Requirement for a Functional int Product in Temperature Inductions of

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JOURNAL OF VIROLOGY, SePt. 1970, p. 320-325 Vol. 6, No. 3 Copyright 1970 American Society for Microbiology Prinited in U.S.A. Requirement for a Functional int Product in Temperature Inductions of Prophage P22 ts mnt MICHAEL GOUGH Department of Microbiology, Baylor College of Medicine, Houston, Texas 77025 Received for publication 17 April 1970 Prophage P22 ts mnt was found to be inducible by high temperatures. This property was maintained when the ts mnt allele was recombined into a phage that cannot synthesize phage deoxyribonucleic acid at high temperature. Prophage P22 int ts mnt, on the other hand, was not inducible at high temperature. This result leads to the suggestion that the int enzyme, which is involved in excision, is regulated by the product of gene mnt. Prophage P22 requires two repressors, mnt (5) and c2 (8), to maintain lysogeny (mnt is called vl in reference 14). Phages with temperaturesensitive (ts) mutations in mnt or c2 can establish and maintain lysogeny at temperatures <30 C but are induced at >40 C. When a culture of Salmonella typhimurium LT2 (P22 ts nut) is shifted from 30 C to >40 C, the number of microscopically observable cells increases for about 45 min. There is a smaller increase in the number of colony-forming units. Thus killing, defined as the loss of colony-forming ability, begins at time zero. At 30 to 45 min, the number of colony formers begins to decrease and reaches about 0.1 by 90 min. Infective centers appear at 30 to 45 min and increase in number until 120 min. The yield of infective centers is equal to the number of cells observed at 45 min (5). The kinetics of temperature induction of LT2 (P22 ts c2) are quite different. The number of viable cells, as determined by ability to form colonies, decreases from time zero and reaches <0.01 after about 20 min; infective centers increase from time zero and reach a number essentially equal to the number of colony formers by 20 min (13; unpublished observations). When LT2 (P22 ts mnt) was irradiated with ultraviolet light before being shifted from 30 to 43 C, there was no change in the kinetics of temperature induction (6). Since ultraviolet irradiation is thought to interfere with the functioning of c2 product and there was no cooperative effect of irradiation and heat, I concluded that the products of c2 and mnt do not interact and that they probably act separately to repress different phage functions (6). Infections of LT2 leading to lysogenization require at least two phage-directed activities: (i) phage-induced deoxyribonucleic acid (DNA) synthesis is regulated (11) and (ii) the phage DNA is integrated into the host chromosome (10). The first of these two requirements is satisfied by the sequential action of products of genes cl and c2 which repress DNA synthesis (11). Levine and Smith concluded that c2 continues to repress phage-directed DNA synthesis during lysogeny (9). The product of gene int, "integrase," catalyzes the required recombinational event which inserts the phage DNA into the bacterial DNA (10, 12). The gene specifying integrase must also be regulated during lysogeny, because it is involved in the reverse operation of excision as well as integration (10, 12). If int is not repressed, the prophage DNA can be cut from the chromosome, resulting in either curing or induction. The results presented in this paper show that a functional int gene is required in the prophage in order for P22 ts mnt lysogens to be temperature inducible, as measured by host killing or infective center production. This is to be contrasted to induction of prophage P22 by ultraviolet irradiation, or prophage P22 ts c2 by heat (10, 12); these prophages do not require a functional int to kill their hosts. The essential requirement for int in ts mnt-mediated inductions suggests that the relationship of mnt repression and the int function is much more intimate than is c2 repression and int. This observation is 320

