Summary
We have isolated and characterized a novel int mutant of phage λ. This mutant promotes efficient recombination between the phage and bacterial attachment sites, but, unlike wild type, does not promote efficient recombination of any other pair of attachment sites tested in most conditions. IN particular, recombination between two phage or two prophage attachment sites is poor relative to the wild type frequency. We attribute this unusual phenotype to differences in the distribution of int protein binding sites among different attachment sites (Ross and Landy 1982, 1983). We suggest that int protein molecules bound to one of two recombining DNAs interact with empty sites or with bound proteins on the other, and that the mutant protein acts efficiently only if the distribution of protein binding sites within the two attachment sites is that of the attP-attB pair. Similar discrimination among attachment site pairs by wild type int protein may also modulate recombination frequencies.
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References
Abraham J, Echols H (1981) Regulation of int gene transcription by bacteriophage λ. Location of the RNA start generated by an int constitutive mutation. J Mol Biol 146:157–165
Adhya S, Cleary P, Campbell A (1968) A deletion analysis of prophage λ and adjacent genetic regions. Proc Natl Acad Sci USA 61:956–962
Bachman B, Low KB (1980) Linkage map of Escherichia coli K12, Edition 6. Microbiol Rev 44:1–56
Better M, Lu C, Williams R, Echols H (1982) Site-specific DNA condensation and pairing mediated by the int protein of bacteriophage λ. Proc Natl Acad Sci USA 79:5837–5841
Better M, Wickner S, Auerbach J, Echols H (1983) Role of the xis protein of bacteriophage λ in a specific reactive complex at the attR prophage attachment site. Cell 32:161–168
Daniels D, Schroeder J, Szybalski W, Sanger F, Blattner F (1983) A molecular map of bacteriophage λ. In: Hendrix R, Roberts J, Stahl F, Weisberg R (eds) Lambda II. Cold Spring Harbor Press, New York, pp 467–517
Enquist L, Weisberg R (1976) The red plaque test: a rapid method for identification of excision-defective variants of bacteriophage λ. Virology 72:147–153
Enquist L, Weisberg R (1977a) Flexibility in attachment site recognition by λ integrase. In: Bukhari A, Shapiro J, Adhya S (eds) DNA Insertion elements, plasmids and episomes. Cold Spring Harbor Press, New York, pp 343–348
Enquist L, Weisberg R (1977b) A genetic analysis of the att-int-xis region of coliphage λ. J Mol Biol 111:97–120
Enquist LW, Kikuchi A, Weisberg RA (1979) The role of λ intergrase in integration and excision. Cold Spring Harbor Symp Quant Biol 43:1115–1120
Goldberg A, Howe M (1969) New mutants in the S cistron of bacteriophage λ affecting host cell lysis. Virology 38:200–202
Gottesman ME, Yarmolinsky M (1968a) Integration negative mutants of bacteriophage lambda. J Mol Biol 31:487–505
Gottesman ME, Yarmolinsky M (1968b) The integration and excision of the bacteriophage lambda genome. Cold Spring Harbor Symp Quant Biol 33:735–747
Guarneros G, Echols H (1973) Thermal asymmetry of site-specific recombination by bacteriophage λ. Virology 52:30–38
Herskowitz I, Signer E (1970) A site essential for expression of all late genes in bacteriophage lambda. J Mol Biol 47:545–556
Hsu P-L, Ross W, Landy A (1980) The λ phage att site: functional limits and interaction with int protein. Nature 285:85–91
Landy A, Ross W (1977) Viral integration and excision. Structure of the lambda att sites. Science 197:1147–1160
Kikuchi Y, Nash H (1979) Nicking-closing activity associated with bacteriophage λ int gene product. Proc Natl Acad Sci USA 76:3760–3764
