Purification of B. megatherium Phage G and Evidence for a Muralytic Enzyme as an Integral Part of the Phage

The Purification Of B. megatherium G phage is described and it is shown that DEAE cellulose chromatography combined with conventional methods gave a phage preparation which was at least 95 per cent pure, and contained 2.16 µg nitrogen/10¹¹ infective particles. The phage particle weight in molecular weight units was 91 x 10⁶. The small amount of contaminating material appeared to represent phage "ghosts." An essentially 1:1 ratio of particles to infective units was found when data from electron microscopic counts or data from chemical analysis were related to phage infectivity. Comparison, by several methods, of the G phage and coliphage T2 shows that T2 is 2.6 times larger than G phage. The specific activity of the muralytic component obtained by disintegration of phage preparations with urea was unchanged by the purification indicating that the phage-"bound" muralytic activity is an integral part of the phage structure.     

Nucleic acid economy in bacteria infected with bacteriophage T2. I. Purine and pyrimidine composition

1. The phosphorus content per infective particle of isolated bacteriophage T2 has been redetermined. It does not exceed 1.8 to 2.2 x 10^–11 µg. The equivalent amount of DNA has been defined in terms of several analytical methods and taken as a unit of measurement of intrabacterial DNA. 2. The DNA of E. coli contains guanine, adenine, cytosine, and thymine in approximately equal amounts, but no hydroxymethylcytosine. One bacterial cell contains 40 to 150 units of DNA, depending on the conditions of growth and the method of measurement. 3. The DNA of phage T2 (one unit per particle by definition) contains guanine, 5-hydroxymethylcytosine, and relatively large amounts of adenine and thymine, but no cytosine. 4. Infected bacteria contain DNA of a composition that varies systematically during the course of viral growth. At all times it resembles a mixture of bacterial and viral DNA. 5. The characteristic bacterial DNA is decomposed after infection, measuring about one-third its initial amount at 20 minutes. The characteristic viral DNA increases in amount, after a short delay, reaching a level of 100 to 400 units per bacterium 30 minutes after infection. At 10 minutes after infection, the two kinds of DNA are approximately equal in amount. 6. The characteristic viral DNA present in infected cells exists in two forms, one consisting of infective particles and one not. The portion not contained in infective particles builds up to 40 to 80 units per cell during the first 10 minutes after infection and afterwards remains roughly constant in amount. Infective particles begin to appear at 10 minutes and account for all or most of the increase thereafter.     

Nucleic acid economy in bacteria infected with bacteriophage T2

1. During the first 10 minutes of viral growth following infection of E. coli by phage T2 in broth, a pool of DNA is built up that contains phosphorus later to be incorporated into phage. This pool receives phosphorus from, but does not contain, the bacterial DNA. 2. After 10 minutes, DNA synthesis and phage maturation keep pace in such a way that the amount of precursor DNA increases moderately for a time and then remains constant. 3. The pool so described is defined in terms of the kinetics of transport of phosphorus from its origins in the culture medium, the bacterial DNA, and the DNA of the parental phage, to the viral progeny. The most interesting parameter of this system is the size of the precursor pool, which measures 10^–9 to 2 x 10^–9 µg. DNA-P (50 to 100 phage particle equivalents) per bacterium. 4. Neither the precursor nor the intracellular phage population exchanges phosphorus with the phosphate in the medium. More interestingly, the phosphorus in mature phage does not exchange with phosphorus in the precursor, showing that maturation is an irreversible process. 5. Maturation is also a remarkably efficient process. About 90 per cent of labeled phosphorus introduced early into the precursor pool is later incorporated into phage. 6. Viral DNA is synthesized at the rate of about 1.5 x 10^–10 µg. DNA-P (7 or 8 phage particles) per bacterium per minute. This is somewhat faster than bacterial DNA is formed, but considerably slower than RNA is formed, in uninfected bacteria. 7. The transport of phosphorus from medium to viral precursor DNA takes an average of 8 or 9 minutes, and from precursor to phage an additional 7 or 8 minutes. 8. Metabolically active RNA has been detected in infected bacteria.     