VOL. 6, 1970 TEMPERATURE INDUCTIONS OF PROPHAGE P22 ts miet 321 consistent with the hypothesis that mnt product directly or indirectly represses int in the prophage. MATERIALS AND METHODS Bacteria. S. typhimurium LT2 #18 obtained from the collection of M. Levine was used for all experiments. This strain is a wild-type LT2 cured of a defective prophage by Zinder (14). A galh derivative of LT2 was used as indicator bacterium (8). Phage. The isolation of P22 ts mnt (5) and temperature-sensitive conditional lethal mutants (2, 7) has been described. Mutations in four cistrons of P22, e.g., 6, 12, 18, and 21, are known to interfere with DNA synthesis (2; Levine and Botstein, unpublished data). Phages with temperature-sensitive alleles in these cistrons are designated P22 ts 6.1, P22 ts 12.1, etc. P22 int4, intl8, and int32 were isolated by Smith and Levine (12). The plaque morphology markers m3 and h21 have been described (8). Figure 1 represents the order of genes mentioned in this paper. Media. All liquid cultures were grown in M9-CAA (8), and M9 salt solutions without glucose or amino acids were used for dilutions. Platings were made on indicator agar (8) to determine phage plaque morphology. EMB-galactose-agar was used for plating of induction experiments. The use of EMB-galactoseagar permits the scoring of lysogenic colonies, sensitive colonies, and infective centers on the same plate (8). LT2 # 18 is Gal+ and grows through Gal- bacteria used as indicator on EMB-galactose plates. Dark Gal+ colonies that are surrounded by haloes of lysis in the Gal- bacteria are scored as lysogenic bacteria. Phage crosses. Phage crosses were carried out as described previously (7), with the exception that treatment of phage-bacteria mixtures with antiserum to P22 after phage adsorption was eliminated. This step is unnecessary, under the conditions used, because >95% of the input adsorb. P22 int ts mnt was prepared by crossing P22 ts melt ts 12.1 X P22 int4, P22 intl8, and P22 int32. Lysates were plated out at 39 C on tryptone-agar to detect Mnt plaques (14); turbid centers of such plaques were picked with sterile toothpicks onto indicator agar and incubated at 25 C to determine which were Int (12). The genotype of P22 int ts mnt was verified by backcrosses. Recombinants between ts mitt and ts conditional lethal genes were prepared as follows. The plaque morphology gene m3 (8) is closely linked to ts mnt (5), and h21 (8) is linked to tsl2.1 (7; Fig. 1). To prepare P22 ts mnt ts 12.1, P22 m+ ts mnt h+ was crossed with P22 m3 tsl2.1 h21, and M+H recombinants from plating at 25 C were picked onto plates that were incubated at 39 C. Phage that did not grow at 39 C were m3 mnt int (6,21) c2 18 12 h21 FIG. 1. Partial geiietic map of phage P22. (Data from references 5, 7, 8, 11, and unpublished experimentis). scored as recombinants that were m+ ts12.1 h21. Lysates of P22 m+ tsl2.1 h21 were grown at 25 C and plated at 39 C on tryptone-agar. Phages that had reverted to tsl2.1+ plated under these conditions and could be scored for the presence of ts mnt because of the distinctive plaque morphology of is mint a 39 C (5). Phages that had been scored as m+ tsl2.1 h21 whose revertants to tsl2.1+ produced Mnt plaques at 39 C were identified as P22 m+ is mnt tsl12.1, the desired result of this cross. Similar crosses were carried out to prepare P22 is miit ts6.1, P22 ts mnt tsl8.1, and P22 ts mnt ts21.1. Preparation of lysogens. Lysogens carrying P22 int ts mnt prophages were prepared by complementation. LT2 was mixedly infected with P22 int ts mnt and P22 c2 mtii (12) at 25 C in M9-CAA, and lysogenic bacteria carrying P22 int ts mtii were isolated and purified by repeated streakings. The genetic constitution of the prophage was verified by backcrosses. Other lysogens were prepared by picking turbid centers of plaques at 25 C. Induction experiments. Cultures (10 ml) of lysogenic bacteria were grown in M9-CAA in 250-ml flasks shaken at 30 C. When a Klett-Summerson colorimeter reading corresponding to 108 bacteria per ml was reached, the bacteria were shifted to 43 C by dilution. Cultures were diluted to 103 to 2 X 103 bacteria per ml at the higher temperature in M9-CAA containing antiserum to P22 at K = 2. At intervals, 0.1-ml volumes were plated on EMB-galactose-agar. Colony-forming units and infective centers were scored after 2 days of incubation at 25 or 30 C. Plating experiments. Lysogenic bacteria were grown to late log phase at 30 C, diluted, plated, and incubated at 25 and 43 C. Dilutions were made so that each plate at 25 C produced 75 to 125 colonies after 36 to 48 hr of incubation. Colonies on the plates incubated at 43 C were counted at the same time. RESULTS Experimental induction of prophage P22 ts mnt involves a period of time at 43 C which is followed by plating of the