melt poly[d(A-T)] at this salt concentration, as the protein thermally unfolds before melting can take place. At 25 mM NaCl, however, apo-g32P lowers the Tm of poly[d(A-T)] by 36 degrees C, but the melting curve is broad compared to the steep cooperative melting induced by Zn(II) g32P. Association constants Ka calculated from the poly[d(A-T)] melting curves for Zn(II) and apo-g32P differ by 3 orders of magnitude, 4.8 X 10(10) M-1 and 4.3 X 10(7) M-1, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

On the thermodynamics and kinetics of the cooperative binding of bacteriophage T4-coded gene 32 (helix destabilizing) protein to nucleic acid lattices.

In this paper we summarize a series of thermodynamic, and preliminary kinetic, studies on the molecular details and specificity of interaction of phage T4-coded gene 32-protein (GP32) with nucleic acid lattices. It is shown that the binding of GP32 to short (l = 2--8 residues) oligonucleotides is essentially independent of base composition and sugar-type, as well as of salt concentration. In contrast, cooperative (continuous) or isolated binding of GP32 to single-stranded polynucleotides is base and sugar composition-dependent (binding is tighter to DNA than to RNA) and highly dependent on salt concentrations. Binding constants (K), cooperativity parameters (w), and binding site sizes (n) are determined for binding to various nucleic acid lattices under a variety of environmental conditions. These results are used to show that GP32 can bind to nucleic acid lattices in two different conformations, and to characterize the molecular details of these binding species. Further insight into the molecular origins of binding cooperativity is obtained by determining these thermodynamic parameters also for the specifically proteolytically degraded GP32 fragments GP32 I (C-terminal peptide removed) and GP32 III (C- and N-terminal peptides removed). It is also shown that these GP32-nucleic acid binding measurements can be used to provide a quantitative molecular interpretation of the sequential (competitive) binding equilibria involved in the autogenous translational regulation of GP32 synthesis (Lemaire et al., 1978, J. Mol. Biol. 126:73, 1978), and to illustrate some general principles of the development of interactional specificity in cooperatively binding protein-nucleic acid complexes. Preliminary experiments have also been carried out on the kinetics of GP32 association to, and dissociation from, single-stranded nucleic acid lattices. In particular, fluorescence stopped-flow measurements of the dissociation of GP32 from such lattices as a function of lattice saturation (and protein cluster size) can be interpreted to suggest that the protein may translocate ("slide") on the lattice before dissociation, These studies permit an approach to possible rates and mechanisms of such translocation events.     

New late gene, dar, involved in the replication of bacteriophage T4 DNA. II. Overproduction of DNA binding protein (gene 32 protein) and further characterization.

We have previously shown that the arrested DNA synthesis of mutant defective in T4 phage gene 59 can be reversed by a mutation in dar. In this paper, we have examined the effect of the dar mutation on the kinetics of gene 32 protein (DNA binding protein) synthesis, DNA packaging, progeny formation, and several other porcesses. Several lines of evidence are presented showing that the regulation of synthesis of gene 32 protein is abnormal in dar 1-infected cells. In these cells, gene 32 protein, an early protein, is also expressed late in the infectious cycle. Our data also indicate that the packaging og DNA into T4 phage heads is delayed in dar mutant-infected cells, and this in turn results in a 6- to 8-min delay in intracellular progeny formation, although the synthesis of late proteins appears to be normal, as shown by gel electrophoresis. We have also studied the phenotypes of the double mutant dar-amC5 (gene 59). The increased sensitivity to hydroxyurea caused by a mutation in the dar gene can be alleviated by a second mutation in gene 59, but an increased sensitivity to UV irradiation caused by a mutation in gene 59 cannot be alleviated by a second mutation in the dar gene. Therefore, the double mutant still exhibits abnormalities in the repair of UV lesions.     