Independent functions of viral protein and nucleic acid in growth of bacteriophage

1. Osmotic shock disrupts particles of phage T2 into material containing nearly all the phage sulfur in a form precipitable by antiphage serum, and capable of specific adsorption to bacteria. It releases into solution nearly all the phage DNA in a form not precipitable by antiserum and not adsorbable to bacteria. The sulfur-containing protein of the phage particle evidently makes up a membrane that protects the phage DNA from DNase, comprises the sole or principal antigenic material, and is responsible for attachment of the virus to bacteria. 2. Adsorption of T2 to heat-killed bacteria, and heating or alternate freezing and thawing of infected cells, sensitize the DNA of the adsorbed phage to DNase. These treatments have little or no sensitizing effect on unadsorbed phage. Neither heating nor freezing and thawing releases the phage DNA from infected cells, although other cell constituents can be extracted by these methods. These facts suggest that the phage DNA forms part of an organized intracellular structure throughout the period of phage growth. 3. Adsorption of phage T2 to bacterial debris causes part of the phage DNA to appear in solution, leaving the phage sulfur attached to the debris. Another part of the phage DNA, corresponding roughly to the remaining half of the DNA of the inactivated phage, remains attached to the debris but can be separated from it by DNase. Phage T4 behaves similarly, although the two phages can be shown to attach to different combining sites. The inactivation of phage by bacterial debris is evidently accompanied by the rupture of the viral membrane. 4. Suspensions of infected cells agitated in a Waring blendor release 75 per cent of the phage sulfur and only 15 per cent of the phage phosphorus to the solution as a result of the applied shearing force. The cells remain capable of yielding phage progeny. 5. The facts stated show that most of the phage sulfur remains at the cell surface and most of the phage DNA enters the cell on infection. Whether sulfur-free material other than DNA enters the cell has not been determined. The properties of the sulfur-containing residue identify it as essentially unchanged membranes of the phage particles. All types of evidence show that the passage of phage DNA into the cell occurs in non-nutrient medium under conditions in which other known steps in viral growth do not occur. 6. The phage progeny yielded by bacteria infected with phage labeled with radioactive sulfur contain less than 1 per cent of the parental radioactivity. The progeny of phage particles labeled with radioactive phosphorus contain 30 per cent or more of the parental phosphorus. 7. Phage inactivated by dilute formaldehyde is capable of adsorbing to bacteria, but does not release its DNA to the cell. This shows that the interaction between phage and bacterium resulting in release of the phage DNA from its protective membrane depends on labile components of the phage particle. By contrast, the components of the bacterium essential to this interaction are remarkably stable. The nature of the interaction is otherwise unknown. 8. The sulfur-containing protein of resting phage particles is confined to a protective coat that is responsible for the adsorption to bacteria, and functions as an instrument for the injection of the phage DNA into the cell. This protein probably has no function in the growth of intracellular phage. The DNA has some function. Further chemical inferences should not be drawn from the experiments presented.     

DNA crosslinks,single-strand breaks and effects on bacteriophage T4 survival from tritium decay of [2-3H]adenine, [8-3H]adenine and [8-3H]guanine

Escherichia coli and bacteriophage T4 DNA containing [2-³H]adenine accumulated crosslinks between the complementary strands. For T4 DNA stored in frozen solution there were 0.41 to 0.54 crosslinks formed per tritium decay. The crosslinks were demonstrated both by an increased DNA sedimentation rate in alkaline sucrose gradients and by an increasing amount of DNA that renatured quickly after denaturation by heat or alkali. Single-strand breaks were also formed with an efficiency of 0.08 to 0.50 breaks per tritium decay. DNA containing both [8-³H]adenine and [8-³H]guanine showed no crosslinking but did undergo single-strand breaks at a rate of 0.08 per tritium decay. T4 bacteriophage containing [2-³H]adenine lost plaque-forming ability when stored at 4 °C, with 0.34 lethal hits per tritium decay, whereas the same phage labeled with a mixture of [8-³H]adenine and [8-³H]guanine sustained only 0.12 lethal hits per tritium decay. The loss of plaque-forming ability in the latter case is probably due to a radiation effect from the emitted beta particle; the high lethal efficiency for tritium decay at 2-adenine is probably caused either by crosslinks between complementary strands or from some undetected lesion produced in the DNA.     

