Résumé
Sans préjuger de la nature ou de l’origine des bactériophages, on peut dire qu’ils se comportent d’une façon générale comme des virus. Ils se sont révélés un matériel de choix pour l’étude de la génétique de ces agents en raison de la facilité de leur manipulation et de la vitesse de leur multiplication. Leur numération peut se faire de manière simple et précise, car chaque particule de phage, déposée à la surface d’une culture continue d’une bactérie indicatrice sensible, donne naissance à une tache de lyse macroscopiquement visible et facile à compter.
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Bibliographie
Adams, M. H.: (1) A heat resistant mutant of bacterial virus T. 5. Bull. N. Y. Acad. Med. 26, 566 (1950).
— (2) Methods of study of bacterial viruses. Methods in Medical Research. Vol. 2. Chicago: Year Book Pub. (1950).
— The hybridization of coliphage T. 5 and salmonella phage PB. J. Immunol, 67, 313 (1951).
— (1) The genotypically and phenotypically heat resistant forms in the T. 5 species of bacteriophage. Ann. Inst. Pasteur, 84, 164 (1953).
— (2) Virus and Rickettsial classification and nomenclature. Annals N. Y. Acad. Sci. 56, 442 (1953).
Adams, M. H. and G. Lark: Mutation to heat resistance in coliphage T. 5. J. Immunol. 64, 335 (1950).
Anderson, E. S. and A. Felix: (1) The Vi-type determining phages carried by Salmonella typhi. J. gen. Microbiol. 9, 65 (1953).
— (2) “Degraded Vi strains” and variation in Vi-phage II of Salmonella typhi. J. gen. Microbiol. 8, 408 (1953).
Anderson, T. F.: The inheritance of requirements for adsorption cofactors in the bacterial virus T. 4. J. Bacter. 55, 651 (1948).
Appleyard, R. K.: Segregation of lambda lysogenicity during bacterial recombination in E. coli K. 12. Cold Spring Harbor Symp. Quant. Biol. 18, 95 (1953).
— (1) Segregation of lambda lysogenicity during bacterial recombination in Escherichia coli K. 12. Genetics 39, 429 (1954).
— (2) Segregation of new lysogenic types during growth of a doubly lysogenic strain derived from Escherichia coli K. 12. Genetics 39, 440 (1954).
Barksdale, W. L. and A. M. Pappenheimer: Phage-Host relationships in non toxigenic and toxigenic diphteria bacilli. J. Bacter. 67, 220 (1954).
Baron, L. S.: Genetic transfer by means of Vi-phage lysates. Cold Spring Harbor Symp. Quant. Biol. 18, 271 (1953).
Baron, L. S., S. B. Formal and W. Spilman: Use of Vi-phage lysates in genetic transfer. Proc. Soc. exper. Biol. Med. 83, 292 (1953).
— Vi Phage-Host interaction in Salmonella typhosa. J. Bacter. 69, 177 (1955).
Bertani, G.: Studies on lysogenesis. I. The mode of phage liberation by lysogenic Escherichia coli. J. Bacter. 62, 293 (1951).
— Studies on lysogenesis. III. Superinfection of lysogenic Shigella dysenteriae with temperate mutants of the carried phage. J. Bacter. 67, 696 (1954).
Bertani, G. and J. J. Weigle: Host controlled variation in bacterial viruses. J. Bacter. 65, 113 (1953).
Beumer, J. et M. P. Beumer-Jochmans: Importance de l’hôte bactérien pour les besoins en calcium d’un bacteriophage. Ann. Inst. Pasteur 89, 394 (1955).
Bowen, G. H.: Studies of ultraviolet irradiation phenomena — an approach to the problems of bacteriophage reproduction. Cold Spring Harbor Symp. Quant. Biol. 18, 245 (1953).
Boyd, J. S. K.: (1) Observations on the relationship of symbiotic and lytic bacteriophage. J. Path. Bacter. 63, 445 (1951).
— (2) Mutation in a bacterial virus. Nature 168, 994 (1951).
— Bacteriophage and heredity. Nature 173, 1050 (1954).
Bresch, C.: Genetical studies on bacteriophage T. 1. Ann. Inst. Pasteur 84, 157 (1953).
Brown, E. R., W. B. Cherry, M. D. Moody and M. A. Gordon: The induction of motility in Bacillus anthracis by means of bacteriophage lysates. J. Bacter 69, 590 (1955).