Kinetics and mechanism of the association of the bacteriophage T4 gene 32 (helix destabilizing) protein with single-stranded nucleic acids. Evidence for protein translocation

We have investigated the association kinetics of the co-operatively binding T4-coded gene 32 (helix destabilizing) protein with a variety of single-stranded homopolynucleotides (both RNA and DNA). Stopped-flow mixing experiments were performed by monitoring the partial quenching of the intrinsic tryptophan fluorescence of the protein upon binding to the nucleic acid under conditions where the nucleic acid concentration is in great excess over the protein concentration. Investigations of the association rate (and rate constants) as a function of solution variables has demonstrated quite different behavior at the extremes of “low” and “high” salt concentration. Under low salt (high binding constant) conditions the non-co-operative association is rate-limiting and we measure a bimolecular rate constant of 3 × 10⁶ to 4 × 10⁶ m^?1 (nucleotide)s^?1 (0·1 m-NaCl, 25·0 °C). However, at higher salt concentrations (lower binding constant) a pre-equilibrium involving non-co-operatively bound protein is established, followed by the rate-limiting formation of co-operatively bound protein clusters.Based on these observations we have proposed a mechanism for the formation of co-operatively bound T4 gene 32 protein clusters, under conditions of low binding density, which consists of three steps: (1) pre-equilibrium formation of non-co-operatively bound protein (nucleation); followed by (2) association of free protein to the singly contiguous sites established in the nucleation step, hence forming the first co-operative interactions (growth step); and (3) a redistribution of the growing protein clusters to form the final equilibrium distribution. From comparisons of our experimental values of the forward rate constant for the second step (growth of clusters) with theoretical estimates based on the work of Berg &; Blomberg (1976,1978) we infer that the T4 gene 32 protein is able to translocate along singlestranded polynucleotides. The implications of these results for the in vivo action of the T4 gene 32 protein are discussed.     

Autoregulation of gene expression: Quantitative evaluation of the expression and function of the bacteriophage T4 gene 32 (single-stranded DNA binding) protein system

The free concentration of bacteriophage T4-coded gene 32 (single-stranded DNA binding) protein in the cell is autoregulated at the translational level during T4 infection of Escherichia coli. The control of the synthesis of this protein reflects the following progression of net (co-operative) binding affinities for the various potential nucleic acid binding targets present: single-stranded DNA > gene 32 mRNA > other T4 mRNAs ? double-stranded DNA. In this paper we show that the free concentration of gene 32 protein is maintained at 2 to 3 μm, and use the measured binding parameters for gene 32 protein, extrapolated to intracellular conditions, to provide a quantitative molecular interpretation of this system of control of gene expression. These results are then further utilized to define the specific autoregulatory binding sequence (translational operator site) on the gene 32 mRNA as a uniquely unstructured finite binding lattice terminated by elements of secondary structure not subject to melting by gene 32 protein at the autoregulated concentration, and to predict how this site must differ from those found on other T4 messenger RNAs. It is shown that these predictions are fully consistent with available T4 DNA sequence data. The control of free protein concentration as a method of genome regulation is discussed in terms of other systems to which these approaches may apply.     

A retrovirus-like zinc domain is essential for translational repression of bacteriophage T4 gene 32

Gene 32 protein (gp32), a single-stranded DNA-binding protein from bacteriophage T4, contains a zinc-binding subdomain with sequence homologies to the 3-cysteine/1-histidine zinc-binding motif found in a variety of retroviruses and plant viruses. In vitro studies suggest that autoregulation of gp32 occurs at the level of translation by gp32 specifically binding gene 32 mRNA at an unusual stem-loop structure that can be modeled as an RNA pseudoknot. Nucleation of gp32 binding via this pseudoknot is thought to be needed to facilitate cooperative binding of gp32 through a largely unstructured region that overlaps the ribosome binding site (McPheeters, D. S., Stormo, G. D., and Gold, L. (1988) J. Mol. Biol. 201, 517-535). Removal of Zn(II) from gp32 results in a protein that retains the ability to bind single-stranded RNA with high affinity but is unable to specifically autoregulate itself at the level of translation. Deletion of the pseudoknot sequences from the gene 32 autoregulatory region results in an mRNA that cannot be repressed by gp32. These results suggest that the zinc-binding subdomain of gp32 plays an essential role in autoregulation by providing a critical element necessary for nucleating cooperative binding at the gene 32 mRNA pseudoknot.     