Dual Functions of Bacteriophage T4D Gene 28 Product: Structural Component of the Viral Tail Baseplate Central Plug and Cleavage Enzyme for Folyl Polyglutamates I. Identification of T4D Gene 28 Product in the Tail Plug

The T4D bacteriophage gene 28 product is a component of the central plug of the tail baseplate, as shown by the following two independent lines of evidence. (i) A highly sensitive method for radioactive labeling of only tail baseplate plug components was developed. These labeled plug components were incorporated by a complementation procedure into new phage particles and were analyzed by radioautography after sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Three new structural proteins were found in addition to the three known tail plug proteins (i.e., gP29, gP27, and gP5). One of the three newly identified components had a molecular weight of 24,000 to 25,000 and appeared to be a product of T4D gene 28. (ii) Characterization of mutants of Escherichia coli bacteriophage T4D which produced altered gene 28 products also indicated that the gene 28 product was a viral tail component. T4D 28^ts phage particles produced at the permissive temperature had altered heat labilities compared with parent T4D particles. We isolated a single-step temperature revertant of T4D 28^ts and found that it produced phage particles which phenotypically resembled the original T4D particles. Since the properties of the phage baseplate components usually determine heat lability, these two changes in physical stability after two sequential single mutations in gene 28 supported the other evidence that the gene 28 product was a viral baseplate component. Also, compared with parent T4D particles, T4D 28^ts and T4D 28am viral particles adsorbed at different rates to various types of host cells. In addition, T4D 28^ts particles exhibited a different host range than parent T4D particles. This T4D mutant formed plaques with an extremely low efficiency on all E. coli K-12 strains tested. We found that although T4D 28^ts particles adsorbed rapidly and irreversibly to the E. coli K-12 strains, as judged by gene rescue experiments, these particles were not able to inject their DNA into the E. coli K-12 strains. On the other hand, the T4D 28^ts revertant had a plating efficiency on E. coli K-12 strains that was quite similar to the plating efficiency of the original parent, T4D. These properties of phage particles containing an altered gene 28 product supported the analytical finding that the gene 28 product is a structural component of the central plug of the T4D tail baseplate. They also indicated that this component plays a role in both host cell recognition and viral DNA injection.     

Presence of nucleoside triphosphates and calcium associated with mycobacteriophage I3

The association of nucleoside triphosphate molecules and calcium ions with purified particles of mycobacteriophage I3 has been documented. The content of nucleoside triphosphate has been determined to be 118 molecules per phage particle by equilibrium dialysis against labelled ATP or 148 molecules per phage particle by the direct determination of labelled nucleoside triphosphate. The concentration of bound Ca²⁺ exhibited a high degree of variation between different batches, which may be due to the nonspecific binding of Ca²⁺ by the virus particles. However, the tightly bound Ca²⁺ not removable by dialysis against calciumspecific chelating agent, showed a constant value of 2985 atoms/phage particle.Abbreviations EGTA Ethylene glycol-bis (-aminoethylether)-N,N¹ tetraacetic acid - PFU plaque forming unit - NTP nucleoside triphosphate     

Inactivation of bacteriophages by decay of incorporated radioactive phosphorus

The inactivation of the phages T1, T2, T3, T5, T7, and lambda by decay of incorporated P(32) has been studied. It was found that these phages fall into two classes of sensitivity to P(32) decay: at the same specific activity of P(32) in their deoxyribonucleic acid (DNA), T2 and T5 are inactivated three times as rapidly as T1, T3, T7, and lambda. Since the strains of the first class were found to contain about three times as much total phosphorus per phage particle as those of the second) it appears that the fraction of all P(32) disintegrations which are lethal is very nearly the same in all the strains. This fraction alpha depends on the temperature at which decay is allowed to proceed, being 0.05 at -196 degrees C., 0.1 at +4 degrees C., and 0.3 at 65 degrees C. Decay of P(32) taking place only after the penetration of the DNA of a radioactive phage particle into the interior of the bacterial cell can still prevent the reproduction of the parental phage, albeit inactivation now proceeds at a slightly reduced rate. T2 phages inactivated by decay of P(32) can be cross-reactivated; i.e., donate some of their genetic characters to the progeny of a mixed infection with a non-radioactive phage. They do not, however, exhibit any multiplicity reactivation or photoreactivation. The fact that at low temperatures less than one-tenth of the P(32) disintegrations are lethal to the phage particle and the dependence of the fraction of lethal disintegrations on temperature can be accounted for by the double stranded structure of the DNA macromolecule.     