Burnet, F. M. and D. Lush: Induced lysogenicity and mutation of bacteriophage within lysogenic bacteria. Australian Journ. exper. Biol. 14, 27 (1936).
Cavalli, L. L., J. Lederberg and E. M. Lederberg: An infective factor controlling sex compatibility in Bacterium coli. J. gen. Microbiol. 8, 89 (1953).
Craigie, J.: The significance and applications of bacteriophage in bacteriological and virus research. Bacter. Reviews 10, 73 (1946).
Delbrück, M.: Interference between bacterial viruses. III. The mutual exclusion effect and the depressor effect. J. Bacter. 50, 151 (1945)
Delbrück, M.: Biochemical mutants of bacterial viruses. J. Bacter. 56, 1 (1948).
Delbrück, M. and W. T. Bailey Jr.: Induced mutations in bacterial viruses. Cold Spring Harbor Symp. Quant. Biol. 11, 33 (1946).
Delbrück, M. and S. E. Luria: Interference between bacterial viruses. I. Interference between 2 bacterial viruses acting upon the same host, and the mechanism of virus growth. Arch. Biochem. 1, 111 (1942).
De Mars, R. I.: Chemical mutagenesis in bacteriophage T. 2. Nature 172, 964 (1953).
Demerec, M., H. Moser, J. Hemmerly, I. Blomstrand, Z. E. Demerec, P. L. Fitzgerald, S. W. Glover, J. F. Hanson, F. J. Nielsen and T. Yura: Bacterial genetics. I. Carnegie Inst. Wash. Year Book 53, 225 (1954).
Doermann, A. H.: The vegetative state in the life cycle of bacteriophage: evidence for its occurence and its genetic characterization. Cold Spring Harbor Symp. Quant. Biol. 18, 3 (1953).
Doermann, A. H., M. Chase and F. W. Stahl: Genetic recombination and replication in bacteriophage. J. cell. comp. Physiol. 45, 51 (1955).
Doermann, A. H. and C. F. R. Dissosway: Intracellular growth and genetics of bacteriophage. Carnegie Inst. Wash. Yearbook 48, 170 (1949).
Doermann, A. H. and M. B. Hill: Genetic structure of bacteriophage T. 4 as described by recombination studies of factors influencing plaque morphology. Genetics 38, 79 (1953).
Dooren de Jong, E. L. den: Studien über Bakteriophagie. I. Über Bac. megatherium und den darin anwesenden Bakteriophagen. Zentralbl. Bakter. I. Orig. 120, 1 (1931).
Dulbecco, R.: The number of particles of bacteriophage T. 2 that can participate in intracellular growth. Genetics 34, 126 (1949)
Dulbecco, R.: A critical test of the recombination theory of multiplicity reactivation. J. Bacter. 63, 199 (1952).
Edwards, P. R., B. R. Davis and W. B. Cherry: Transfer of antigens by phage lysates with particular reference to the 1, w antigens of Salmonella. J. Bacter. 70, 279 (1955).
Ellis, E. L. and M. Delbrück: The growth of bacteriophage. J. gen. Physiol. 22, 365 (1939).
Epstein, H. T.: The properties of Bacteriophages. Advances in Virus Research 1, 1 (1953).
Evans, E. A.: Bacterial viruses (Reference to synthesis of). Ann. Rev. Microbiology 8, 237 (1954).
Felix, A. and E. S. Anderson: Bacteriophages carried by the Vi-phage-types of Salmonella typhi. Nature 167, 603 (1951).
Fernandez, B., F. L. Haas and O. Wyss: Induced host-range mutations in bacteriophage. Proc. nat. Acad. Sci. 39, 1053 (1953).
Fischer, G.: (1) On the occurence of heat-resistant variants in a pure anticoli bacteriophage. Acta Path. Microbiol. Scand. 27, 129 (1950).
— (2) Variations of an E. coli virus (anticolibacteriophage). Acta Path. Microbiol. Scand. 27, 937 (1950).
Fodor, A. R. and M. H. Adams: Genetic control of serological specificity in bacteriophage. J. Immunol. 74, 228 (1955).
Foster, R. A. C.: An analysis of the action of proflavine on bacteriophage growth. J. Bacter. 56, 795 (1948).
Fraser, D. and R. Dulbecco: A genetic analysis of the factors controlling the h character in bacteriophage T. 3. Cold Spring Harbor Symp. Quant. Biol. 18, 15 (1953).
