Interactions of the Major Cold Shock Protein of Bacillus subtilis CspB with Single-stranded DNA Templates of Different Base Composition*

CspB is a small acidic protein of Bacillus subtilis, the induction of which is increased dramatically in response to cold shock. Although the exact functional role of CspB is unknown, it has been demonstrated that this protein binds single-stranded deoxynucleic acids (ssDNA). We addressed the question of the effect of base composition on the CspB binding to ssDNA by analyzing the thermodynamics of CspB interactions with model oligodeoxynucleotides. Combinations of four different techniques, fluorescence spectroscopy, gel shift mobility assays, isothermal titration calorimetry, and analytical ultracentrifugation, allowed us to show that: 1) CspB can preferentially bind poly-pyrimidine but not poly-purine ssDNA templates; 2) binding to T-based ssDNA template occurs with high affinity (K d (25 °C)≈ 42 nm) and is salt-independent, whereas binding of CspB to C-based ssDNA template is strongly salt-dependent (no binding is observed at 1 m NaCl), indicating large electrostatic component involved in the interactions; 3) upon binding each CspB covers a stretch of 6–7 thymine bases on T-based ssDNA; and 4) the binding of CspB to T-based ssDNA template is enthalpically driven, indicating the possible involvement of interactions between aromatic side chains on the protein with the thymine bases. The significance of these results with respect to the functional role of CspB in the bacterial cold shock response is discussed.

[1]  T. Henkin Control of transcription termination in prokaryotes. , 1996, Annual review of genetics.

[2]  Wallace Rb,et al.  Oligonucleotide probes for the screening of recombinant DNA libraries , 1987 .

[3]  M. Marahiel,et al.  The major cold shock protein of Bacillus subtilis CspB binds with high affinity to the ATTGG‐ and CCAAT sequences in single stranded oligonucleotides , 1994, FEBS letters.

[4]  M. Inouye,et al.  The cold‐shock response — a hot topic , 1994, Molecular microbiology.

[5]  P. Privalov,et al.  Stability of protein structure and hydrophobic interaction. , 1988, Advances in protein chemistry.

[6]  J F Brandts,et al.  Rapid measurement of binding constants and heats of binding using a new titration calorimeter. , 1989, Analytical biochemistry.

[7]  N C Seeman,et al.  RNA double-helical fragments at atomic resolution. II. The crystal structure of sodium guanylyl-3',5'-cytidine nonahydrate. , 1976, Journal of molecular biology.

[8]  M. Marahiel,et al.  Effect of pH and phosphate ions on self‐association properties of the major cold‐shock protein from Bacillus subtilis , 1994, Protein science : a publication of the Protein Society.

[9]  G T Montelione,et al.  Solution NMR structure and backbone dynamics of the major cold-shock protein (CspA) from Escherichia coli: evidence for conformational dynamics in the single-stranded RNA-binding site. , 1998, Biochemistry.

[10]  W. M. Haynes CRC Handbook of Chemistry and Physics , 1990 .

[11]  M. Marahiel,et al.  Mutational analysis of the putative nucleic acid‐binding surface of the cold‐shock domain, CspB, revealed an essential role of aromatic and basic residues in binding of single‐stranded DNA containing the Y‐box motif , 1995, Molecular microbiology.

[12]  T. Lohman,et al.  Kinetics of protein-nucleic acid interactions: use of salt effects to probe mechanisms of interaction. , 1986, CRC critical reviews in biochemistry.

[13]  M. Inouye,et al.  The CspA family in Escherichia coli : multiple gene duplication for stress adaptation , 1998, Molecular microbiology.

[14]  M. Marahiel,et al.  Overproduction, crystallization, and preliminary X‐ray diffraction studies of the major cold shock protein from Bacillus subtilis, CspB , 1992, Proteins.

[15]  Hermann Schindelin,et al.  Universal nucleic acid-binding domain revealed by crystal structure of the B. subtilis major cold-shock protein , 1993, Nature.

[16]  M. Jezewska,et al.  Quantitative analysis of ligand-macromolecule interactions using differential dynamic quenching of the ligand fluorescence to monitor the binding. , 1997, Biophysical chemistry.