Transfection of Escherichia coli Spheroplasts I. General Facilitation of Double-Stranded Deoxyribonucleic Acid Infectivity by Protamine Sulfate

The addition of 25 mug of protamine sulfate per ml to lysozyme-ethylenediamine-tetraacetic acid spheroplasts of Escherichia coli stimulates transfection not only for T1 phage deoxyribonucleic acid (DNA; Hotz and Mauser, 1969) but also for the following phage DNA species: lambda, 10,000-fold to an efficiency of 10(-3) infective centers per DNA molecule; phiX174 replicative form, 300-fold to an efficiency of 5 x 10(-2); fd replicative form, 300-fold to 10(-6); T7, 300-fold to 3 x 10(-7). Three native phage DNA species were not infective at all in the absence of protamine sulfate but were infective in the presence of protamine sulfate with the following efficiencies: T4, 10(-5); T5, 3 x 10(-6); and P22, 3 x 10(-9). The effect of protamine sulfate is specific for double-stranded DNA. The application of infectivity assays to the study of phage DNA replication, recombination, prophage integration, prophage excision, and interspecies transfection are discussed.     

Infectious DNA from coliphage T1

Summary DNA isolated from coliphage T1 is infective in spheroplasts of E. coli K12/1. The efficiency of the assay amounts to approximately 10^-4 plaque-forming units per DNA molecule of 32·10⁶ daltons. A linear relationship between DNA concentration and total phage yield or infective centers, respectively, holds for native DNA. For heat-treated DNA, however, the co-operation of 1.4 molecules is required for successful infection. Beyond a critical concentration of about 0.1g/ml a self-inhibiting effect of infectious T1-DNA is observed. Breakage by shearing and denaturation of the DNA-molecules destroy their infectious activity. Renaturation, however, restores infectivity to 60–90 per cent of the original activity. Heat treatment of T1-DNA in M/5 NCE buffer results in narrow-coiled, mismatched molecules with partially denatured regions. Though the efficiency of infection of such molecules is reduced by about 30 per cent, the critical concentration of T1-DNA shifts to higher values by a factor of ten, thus giving an increase in the total plaque yield of the system. The effect is explained by the transition of native into narrow-coiled molecular configuration.     

Decay of incorporated radioactive phosphorus during reproduction of bacteriophage T2

The multiplication of vegetative T2 bacteriophage in B/r bacteria has been followed by studying the lethal effects of decay of incorporated radiophosphorus P³² at various stages of the eclipse period. Experiment I. Non-radioactive B/r bacteria were infected with highly radioactive (i.e. P³²-unstable) T2 and infection allowed to proceed at 37°C. for various numbers of minutes before freezing the infected cells and storing them in liquid nitrogen. The longer development had been allowed to proceed at 37°C. before freezing, the slower the inactivation of the frozen infective centers by P³² decay. Samples which were frozen after incubation for 9 minutes were completely stable. Experiment II. Radioactive B/r bacteria in radioactive growth medium were infected with non-radioactive (i.e. stable) T2 and incubated for various lengths of time before being frozen and stored in liquid nitrogen, like those of Experiment I. In this case, the infective centers were stable to P³² decay as long as they were frozen before the end of the eclipse period. The T2 progeny phages issuing from the infected bacteria were P³²-unstable. Experiment III. Radioactive B/r bacteria in radioactive medium were infected with radioactive (i.e. P³²-unstable) T2 and otherwise incubated and frozen like those of the first two experiments. In this case, the same progressive stabilization, of the infective centers towards inactivation by P³² decay was observed as that found in Experiment I. The ability to yield infective progeny of infected bacteria incubated for 10 minutes at 37°C. before freezing could no longer be destroyed by P³² decay. The progeny issuing from the infected cells were as unstable as the parental phage. These results could be explained by one of three general hypotheses. As vegetative phage begins to multiply, it is possible that: (a) there is a high probability that any part of the vegetative phage already duplicated can be saved after its destruction by P³² decay through a process analogous to multiplicity reactivation or, (b) there occurs a change in state of the deoxyribonucleic acid (DNA) preliminary to or in the course of its replication that renders it refractory to destruction by P³² decay, or, finally (c) there occurs a transfer of the genetic factors from the DNA of the infecting phage to another substance not sensitive to destruction by P³² decay.     

Absence of interparental recombination in multiplicity reconstitution from incomplete bacteriophage T4 genomes.