Fredericq, P.: Actions antibiotiques réciproques chez les Enterobacteriaceae. Rev. belge Pathol. et Med. expér. 19, suppl. 4, 1 (1948).
— (1) Une mutation de bacteriophage intéressant son spectre d’activité. C. R. Soc. Biol. 144, 1140 (1950).
— (2) Sur l’irrégularité des taches produites par le mutant T. 1’ du bacteriophage T. 1. C. R. Soc. Biol. 144, 1260 (1950).
Fredericq, P.: (1) Colicines et bactériophages. Ann. Inst. Pasteur 84, 294 (1953).
— (2) Transfert génétique des propriétés lysogènes chez E. coli. C. R. Soc. Biol. 147, 2046 (1953).
— (1) Transduction génétique des propriétés colicinogènes chez Escherichia coli et Shigella sonnei. C. R. Soc. Biol. 148, 399 (1954).
— (2) Rôle éventuel des propriétés lysogènes dans la transduction des propriétés colicinogènes chez Escherichia coli. C. R. Soc. Biol. 148, 624 (1954).
— (3) Intervention du facteur de polarité sexuelle F dans la transduction des propriétés colicinogènes chez Escherichia coli. C. R. Soc. Biol. 148, 746 (1954).
— (4) Localisation du prophage sur le chromosome. Son intervention dans le taux de ségrégation apparent des recombinants d’Escherichia coli K. 12. C. R. Soc. Biol. 148, 1501 (1954).
— (5) Induction de la production de colicine par irradiation ultraviolette de souches colicinogènes d’Escherichia coli. C. R. Soc. Biol. 148, 1276 (1954).
— (1) Colicines et bactériophages dans la génétique bactérienne. Ann. Soc. roy. Sci. med. nat. Bruxelles 8, 15 (1955).
— (2) Recherches génétiques sur la localisation du prophage λ sur le chromosome d’E. coli et sur son intervention dans la ségrégation de divers marqueurs. C. R. Soc. Biol. 149, 840 (1955).
— (3) Induction de la production de colicine et de bactériophages par irradiation ultraviolette de souches colicinogènes et lysogènes d’Escherichia coli. C. R. Soc. Biol., 149, 2028 (1955).
Fredericq, P. et M. Betz-Bareau: (1) Transfert génétique de la propriété de produire un antibiotique. C. R. Soc. Biol. 147, 1653 (1953).
— (2) Transfert génétique de la propriété colicinogène en rapport avec la polarité F des parents. C. R. Soc. Biol. 147, 2043 (1953).
Fredericq, P. et A. Gratia: Actions stimulantes spécifiques de certains bactériophages sur les activités microbiennes. Ann. Inst. Pasteur 79, 612 (1950).
Freeman, V. J.: Studies on the virulence of bacteriophage-infected strains of Corynebacterium diphtheriae. J. Bacter. 61, 675 (1951).
Freeman, V. J. and I. U. Morse: Further observations on the change to virulence of bacteriophage-infected avirulent strains of Corynebacterium diphtheriae. J. Bacter. 63, 407 (1952).
Friedman, M.: The effect of the host on the properties and sensitivity of a bacterial virus. J. Bacter. 68, 274 (1954).
Goebel, W. F., G. T. Barry, M. A. Jesaitis and E. M. Miller: Colicine K. Nature 176, 700 (1955).
Groman, N. B.: (1) Evidence for the induced nature of the change from non toxigenicity to toxigenicity in Corynebacterium diphtheriae as a result of exposure to specific bacteriophage. J. Bacter. 66, 184 (1953).
— (2) The relation of bacteriophage to the change of Corynebacterium diphtheriae from avirulence to virulence. Science 117, 297 (1953).
Hamon, Y. et Z. Lewe: Etude de l’induction par l’irradiation ultraviolette de quelques cultures d’E. coli K. 12 préalablement rendues colicinogènes par transduction. Ann. Inst. Pasteur 89, 336 (1955).
Hayes, A.: (1) The mechanism of genetic recombination in Escherichia coli. Cold Spring Harbor Symp. Quant. Biol. 18, 75 (1953).
— (2) Observations on a transmissible agent determining sexual differentiation in Bacterium coli. J. gen. Microbiol. 8, 72 (1953).
Hershey, A.D.: (1) Mutation of bacteriophage with respect to type of plaque. Genetics 31, 620 (1946).
— (2) Spontaneous mutations in bacterial viruses. Cold Spring Harbor Symp. Quant. Biol. 11, 67 (1946).