culture at 25 C on EMB-galactose plates (5). High temperature could (i) directly and completely eliminate the biological function of mnt product or (ii) reversibly inactivate it. If the former model is correct, all steps subsequent to heating, including killing of the host and production of an infective center, could occur on the EMB-galactose plate at 25 C. On the other hand, if inactivation is reversible, some other critical phage gene product would be required to act at high temperature to cause induction. To decide between these two alternatives, LT2 (P22 ts mnt) was incubated at 43 C in M9 salts. Samples were removed at intervals and plated on EMB-galactose at 25 C. As is shown in Fig. 2, there was no decrease in colony-forming units nor any induction of infective centers for 150 min. All colony formers remained lysogenic,

322 GOUGH J. VIROL. 2.0 r 0.9, 0.8-0.7,, 0.6 Cw 0.5 _t 0. 0 15 30 45 60 75 90 105 120 135 150 TIME AFTER SHIFT TO 43 C (MINUTES) FIG. 2. LT2 (P22 ts mnt) was grown at 30 C and shifted to non-nutritive medium at 43 C. At the indicated times platings were made at 25 C. ( 0) Colony-forming ulnits. as determined by their appearance on EMBgalactose plates. This absence of effect of high temperature can be compared to Fig. 3, which shows results obtained when LT2 (P22 ts mnt) was heated in M9-CAA at 43 C. Heating LT2 (P22 ts mnt) in the absence of nutrients did not cause induction; this suggests that some metabolic activity and the functioning of some phage gene are necessary during the heat treatment in order for loss of mnt activity to result in host killing and prophage induction. At least four genes of P22 are involved in DNA synthesis (2; Levine and Botstein, unpublished data). To see whether any of these are necessary for induction of prophage P22 ts mnt, temperature-sensitive alleles of each of these four genes were recombined into P22 ts mnt, and lysogens were constructed. The results in Fig. 3 were obtained when LT2 (P22 ts mnt ts 12.1) and LT 2 (P22 ts mnt) were incubated under inducing conditions. After being shifted to 43 C, the number of colony formers in the culture of LT2 (P22 ts mnt) increased for about 40 min. At about 40 min, the number of colony formers began to decrease, and infective centers appeared. The results of heating the lysogen containing a prophage defective in DNA synthesis at high temperature were not markedly different from that of the control. The only observed difference was a slight delay in the beginning of the decrease in colony-forming units and the appearance of infective centers. Clearly, the inability of the ts 12.1 prophage to make DNA at high temperature does not prevent induction after removal of mnt product. Other experiments involving prophages P22 ts mnt ts6.1, P22 ts mnt tsl8.1, and P22 ts mnt ts21.1 produced results comparable to those shown in Fig. 3. I concluded that none of these TS alleles of genes involved in DNA synthesis prevented or greatly retarded the induction of prophage P22 ts mnt. It is conceivable, of 0 0 0 course, that the synthesis of the products of genes 6, 12, 18, and 21 is inhibited by high temperature or that the products are reversibly inactivated. If this is so, synthesis or functioning of these products could take place after the culture is plated at 25 C. It is not known whether the synthesis of the products of these genes or the products themselves are temperature-sensitive, but the results of the plating experiments in Table 1 show that doubly mutant prophages carrying ts mnt and a TS allele of a gene involved in DNA synthesis kill their hosts at 43 C with essentially the same efficiency as does prophage P22 ts mnt. Also shown in Table 1 is the much less efficient killing by prophages P22 int4 ts mnt, P22 intl8 ts mnt, and P22 int32 ts mnt when their hosts were plated at 43 C. This result shows that a functioning int gene is of much more importance to induction after inactivation of mnt product than are the "DNA genes." In contrast to the experiments shown in Fig. 3, and as expected from the results in Table 1, 6. 0 5.0 4. 0 3. 0-2. 0-0.47 0 15 30 45 60 75 90 105 120 TIME AFTER SHIFT TO 43 C (MINUTES) FIG. 3. Lysogenic LT2 strains were grown at 30 C and shifted to 43 C in M9-CAA. At the indicated times, platings were made at 25 C. Strain LT2 (P22 ts mnt): 0, colony-forming units; /L, infective centers. Strain LT2 (P22 ts mnt ts 12.1): 0, colony-forminzg units; A, infective centers.