Suppressors of gene 32 am mutants that specifically overproduce P32 (unwinding protein) in bacteriophage T4.

A gene 32 amber (am) mutant, amNG364, fails to grow on Escherichia coli Su3+ high temperatures, suggesting that the tyrosine residue inserted at the am codon by Su3+ leads to a temperature-sensitive gene 32 protein (P32). By plating amNG364 on E. coli Su3+ 45 degrees C, several pseudorevertants were found that proved to contain a suppressor (su) mutant in addition to the original am mutation. Crosses of two of these amNG364su strains to am+ phage indicated that the suppressors themselves are in or close to gene 32. Phage strains carrying either of the two su mutations, without amNG364, grew normally. When cells were infected by these su mutants and the proteins produced were examined by sodium dodecyl sulfate-gel electrophroesis, specific overproduction of P32 was found. Maximum overproduction compared to am+ phage was 6.6-fold for one su mutant and 2.4-fold for the other. Other proteins were produced in normal amounts and in normal time sequence. When amNG364su phage were allowed to infect E. coli S/6/5(Su-), the gene 32 am fragments produced were present at the same derepressed levels as in an infection by amNG364 without a suppressor. The suppressor mutations are interpreted as causing derepression of P32 by altering sites in this autogenously regulated protein involved in template recognition. Previously, specific derepression of gene 32 had only been shown using gene 32 conditional lethal mutants grown under restrictive conditions. We have shown that P32 can also be derepressed under permissive conditions, indicating that loss of P32 function is not necessary for specific derepression.     

Interaction between bacteriophage T4 coded gene 32 protein and poly(rA)

The cooperative binding of T4 gene 32 protein with polynucleotides, of which the quantitative aspects in the literature have not satisfied the requirements of thermodynamics, is studied by adopting a modified formula of the lattice theory. A moderate value is found for the cooperativity parameter (q approximately 200 at 0.2 M NaCl), which is weakly dependent on salt concentration. The cation effect on the binding suggests that the shielding of negative charges of the protein or a loose cation bridge between the bound protein molecules plays a role in the cooperative binding process.     

Zn(II) coordination domain mutants of T4 gene 32 protein.

Gene 32 protein (g32P), the replication accessory single-stranded nucleic acid binding protein from bacteriophage T4, contains 1 mol of Zn(II)/mol of protein. Zinc coordination provides structural stability to the DNA-binding core domain of the molecule, termed g32P-(A+B) (residues 22-253). Optical absorption studies with the Co(II)-substituted protein and 113Cd NMR spectroscopy of 113Cd(II)-substituted g32P-(A+B) show that the metal coordination sphere in g32P is characterized by approximately tetrahedral ligand symmetry and ligation by the Cys-S- atoms of Cys77, Cys87, and Cys90. These studies predicted the involvement of a fourth protein-derived non-thiol ligand to complete the tetrahedral complex, postulated to be His81 on the basis of primary structure prediction and modeling [Giedroc, D.P., Johnson, B.A., Armitage, I.M., & Coleman, J.E. (1989) Biochemistry 28, 2410-2418]. To test this model, we have employed site-directed mutagenesis to substitute each of the two histidine residues in g32P (His64 and His81), accompanied by purification and structural characterization of these single-site mutant proteins. We show that g32P's containing any of three substitutions at residue 64 (H64Q, H64N, and H64L) are isolated from Escherichia coli in a Zn(II)-free form [less than or equal to 0.03 g.atom Zn(II)]. All derivatives show extremely weak affinity for the ssDNA homopolymer poly(dT). All are characterized by a far-UV-CD spectrum reduced in negative intensity relative to the wild-type protein. These structural features parallel those found for the known metal ligand mutant Cys87----Ser87 (C87S) g32P. In contrast, g32P-(A+B) containing a substitution of His81 with glutamine (H81Q), alanine (H81A) or cysteine (H81C), contains stoichiometric Zn(II) as isolated and binds to polynucleotides with an affinity comparable to the wild-type g32P-(A+B). Spin-echo 1H NMR spectra recorded for wild-type and H81Q g32P-(A+B) as a function of pH allow the assignment of His81 ring proteins to delta = 6.81 and 6.57 ppm, respectively, at pH 7.8, corresponding to the C and D histidyl protons of 1H-His-g32P-(A+B) [Pan, T., Giedroc, D.P., & Coleman, J.E. (1989) Biochemistry 28, 8828-8832]. These resonances shift downfield as the pH is reduced from 7.8 to 6.6 without metal dissociation, a result incompatible with His81 donating a ligand to the Zn(II) in wild-type g32P. Likewise, Cys81 in Zn(II) H81C g32P is readily reactive with 5,5'-dithiobis(2-nitrobenzoic acid), unlike metal ligands Cys77, Cys87, and Cys90.(ABSTRACT TRUNCATED AT 400 WORDS)     