— Inheritance in Bacteriophage. Advances in Genetics 5, 89 (1953).
Hershey, A. D. and M. Chase: Genetic recombination and heterozygosis in bacteriophage. Cold Spring Harbor Symp. Quant. Biol. 16, 471 (1951).
Hershey, A. D. and H. Davidson: Allelic and non-allelic genes controlling host specificity in a bacteriophage. Genetics 36, 667 (1951).
Hershey, A. D., A. Garen, D. K. Fraser and J. D. Hudis: Growth and inheritance in bacteriophage. Carnegie Inst. Washington Year Book 53, 210 (1954).
Hershey, A. D., C. Roesel, M. Chase and S. Forman: Growth and inheritance in bacteriophage. Carnegie Inst. Washington Year Book 50, 195 (1951).
Hershey, A. D. and R. Rotman: Linkage among genes controlling inhibition of lysis in a bacterial virus. Proc. Nat. Acad. Sci., U. S. 34, 89 (1948).
— Genetic recombination between host-range and plaque type mutants of bacteriophage in single bacterial cells. Genetics 34, 44 (1949).
Hewitt, L. F.: (1) Autoadaptation of bacterial viruses and its effect on bacterial variation and evolution. J. gen. Microbiol. 11, 261 (1954).
— (2) Mechanism of virulence transfer by bacterial viruses. J. gen. Microbiol. 11, 272 (1954).
— (3) The effect of certain antibiotics and other chemotherapeutic agents on lysogenicity and virulence transfer by bacterial viruses in Corynebacterium diphtheriae. J. gen. Microbiol. 11, 288 (1954).
Ionesco, H.: Sur une propriété de Bacillus megaterium liée à la présence d’un prophage. C. R. Acad. Sci. 237, 1794 (1953).
Iseki, S. and T. Sakai: (1) Artifical transformation of O antigens in Salmonella E. group. I. Transformation by antiserum and bacterial autolysate. Proc. Japan. Acad. 29, 121 (1953).
— (2) Artificial transformation of O antigens in Salmonella E. group. II. Antigen transforming factor in bacilli of subgroup E 2. Proc. Japan Acad. 29, 127 (1953).
— Transduction of biochemical properties in Salmonella E. group. Proc. Japan Acad. 30, 143 (1954).
Jacob, F.: (1) Mutation d’un bactériophage induite par l’irradiation des seules bactéries-hôtes avant l’infection. C. R. Acad. Sci. 233, 732 (1954).
— (2) Les bactéries lysogènes et la notion de provirus. Monographies de F Inst. Pasteur, Masson, Paris (1954).
— Transduction of lysogeny in Escherichia coli. Virology 1, 207 (1955).
Jacob, F., L. Siminovitch et E. Wollman: Sur la biosynthèse d’une colicine et sur son mode d’action. Ann. Inst. Pasteur 83, 295 (1952).
Jacob, F. et E. L. Wollman: (1) Etude génétique d’un bactériophage tempéré d’Escherichia coli. I. Le système génétique du bactériophage λ. Ann. Inst. Pasteur 87, 653 (1954).
— (2) Induction spontanée du développement du bactériophage λ au cours de la recombinaison génétique chez Escherichia coli K. 12. C. R. Acad. Sci. 239, 317 (1954).
— Etude génétique d’un bactériophage tempéré d’Escherichia coli. III. Effet du rayonnement ultraviolet sur la recombinaison génétique. Ann. Inst. Pasteur 88, 724 (1955).
Jacob, F., E. Wollman et L. Siminovitch: Propriétés inductrices des mutants virulents d’un phage tempéré. C. R. Acad. Sci. 236, 544 (1953).
Kauffmann, F.: On the transduction of serological properties in the Salmonella group. Acta Path. Microb. Scand. 33, 409 (1954).
Latarjet, R.: Mutation induite chez un virus par irradiation ultraviolette de cellules infectées. C. R. Acad. Sci. 228, 1354 (1949).
Latarjet, R. and P. Fredericq: An X-ray study of a colicine and of its relationship to bacteriophage T. 6. Virology 1, 100 (1955).
Lederberg, E. M. and J. Lederberg: Genetic studies of lysogenicity in Escherichia coli. Genetics 38, 51 (1953).
Lederberg, J.: Cell genetics and hereditary symbiosis. Physiol. Reviews. 32, 403 (1952).
— Recombination mechanisms in bacteria. J. cell. comp. Physiol. 45, 75 (1955).