VOL. 6, 1970 TEMPERATURE INDUCTIONS OF PROPHAGE P22 ts mnt 323 TABLE 1. Number of colony formers found when equal volumes of lysogenic S. typhimurium cultures were plated and incubated at 25 and 43 C Genotype of prophage P22 No. of colony formers Colony formers at 43 C/colony formers at 25 C Al 25 C At 43 C Wild type... 351 371 1.06 ts mnt... 921 28 0.03 ts mntts 6.1. 267 22 0.08 ts mnt ts 12... 243 0 <0.01 ts mnt ts 18... 183 0 <0.01 ts mnt ts 21.1.. 1,608 13 <0.01 intt4 ts mnt... 487 460 0.94 int 18 ts mnt. 1,040 999 0.96 int 32 ts mnt. 1,400 1,266 0.91 high temperature does not induce prophage P22 int4 ts mnt, as measured by decrease in colony-forming units or increase in infective centers. LT2 (P22 int4 ts mnt) was grown at 30 C to 108 bacteria per ml and diluted in quadruplicate to 103 bacteria per ml at 43 C. Samples (0.1 ml) were plated at intervals. The mean and standard error of the number of colonies at each time point is shown in Fig. 4. There was no decrease in the number of colony formers, and all remained lysogenic, as determined by plating on EMB-galactose plates at 25 C after exposure to 43 C. The number of infective centers produced was less than 0.01 times the number of colony formers. Very similar results were obtained when LT2 (P22 int32 ts mnt) was treated in the same way. The absence of induction when prophage P22 int ts mnt (Table 1 and Fig. 4) is heated is in marked contrast to the induction of prophages P22 ts mnt, which cannot make phage DNA at high temperature (Tabie 1 and Fig. 3). The inability of thermal inactivation of the ts mnt product to cause induction in the absence of a functional int product suggests that "turning on" the int function is a necessary step in inductions following removal of mnt product. The temporary lag in cell division observed in the growth curve of LT2 (P22 int ts mnt) between 30 and 60 min at 43 C has also been observed when nonlysogenic LT2 was subjected to the same temperature shift. Since the presence of a prophage is not necessary to cause this lag, it seems reasonable that the cell has to establish new equilibria of pool size or enzyme concentrations after the shift. The extent of the lag in division rate is variable in both lysogenic and nonlysogenic cells. 1000 900 800 700 600 500 400 o 300 m 20 0 200 100 " 1 I 0 15 30 45 60 75 90 105 120 TIME AFTER SHIFT TO 43 C (MINUTES) FIG. 4. LT2 (P22 int ts mnt) was grown at 30 C and shifted to 43 C in M9-CAA. At the indicated times, platings were made in quadruplicate at 25 C. The average number of colony-forming units (0) and the standard error are shown. DISCUSSION The involvement of int product has been studied in three different avenues of induction of prophage P22. Prophage P22 int exposed to ultraviolet irradiation kills the host bacterium with the same kinetics as does P22 int+ (10, 12). The yield of infectious phage following ultraviolet induction is, however, very much reduced by an int- allele (10, 12). Prophage P22 int ts c2 induced by a shift to high temperature also kills its host with the same kinetics as P22 int+ ts c2, but produces a small number of infectious phage and a large number of defective particles which contain both phage and bacterial DNA (10, 12). The absence of int product in these two systems has little effect on host killing, but does affect the production of infective centers and phage. The absence of int+ function when prophage P22 int ts mnt is heated prevents both host killing and infective center production. This

324 GOUGH J. VIROL. suggests that int is directly involved in inductions following removal of mnt, and, in turn, suggests that mnt regulates int. The following discussion will be based on this assumption. If the primary function of mnt is to repress int, its inactivation would allow expression of the int gene present on each prophage-bearing chromosome. In the case of prophage P22 int+ ts mnt, the expression of the int+ is sufficient to cause killing of the host and results in formation of an infective center. When prophage P22 int ts mnt is induced, the expression of int- is not sufficient to kill the host or cause induction. In the two other methods of induction, phage DNA replication may occur as a primary result of induction, and the increased gene dosage of the int- genes may be sufficient for some int function. Such in situ replication of prophage DNA has been postulated to occur after induction of X sus N prophages in Escherichia coli (4). The two genes required for maintenance of lysogeny in prophage P22 appear to produce products affecting different operators (M. Bronson, and C. Swanson and D. Botstein, personal communications; M. Gough, unpublished observations). Two operators have been found which flank c2 and are most likely involved in control of the "DNA genes." Phages bearing an operator-type mutation which maps near mnt (C. Swanson and D. Botstein, personal communication; M. Gough, unpublished observations), can be used to superinfect LT2 (P22) lysogens. One result of such superinfections is to induce the prophage. My interpretation of this observation is consistent with the idea that mnt regulates the function of int. The conjecture is that the mutant operator on the superinfecting phage cannot bind the mnt product; therefore, the int function of the superinfecting phage could be expressed constitutively and excise the prophage DNA. Induction after heating prophage P22 ts mnt proceeds through at least two stages, a killing event which begins at time zero and the appearance of infective centers which is delayed at least 15 min and lags behind the killing event until 90 to 120 min (5). The killing event could result from int-mediated excision which fails to restore the integrity of the host chromosome after the prophage DNA is cut out. The appearance of infective centers must involve irreversible changes leading toward the synthesis of mature phage. Why c2 product, which should exist after excision, fails to suppress DNA synthesis by the excised phage DNA is not clear. Perhaps in a cell killed by int-mediated excision some general effect of death results in removal of c2 repression. In addition to a model such as this in which disruption of mnt function does not directly interfere with c2 function, models which involve interactions between c2 and mnt products are possible. Experiments are being designed to investigate such models. The requirement of two repressors, mnt and c2, to maintain lysogeny in P22 is different from the one repressor needed in E. coli phage X. In X, the cl product represses synthesis of DNA synthetic enzymes directly and int product synthesis indirectly (3). Whether one or neither of these systems for the maintenance of lysogeny is "typical" for bacteriophages is, of course, unknown. Separation of the two repressor activities is probably responsible for the two immunity regulator systems found in P22 (1) as opposed to the one found in X(3). Given that immunity is a desirable attribute, the two-repressor system of P22 may be an advantage, since evolution can take place in both. From the standpoint of maintaining lysogeny, however, the two-repressor system seems to confer no advantage, because removal of either repressor results in induction. During the preparation of this manuscript, H. 0. Smith (personal communication) isolated a mutation in P22 called xis. The product of gene xis is necessary but not sufficient for excision of prophage P22. Its possible relationship to the proposed mnt-mediated repression of int is now being investigated. ACKNOWLEDGMENTS I thank 0. de la Rosa for excellent assistance, and M. Levine and H. 0. Smith for reading earlier versions of this manuscript. This research was supported by Public Health Service General Research Support grant GRS 69-16 and by National Science Foundation grant GB 12190. LITERATURE CITED 1. Bezdek, M., and P. Amati. 1968. Evidence for two immunity regulator systems in temperate bacteriophages P22 and L. Virology 36:701-703. 2. Botstein, D., and M. Levine. 1968. Synthesis and maturation of phage P22 DNA. II. Properties of temperature-sensitive phage mutants defective in DNA metabolism. J. Mol. Biol. 34:643-654. 3. Dove, W. F. 1968. The genetics of the lambdoid phages. Annu. Rev. Genet. 2:305-340. 4. Eisen, H., L. Pereira da Silva, and F. Jacob. 1968. The regulation and mechanism of DNA synthesis in bacteriophage X. Cold Spring Harbor Symp. Quant. Biol. 33:755-764. 5. Gough, M. 1968. Second locus of bacteriophage P22 necessary for the maintenance of lysogeny. J. Virol. 2:992-998. 6. Gough, M. 1969. Thermal reversal of ultraviolet-irradiation damage in Salmonella typhinurium. J. Bacteriol. 99:350-352. 7. Gough, M., and M. Levine. 1968. The circularity of the phage P22 linkage map. Genetics 58:161-169.

VOL. 6, 1970 TEMPERATURE INDUCTIONS OF PROPHAGE P22 ts mnt 325 8. Levine, M. 1957. Mutations in the temperate phage P22 and lysogeny in Salmonella. Virology 3:22-41. 9. Levine, M., and H. 0. Smith. 1964. Sequential gene action in the establishment of lysogeny. Science 146:1581-1582. 10. Smith, H. 0. 1968. Defective phage formation by lysogens of integration deficient phage P22 mutants. Virology 34:202-223. 11. Smith, H. O., and M. Levine. 1964. Two sequential repressions of DNA synthesis in the establishment of lysogeny by phage P22 and its mutants. Proc. Nat. Acad. Sci. U.S.A. 52:356-363. 12. Smith, H. O., and M. Levine. 1967. A phage P22 gene controlling integration of prophage. Virology 31:207-216. 13. Wing, J. P. 1968. Integration and induction of phage P22 in a recombination-deficient mutant of Salmontella typhimurium. J. Virol. 2:702-709. 14. Zinder, N. D. 1958. Lysogenization and superinfection immunity in Salmonella. Virology 5:291-326.