Interparental recombination between injected T4 DNA molecules is indetectable for incomplete petite phages (carrying a terminally deficient genome and therefore unable to circularize) as well as for genetically complete phages. The nonvialbe petite phages can individually replicate their DNA repeatedly, and they aso undergo multiplicity reconstitution, producing complete phages, provided that a host bacterium is infected by several petite particles that carry genetically complementary segments of DNA. The formation of complete phages in multiplicity reconstitution must be due to recombination among incomplete progeny fragments, i.e., partial replicas of the T4 genomes. It evidently does not result from interparental recombination. To test for interparental recombination, light bacteria (containing no bromouracil) were simultaneously infected in light medium with light radioactive phage in minority (usually less than one per cell) and heavy (bromouracil-labeled) phage in majority (usually about nine per cell). Any interparental recombination should, under these circumstances of infection, head to movement of the radioactive label of the minority light phage DNA to a position of higher density. That possibility was not observed.     

Intracellular growth of bacteriophage studied by roentgen irradiation

Growing Escherichia coli infected with bacteriophage T2 was x-rayed during the 21 minute latent period which elapses between infection and lysis of the cells. Survival curves of the infected bacteria were determined almost from minute to minute; they disclosed the following facts which are related to the process of phage growth: During the first 7 minutes, the infective virus particle remains in the cell unique and genetically intact. The host cell synthesizes some ultraviolet-absorbing material probably devoted to building future particles. From the 7th to 9th minute the x-ray resistance of the virus particle increases, probably because of some internal change. Then, multiplication starts and is completed at about the 13th minute, when an average of 130 virulent units is present per cell, displaying an x-ray resistance twice as high as that of the extracellular virus particle. From 13 minutes to the end, the new units progressively recover the x-ray sensitivity of the extracellular virus. Nothing can be said about either the rate of multiplication between 9 and 13 minutes, or the nature of the multiplying units, except that they are more radiation-resistant (probably smaller) than the extracellular virus. The first steps of the growth process are favored by an unknown component of the lysate, different from the active particles. Several particles can grow in the same host cell.     

In vitro packaging of bacteriophage T7 DNA requires ATP.

Removal of nucleoside triphosphates from extracts prepared from bacteriophage T7-infected Escherichia coli results in a stringent requirement for added ATP to form infective phage particles by in vitro packaging of bacteriophage T7 DNA. Optimal packaging efficiency was achieved at a concentration of about 1.25 mM. Other nucleoside triphosphates could be substituted for ATP, but none of the common nucleoside triphosphates was as effective as ATP in promoting in vitro encapsulation.     

Ultraviolet mutagenesis in bacteriophage T-4. I. Irradiation of extracellular phage particles

Drake, John W. (University of Illinois, Urbana). Ultraviolet mutagenesis in bacteriophage T4. I. Irradiation of extracellular phage particles. J. Bacteriol. 91:1775-1780. 1966.-Ultraviolet (UV) irradiation of extracellular T4 phage particles induces about 2 x 10(-4)r mutations per lethal hit. The mutants largely escape detection unless the irradiated phages are plated with very soft overlay agar. Multiplicity reactivation is not a prerequisite for mutagenesis. A much higher frequency of base pair substitution-type mutants is induced than is found in the spontaneous background, but sign mutants are also induced. Nearly half of the mutants map into previously identified UV hot spots. The rII mutants induced extracellularly are very similar to those induced intracellularly. The mutants also appear to result from direct radiation effects upon the bacteriophage deoxyribonucleic acid.     

THE GROWTH OF BACTERIOPHAGE

1. An anti-Escherichia coli phage has been isolated and its behavior studied. 2. A plaque counting method for this phage is described, and shown to give a number of plaques which is proportional to the phage concentration. The number of plaques is shown to be independent of agar concentration, temperature of plate incubation, and concentration of the suspension of plating bacteria. 3. The efficiency of plating, i.e. the probability of plaque formation by a phage particle, depends somewhat on the culture of bacteria used for plating, and averages around 0.4. 4. Methods are described to avoid the inactivation of phage by substances in the fresh lysates. 5. The growth of phage can be divided into three periods: adsorption of the phage on the bacterium, growth upon or within the bacterium (latent period), and the release of the phage (burst). 6. The rate of adsorption of phage was found to be proportional to the concentration of phage and to the concentration of bacteria. The rate constant k_a is 1.2 x 10^–9 cm.⁸/min. at 15°C. and 1.9 x 10^–9 cm.⁸/min. at 25°. 7. The average latent period varies with the temperature in the same way as the division period of the bacteria. 8. The latent period before a burst of individual infected bacteria varies under constant conditions between a minimal value and about twice this value. 9. The average latent period and the average burst size are neither increased nor decreased by a fourfold infection of the bacteria with phage. 10. The average burst size is independent of the temperature, and is about 60 phage particles per bacterium. 11. The individual bursts vary in size from a few particles to about 200. The same variability is found when the early bursts are measured separately, and when all the bursts are measured at a late time.     