Lederberg, J. and P. R. Edwards: Serotypic recombination in Salmonella. J. Immunol. 71, 232 (1953).
Lederberg, J., E. M. Lederberg, N. D. Zinder and E. R. Lively: Recombination analysis of bacterial heredity. Cold Spring Harbor Symp. Quant. Biol. 16, 413 (1951).
Lederberg, J. and E. L. Tatum: Gene recombination in Escherichia coli. Nature 158, 558 (1946).
Lennox, E.: Transduction of linked characters of the host by bacteriophage P. 1. Virology 1, 190 (1955).
Levinthal, C.: Recombination in phage: its relationship to heterozygosis and growth. Cold Spring Harbor Symp. Quant. Biol. 18, 13 (1953).
— Recombination in phage T. 2: its relationship to heterozygosis and growth. Genetics 39, 169 (1954).
Levinthal, C. and N. Visconti: Growth and recombination in bacterial viruses. Genetics 38, 500 (1953).
Luria, S. E.: Mutations of bacterial viruses affecting their host range. Genetics 30, 84 (1945).
— Reactivation of irradiated bacteriophage by transfer of self reproducing units. Proc. Nat. Acad. Sci. U. S. 33, 253 (1947).
— (1) Lethal mutations produced by ultraviolet light in bacteriophage. Exp. Cell. Res., suppl. I, 171. (1949).
— (2) Type hybrid bacteriophages. Records Genetic Soc. America 18, 102 (1949).
— Spontaneous mutations in the study of virus reproduction. Genetics 35, 676 (1950).
— The frequency distribution of spontaneous bacteriophage mutants as evidence for the exponential rate of phage reproduction. Cold Spring Harbor Symp. Quant. Biol. 16, 463 (1951).
— (1) Host-induced modifications of viruses. Cold Spring Harbor Symp. Quant. Biol. 18, 237 (1953).
— (2) General Virology. Wiley and Sons, New York (1953).
Luria, S. E. and M. Delbrück: Mutations of bacteria from virus sensitivity to virus resistance. Genetics 28, 491 (1943).
Luria, S. E. and R. Dulbecco: Genetic recombinations leading to production of active bacteriophage from ultraviolet inactivated bacteriophage particles. Genetics 34, 93 (1949).
Luria, S. E. and M. L. Human: A non hereditary host-induced variation of bacterial viruses. J. Bacter. 64, 557 (1952).
Lwoff, A.: Lysogeny. Bacter. Reviews 17, 269 (1953).
Morse, M. L.: Transduction of certain lociin Escherichiacoli K. 12. Genetics 39, 984 (1954).
Murphy, J. S.: Mutants of a bacteriophage of Bacillus megatherium. J. exper. Med. 96, 581 (1952).
— Recombination of mutant phages of Bacillus megatherium 899a. J. exper. Med. 98, 657 (1953).
— Some mutant phages produced directly by Bacillus megatherium 899 a with their rate of occurence. J. exper. Med. 100, 657 (1954).
Mutsaars, W.: Résistance du bactériophage aux acridines. Ann. Inst. Pasteur 80, 65 (1951).
Nicolle, P. et Y. Hamon: Recherches sur les facteurs qui conditionnent l’appartenance des bacilles paratyphiques B aux différents types bactériophagiques de Felix et Callow. III. Nouvelles études sur les transformations de types par l’action des bactériophages extraits des bacilles lysogènes. Ann. Inst. Pasteur 81, 614 (1951).
Novick, A. and L. Szilard: Virus strains of identical phenotype but different genotype. Science 113, 345 (1951).
Parsons, E. I. and M. Frobisher: Effect of bacteriophage on virulence of Corynebacterium diphtheriae. Proc. Soc. exper. Biol. Med. 78, 746 (1951).
— Bacteriophage and the toxigenicity of Corynebacterium diphtheriae. Amer. J. publ. Hlth. 43, 269 (1953).
Price, W. H.: Bacterial viruses. Ann. Rev. Microbiology 6, 333 (1952).
Raettig, H.: Experimentelle Untersuchungen über Entwicklungsvorgänge bei Bakteriophagen. 5. Die Entwicklung von neuen Valenzen und Typen bei Diagnostik-Phagenstämmen. Zbl. Bakter. I. Orig. 161, 11 (1954).
Ralston, D. J. and A. P. Krueger: Phage multiplication on two hosts. Isolation and activity of variants of Staphylococcus phage P. 1. Proc. Soc. exper. Biol. Med. 80, 217 (1952).