[17]  P. V. von Hippel,et al.  Cooperative and noncooperative binding of protein ligands to nucleic acid lattices: experimental approaches to the determination of thermodynamic parameters. , 1986, Biochemistry.

[18]  M. Inouye,et al.  Complete growth inhibition of Escherichia coli by ribosome trapping with truncated cspA mRNA at low temperature , 1996, Genes to cells : devoted to molecular & cellular mechanisms.

[19]  M. Jezewska,et al.  A general method of analysis of ligand binding to competing macromolecules using the spectroscopic signal originating from a reference macromolecule. Application to Escherichia coli replicative helicase DnaB protein nucleic acid interactions. , 1996, Biochemistry.

[20]  L. Beamer,et al.  Refined 1.8 p crystal structure of the ? repressor-operator complex*1 , 1992 .

[21]  G. K. Ackers,et al.  Calorimetric analysis of lambda cI repressor binding to DNA operator sites. , 1995, Biochemistry.

[22]  M. Inouye,et al.  Family of the major cold‐shock protein, CspA (CS7.4), of Escherichia coli, whose members show a high sequence similarity with the eukaryotic Y‐box binding proteins , 1994, Molecular microbiology.

[23]  T. Lohman,et al.  Thermodynamic methods for model-independent determination of equilibrium binding isotherms for protein-DNA interactions: spectroscopic approaches to monitor binding. , 1991, Methods in enzymology.

[24]  T. Lohman,et al.  Thermodynamics of single-stranded RNA and DNA interactions with oligolysines containing tryptophan. Effects of base composition. , 1993, Biochemistry.

[25]  F. Studier,et al.  Use of T7 RNA polymerase to direct expression of cloned genes. , 1990, Methods in enzymology.

[26]  M. Marahiel,et al.  Characterization of cspB, a Bacillus subtilis inducible cold shock gene affecting cell viability at low temperatures , 1992, Journal of bacteriology.

[27]  G. Montelione,et al.  Solution NMR structure of the major cold shock protein (CspA) from Escherichia coli: identification of a binding epitope for DNA. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[28]  M. Inouye,et al.  CspA, CspB, and CspG, Major Cold Shock Proteins ofEscherichia coli, Are Induced at Low Temperature under Conditions That Completely Block Protein Synthesis , 1999, Journal of bacteriology.

[29]  S. Phillips,et al.  Three-dimensional crystal structures of Escherichia coli met repressor with and without corepressor , 1989, Nature.

[30]  B. Honig,et al.  Free energy determinants of secondary structure formation: I. alpha-Helices. , 1995, Journal of molecular biology.

[31]  G. K. Ackers,et al.  Site-specific enthalpic regulation of DNA transcription at bacteriophage lambda OR. , 1992, Biochemistry.

[32]  F. Neidhardt,et al.  Induction of proteins in response to low temperature in Escherichia coli , 1987, Journal of bacteriology.

[33]  D. Hyre,et al.  Thermodynamic evaluation of binding interactions in the methionine repressor system of Escherichia coli using isothermal titration calorimetry. , 1995, Biochemistry.

[34]  P. Privalov,et al.  Energetics of protein structure. , 1995, Advances in protein chemistry.

[35]  P. Privalov,et al.  Contribution of hydration to protein folding thermodynamics. I. The enthalpy of hydration. , 1993, Journal of molecular biology.

[36]  T. Lohman,et al.  Thermodynamics of single-stranded RNA binding to oligolysines containing tryptophan. , 1992, Biochemistry.

[37]  D Court,et al.  Regulatory sequences involved in the promotion and termination of RNA transcription. , 1979, Annual review of genetics.

[38]  T Platt,et al.  Transcription termination and the regulation of gene expression. , 1986, Annual review of biochemistry.

[39]  M. Inouye,et al.  CspA, the Major Cold-shock Protein of Escherichia coli, Is an RNA Chaperone* , 1997, The Journal of Biological Chemistry.