Studies related to the head-maturation pathway of bacteriophages T4 and T2: II. Nuclear disruption,protein synthesis and particle formation with the mutant 43−·30−·46−

We describe the aberrant phage multiplication of the triple conditional lethal mutant 43^?(polymerase)· 30^?(ligase)·46^?(exonuclease) of bacteriophage T4D in which phage DNA replication is arrested but some late protein synthesis occurs (33). The nuclear disruption is indistinguishable from wild type. Forty-five empty small and empty large particles are assembled per cell when the multiplicity of infection (m.o.i.) is 100. This number corresponds closely to the 38 phage equivalents of cleaved major head protein determined biochemically. By reducing the m.o.i. the number of observable particles decreases, reaching 1–5 per cell at an m.o.i. of 5(+5). The total synthesis of phage related proteins is not significantly dependant on the m.o.i. The synthesis of late proteins is about 10% of that of wild type at high m.o.i. and decreases with the m.o.i. The different early and late proteins do not show the same relative proportions as in wild type and respond differently to an increased m.o.i. These and other results are discussed with respect to the role of phage DNA in prehead assembly and head maturation.     

CYTOCHEMICAL STUDY ON THE PANCREAS OF THE GUINEA PIG : VII. Effects of Spermine on Ribosomes

Pancreatic ribosomes (guinea pig) aggregate and lose upon treatment with polyamines, particularly spermine, their bound secretory enzymes. Spermine, at 0.5 mM, for example, causes the release of about 85 per cent of the chymotrypsinogen and RNase, and from 85 to 100 per cent of the ribosomal amylase. At the same time, the particles lose about 10 per cent of their RNA, 7 to 24 per cent of their total protein, and from 75 to 100 per cent of their Mg⁺⁺. Observations with the electron microscope confirm the heavy agglutinating of the ribosomes but otherwise show little change in the structure of the particles. Using radioactive spermine it was found that, concomitant with the loss of bound enzymes and Mg⁺⁺ from the ribosomes, spermine became bound to the particle. The extent of binding ranged from 0.29 to 1.49 µmoles per 10µmoles RNA-P. The bound radioactive spermine can be removed by subsequent treatment of the ribosomes with GTP, ATP, or P-P, which treatment also removes most of the RNA of the particles, leaving behind ribosomes with a much lower RNA/protein ratio. From this evidence it was inferred that spermine, in releasing the Mg⁺⁺ of the particle, becomes salt-linked to the free phosphate hydroxyl groups of the RNA. Freshly isolated pancreatic and hepatic ribosomes contain very little spermine, about 0.1 to 0.2 µmoles polyamine/10 µmoles RNA-P. The results are discussed in terms of the linkages between the structural protein, the bound secretory enzymes, and the RNA of the ribosomes.     

Effect of Temperature on the Activities of Cytochrome c Oxidase and Respiration in Cassava Root Mitochondria

Cosmid pR4Cl is a derivative of multicopy plasmid pIJ365 which has an insertion of the cos (cohesive end site) region of actinophage R4 [T. Morino, H. Takahashi and H. Saito, Mol. Gen. Genet., 198, 228 (1985)]. When the donor R4 phage was propagated in S. lividans carrying the plasmid, the phage lysate contained transducing particles which encapsulated head-to-tail concatemers of the plasmid DNA. These particles could mediate transfer of the plasmid at a high frequency. We examined conditions that gave a maximum transduction frequency of cosmid pR4Cl. Conditions which depress R4 phage propagation, such as incubation of recipient S. parvulus at a high temperature, improved the frequency. Obviously such conditions minimized the lethal effect of viable phage propogation. The highest transduction frequency obtained so far was around 3 × 10^-3 transductants per infected phage when S. lividans was used as the recipient. This was about 30 per cent of the cosmid transducing particles estimated from the cosmid DNA content in the transducing lysate. The significance of cosmid transduction for gene manipulation in Streptomyces strains is also discussed.