— The isolation of a staphylococcal phage variant susceptible to an unusual hostcontrol. J. gen. Physiol. 37, 685 (1954).
Rautenstein, Y. I.: Une mutation induite d’actinophage (en russe). Mikrobiologija 23, 140 (1954).
Sakai, T. and S. Iseki: Artificial transformation of O antigens in Salmonella E. group. III. Physicochemical properties of antigen transforming factor in bacilli of subgroup E. 2. Gunma J. Med. Sci. 2, 235 (1953).
Scholtens, R. T.: (1) The formation of bacteriophages in mixed cultures by recombination of genetic elements; characterisation of phage types of Salmonella paratyphi B by phage reactions and lysogenic properties. Ant. van Leeuwenhoek 18, 257 (1952).
— (2) La formation de bactériophages dans les cultures mixtes de souches de Salmonella paratyphi B. C. R. Soc. Biol. 146, 504 (1952).
Silvestri, L.: Studi sull’azione dell’azotoiprite (metildibetacloroetilammina) sul batteriofago anticoli T. 2. Boll. Ist. Sieroter. Milanese 28, 326 (1949).
Stent, G. S.: Cross-reactivation of genetic loci of T. 2 bacteriophage after decay of incorporated radioactive phosphorus. Proc. Nat. Acad. Sci. 39, 1234 (1953).
Stocker, B. A. D., N. D. Zinder and J. Lederberg: Transduction of flagellar characters in Salmonella. J. gen. Microbiol. 9, 410 (1953).
Uetake, H., T. Nakagawa and T. Akiba: The relationship of bacteriophage to antigenic changes in group E. Salmonella. J. Bacter. 69, 571 (1955).
Visconti, N.: Genetics of bacteriophage. Ann. Inst. Pasteur 84, 180 (1953).
Visconti, N. and R. C. Coon: Recombination in bacteriophage. Carnegie Inst. Washington Year Book 51, 207 (1952).
Visconti, N. and M. Delbrück: The mechanism of genetic recombination in phage. Genetics 38, 5 (1953).
Visconti, N. and A. Garen: Unity of the vegetative pool in phage-infected bacteria. Proc. nat, Acad. Sci. 39, 620 (1953).
Wahl, R. et L. Blum-Emerique: Mutation du phage C. 16 caractérisée par l’acquisition de l’activité sur les bactéries résistantes des cultures secondaires. Ann. Inst. Pasteur 78, 336 (1950).
Watson, J. D.: Inactivating mutations produced by X-rays in bacteriophages. Genetics 33, 633 (1948).
— The properties of X-ray inactivated bacteriophage. I. Inactivation by direct effect. J. Bacter. 60, 697 (1950).
Weigle, J. J.: Induction of mutations in a bacterial virus. Proc. nat. Acad. Sci. 39, 628 (1953).
Weigle, J. J. et J. Bertani: Variations des bactériophages conditionnées par les bactéries hôtes. Ann. Inst. Pasteur 84, 175 (1953).
Weigle, J. J. and R. Dulbecco: Induction of mutations in bacteriophage T. 3 by ultraviolet light. Experientia 9, 372 (1953).
Welsch, M.: Mutation d’un actinophage. C. R. Soc. Biol. 148, 2099 (1954).
Wollman, E. L.: Sur le déterminisme génétique de la lysogénie. Ann. Inst. Pasteur 84, 281 (1953).
Wollman, E. L. et F. Jacob: (1) Etude génétique d’un bactériophage tempéré d’Escherichia coli. II. Mécanisme de la recombinaison génétique. Ann. Inst. Pasteur 87, 674 (1954).
— (2) Lysogénie et recombinaison génétique chez Escherichia coli K. 12. C. R. Acad. Sci. 239, 455 (1954).
Zinder, N. D.: Infective heredity in bacteria. Cold Spring Harbor Symp. Quant. Biol. 18, 261 (1953).
— Bacterial transduction. J. cell. comp. Physiol. 45, 23 (1955).
Zinder, N. D. and J. Lederberg: Genetic exchange in Salmonella. J. Bacter. 64, 679 (1952).
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Fredericq, P. (1958). Génétique des Bactériophages. In: Hallauer, C., Meyer, K.F. (eds) Handbuch der Virusforschung. Springer, Vienna. https://doi.org/10.1007/978-3-7091-7885-0_2
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