Regulation of the synthesis of bacteriophage T4 gene 32 protein

The synthesis of T4 gene 32 product (P32) has been followed by gel electrophoresis of infected cell lysates. In wild-type infections, its synthesis starts soon after infection and begins to diminish about the time late gene expression commences. The absence of functional P32 results in a marked increase in the amount of the non-functional P32 synthesized. For example, infections of T4 mutants which contain a nonsense mutation in gene 32 produce the nonsense fragment at more than ten times the maximum rate of synthesis of the gene product observed in wild-type infections. All of the temperature-sensitive mutants in gene 32 that were tested also overproduce this product at the non-permissive temperature. This increased synthesis of the non-functional product is recessive, since mixed infections (wild-type, gene 32 nonsense mutant) fail to overproduce the nonsense fragment.Mutations in genes required for late gene expression (genes 33 and 53) as well as some genes required for normal DNA synthesis also result in increased production of P32. The overproduction in such infections is dependent on DNA synthesis; in the absence of DNA synthesis no overproduction occurs. This contrasts with the overproduction resulting from the absence of functional P32 which is not dependent on DNA synthesis.These results are compatible with a model for the regulation of expression of gene 32 in which the synthesis of P32 is either directly or indirectly controlled by its own function. Thus, in the absence of P32 function the expression of this gene is increased as is manifest by the high rate of P32 synthesis. It is further suggested that in infections defective in late gene expression and consequently in the maturation of replicated DNA, the increased P32 production is caused by the large expansion of the DNA pool. This DNA is presumed to compete for active P32 by binding it non-specifically to single-stranded regions, thus reducing the amount of P32 free to block gene 32 expression. Similarly, the aberrant DNA synthesized following infections with mutants in genes 41, 56, 58, 60 and 30, although quantitatively less than that produced in the maturation defective infections, can probably bind large quantities of P32 to single-stranded regions resulting in increased P32 synthesis.     

Mutator mutations in bacteriophage T4 gene 32 (DNA unwinding protein).

Bacteriophage T4 gene 32 encodes a DNA unwinding protein required for DNA replication, repair, and recombination. Gene 32 temperature-sensitive mutations enhance virtually all base pair substitution mutation rates.     

Mapping the interactions of the single-stranded DNA binding protein of bacteriophage T4 (gp32) with DNA lattices at single nucleotide resolution: polynucleotide binding and cooperativity

We here use our site-specific base analog mapping approach to study the interactions and binding equilibria of cooperatively-bound clusters of the single-stranded DNA binding protein (gp32) of the T4 DNA replication complex with longer ssDNA (and dsDNA) lattices. We show that in cooperatively bound clusters the binding free energy appears to be equi-partitioned between the gp32 monomers of the cluster, so that all bind to the ssDNA lattice with comparable affinity, but also that the outer domains of the gp32 monomers at the ends of the cluster can fluctuate on and off the lattice and that the clusters of gp32 monomers can slide along the ssDNA. We also show that at very low binding densities gp32 monomers bind to the ssDNA lattice at random, but that cooperatively bound gp32 clusters bind preferentially at the 5′-end of the ssDNA lattice. We use these results and the gp32 monomer-binding results of the companion paper to propose a detailed model for how gp32 might bind to and interact with ssDNA lattices in its various binding modes, and also consider how these clusters might interact with other components of the T4 DNA replication complex.     