Mizuuchi K, Weisberg R, Enquist L, Mizuuchi M, Buraczynska M, Foeller C, Hsu P-L, Ross W, Landy A (1981) Structure and function of the phage λ att site: size, int-binding sites and location of the crossover point. Cold Spring Harbor Symp Quant Biol 45:429–437
Mizuuchi M, Mizuuchi K (1980) Integrative recombination of bacteriophage λ: Extent of the DNA sequence involved in attachment site function. Proc Natl Acad Sci USA 77:3220–3224
Nash H (1974) λ attB-attP. A λ derivative containing both sites involved in integrative recombination. Virology 57:207–216
Nash H, Enquist L, Weisberg R (1977) On the role of the bacteriophage λ int gene product in site-specific recombination. J Mol Biol 116:627–631
Nash H, Mizuuchi K, Enquist LW, Weisberg RA (1981) Strand exchange in λ integrative recombination: genetics, biochemistry, and models. Cold Spring Harbor Symp Quant Biol 45:417–428
Nash H, Mizuuchi K, Weisberg R, Kikuchi Y, Gellert M (1976) Integrative recombination of bacteriophage λ — the biochemical approach to DNA insertions. In: Bukhari A, Shapiro J, Adhya S (eds) DNA Insertion elements, plasmids and episomes. Cold Spring Harbor Press, New York, pp 363–374
Parkinson JS (1971) Deletion mutants of bacteriophage lambda II. Genetic properties of att-defective mutants. J Mol Biol 56:385–401
Ross W, Landy A (1982) Bacteriophage lambda int protein recognizes two classes of sequence in the phage att site: characterization of arm-type sites. Proc Natl Acad Sci USA 79:7724–7728
Ross W, Landy A (1983) Pathways of λ int recognition in the region of strand exchange. Cell 33:261–272
Ross W, Landy A, Kikuchi Y, Nash H (1979) Interaction of int protein with specific sites on lambda att DNA. Cell 18:297–307
Shapiro J, Adhya S (1969) The galactose operon of E. coli K-12. II. A deletion analysis of operon structure and polarity. Genetics 62:249–264
Shimada K, Campbell A (1974) Lysogenization and curing by int-constitutive mutnats of phage λ. Virology 60:157–165
Shimada K, Campbell A (1974) Int-constitutive mutants of bacteriophage lambda. Proc Natl Acad Sci USA 71:237–241
Shimada K, Weisberg RA, Gottesman ME (1972) Prophage lambda at unusual chromsomal locations. I. Location of the secondary attachment sites and the properties of the lysogens. J Mol Biol 63:483–503
Shimada K, Weisberg R, Gottesman M (1973) Prophage lambda at unusual chromosomal locations. II. Mutations induced by bacteriophage lambda in Escherichia coli K12. J Mol Biol 80:297–314
Shimada K, Weisberg R, Gottesman M (1975) Prophage lambda at unusual chromosomal locations. III. The components of the secondary attachment sites. J Mol Biol 93:415–429
Shulman M, Gottesman M (1973) Attachment site mutants of bacteriophage lambda. J Mol Biol 81:461–482
Sternberg N, Hamilton D, Enquist L, Weisberg R (1979) A simple technique for the isolation of deletion mutants of phage lambda. Gene 8:35–51
Wang J, Davidson N (1968) Cyclization of phage DNAs. Cold Spring Harbor Symp Quant Biol 33:409–415
Weil J, Signer E (1968) Recombination in bacteriophage λ. Sitespecific recombination promoted by the integration protein. J Mol Biol 34:273–279
Weisberg RA (1970) Requirements for curing of λ lysogens. Virology. 41:195–199
Weisberg RA, Gottesman ME (1969) The integration and excision defect of bacteriophage λ dg. J Mol Biol 46:565–580
Weisberg R, Landy A (1983) Site-specific recombination in bacteriophage λ. In: Hendrix R, Roberts J, Stahl F, Weisberg R (eds) Lambda II. Cold Spring Harbor Press, New York, pp 211–250
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Communicated by G.R. Smith
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Enquist, L.W., Weisberg, R.A. An integration-proficient int mutant of bacteriophage λ. Mol Gen Genet 195, 62–69 (1984). https://doi.org/10.1007/BF00332725
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DOI: https://doi.org/10.1007/BF00332725