[40]  M. Inouye,et al.  Role of the Cold-Box Region in the 5′ Untranslated Region of the cspA mRNA in Its Transient Expression at Low Temperature in Escherichia coli , 1998, Journal of bacteriology.

[41]  M. Czisch,et al.  Structure in solution of the major cold-shock protein from Bacillus subtilis , 1993, Nature.

[42]  M. Fried,et al.  DNA binding mechanism of O6-alkylguanine-DNA alkyltransferase: stoichiometry and effects of DNA base composition and secondary structure on complex stability. , 1996, Biochemistry.

[43]  R. Inman TRANSITIONS OF DNA HOMOPOLYMERS. , 1964, Journal of molecular biology.

[44]  A. Winder,et al.  Correction of light‐scattering errors in spectrophotometric protein determinations , 1971, Biopolymers.

[45]  Nan Wang,et al.  CspI, the Ninth Member of the CspA Family ofEscherichia coli, Is Induced upon Cold Shock , 1999, Journal of bacteriology.

[46]  A. Kozlov,et al.  Calorimetric studies of E. coli SSB protein-single-stranded DNA interactions. Effects of monovalent salts on binding enthalpy. , 1998, Journal of molecular biology.

[47]  K. Matsumoto,et al.  Gene regulation by Y-box proteins: coupling control of transcription and translation. , 1998, Trends in cell biology.

[48]  H. Eisenberg,et al.  Deoxyribonueleate solutions: Sedimentation in a density gradient, partial specific volumes, density and refractive index increments, and preferential interactions , 1968, Biopolymers.

[49]  T. Lohman,et al.  Thermodynamic analysis of ion effects on the binding and conformational equilibria of proteins and nucleic acids: the roles of ion association or release, screening, and ion effects on water activity , 1978, Quarterly Reviews of Biophysics.

[50]  C. Gualerzi,et al.  Massive presence of the Escherichia coli ‘majorcold‐shock protein’ CspA under non‐stress conditions , 1999, The EMBO journal.

[51]  M. Inouye,et al.  Cold shock and adaptation , 1998, BioEssays : news and reviews in molecular, cellular and developmental biology.

[52]  M. Inouye,et al.  The role of the 5'-end untranslated region of the mRNA for CspA, the major cold-shock protein of Escherichia coli, in cold-shock adaptation , 1996, Journal of bacteriology.

[53]  S. Adhya,et al.  Control of transcription termination. , 1978, Annual review of biochemistry.

[54]  I. Epstein,et al.  Cooperative and non-cooperative binding of large ligands to a finite one-dimensional lattice. A model for ligand-oligonucleotide interactions. , 1978, Biophysical chemistry.

[55]  M. Marahiel,et al.  A superfamily of proteins that contain the cold-shock domain. , 1998, Trends in biochemical sciences.

[56]  M. Marahiel,et al.  Cold shock proteins CspB and CspC are major stationary-phase-induced proteins in Bacillus subtilis , 1999, Archives of Microbiology.

[57]  K. Liu,et al.  Nascent RNA in transcription complexes interacts with CspE, a small protein in E. coli implicated in chromatin condensation. , 1998, Journal of molecular biology.

[58]  T. Lohman,et al.  Co-operative binding of Escherichia coli SSB tetramers to single-stranded DNA in the (SSB)35 binding mode. , 1994, Journal of molecular biology.

[59]  P. V. von Hippel,et al.  Theoretical aspects of DNA-protein interactions: co-operative and non-co-operative binding of large ligands to a one-dimensional homogeneous lattice. , 1974, Journal of molecular biology.

[60]  M. Inouye,et al.  Major cold shock protein of Escherichia coli. , 1990, Proceedings of the National Academy of Sciences of the United States of America.

[61]  P. Privalov,et al.  Partial molar volumes of polypeptides and their constituent groups in aqueous solution over a broad temperature range , 1990, Biopolymers.

[62]  R. C. Weast CRC Handbook of Chemistry and Physics , 1973 .

[63]  G. Wistow Cold shock and DNA binding , 1990, Nature.

[64]  M. Inouye,et al.  Promoter‐independent cold‐shock induction of cspA and its derepression at 37°C by mRNA stabilization , 1997 .