A human gene coding for a membrane-associated nucleic acid-binding protein

Studies to clone a cell-surface DNA-binding protein involved in the binding and internalization of extracellular DNA have led to the isolation of a gene for a membrane-associated nucleic acid-binding protein (MNAB). The full-length cDNA is 4.3 kilobases with an open reading frame of 3576 base pairs encoding a protein of approximately 130 kDa (GenBank accession numbers and ). The MNAB gene is on human chromosome 9 with wide expression in normal tissues and tumor cells. A C3HC4 RING finger and a CCCH zinc finger have been identified in the amino-terminal half of the protein. MNAB bound DNA (K(D) approximately 4 nm) and mutagenesis of a single conserved amino acid in the zinc finger reduced DNA binding by 50%. A potential transmembrane domain exists near the carboxyl terminus. Antibodies against the amino-terminal half of the protein immunoprecipitated a protein of molecular mass approximately 150 kDa and reacted with cell surfaces. The MNAB protein is membrane-associated and primarily localized to the perinuclear space, probably to the endoplasmic reticulum or trans-Golgi network. Characterization of the MNAB protein as a cell-surface DNA-binding protein, critical in binding and internalization of extracellular DNA, awaits confirmation of its localization to cell surfaces.     

DNA binding site of the helix destabilizing protein gp32 from bacteriophage T4.

A helix destabilizing protein, the product of gene 32 (gp32) of bacteriophage T4, was subjected to limited proteolysis to produce three types of products with differing affinities for DNA. Previous work has suggested that the 18 amino acids at the N-terminus are required for tight binding to single-stranded DNA (Hosoda &; Moise, 1978). This paper reports the sequence of the N-terminal region and predicts the amino acid residues responsible for DNA binding.     

The role of the bacteriophage T4 gene 32 protein in homologous pairing

The gene 32 protein of the bacteriophage T4 is required for efficient genetic recombination in infected Eschericia coli cells and strongly stimulates in vitro pairing catalyzed by the phage uvsX protein, a RecA-like strand transferase. This helix-destabilizing factor is known to bind tightly and cooperatively to single-stranded DNA and to interact specifically with the uvsX protein as well as other phage gene products. However, its detailed role in homologous pairing is not well understood. I show here that when the efficiency of uvsX protein-mediated pairing is examined at different gene 32 protein and duplex DNA concentrations, a correlation between the two is found, suggesting that the two interact in a functionally important manner during the reaction. These and other data are consistent with a model in which the gene 32 protein binds to the strand displaced from the recipient duplex during pairing, thereby stabilizing the heteroduplex product. An alternative model in which the gene 32 protein replaces UvsX on the invading strand, thereby freeing the strand transferase to bind to the displaced strand, is also considered.     

Studies of the self-association of bacteriophage T4 gene 32 protein by equilibrium sedimentation.

The self-association of the bacteriophage T4 gene 32 protein has been examined in the analytical ultracentrifuge under varying conditions to determine the nature of the process. The process is not a simple indefinite association with one association constant (monomer

dimer

trimer

etc.). The complexity of the process is shown by (1) peculiarities in the molecular weight versus concentration curves, in the region of the dimer (observed with increasing ionic strength, at pH 10, in 0.04 m-MgCl₂, with aged preparations, at 19 °C and in the presence of the oligonucleotide d(pT)₁₀), (2) the increased sigmoidicity of the association curve in the presence of glycerol or oligo[d(pT)₄], and (3) the discontinuity in the association curve at the tetramer at a pH value of approximately 9.4. A model with two association constants which could vary independently (monomer

dimer

tetramer

etc.) explained many of the findings. However, a more complex model was required to explain curves which had a plateau at the dimer with increased association at higher protein concentrations. Thus, under all conditions examined there is evidence for more than one type of protein-protein interaction. These different interactions may be involved in a physiological function such as recombination.