Interaction of RecBCD enzyme with DNA damaged by gamma radiation

Summary The DNA of a gene 2 mutant (T4 2 ^–) of phage T4 is degraded by RecBCD enzyme in the bacterial cytoplasm. Under normal conditions, recBCD ⁺ cells are therefore incapable of supporting the growth of phage T4 2 ^–. Only if the nucleolytic activity of RecBCD enzyme is absent from the cytoplasm are T4 2 ^–-infected bacteria able to form plaques. We found that recBCD ⁺ cells can form plaques if, before infection with T4 2 ^–, they have been exposed to gamma radiation. It is suggested that gamma ray-induced lesions of the bacterial DNA (e.g., double-strand breaks) bind RecBCD enzyme. This binding enables the enzyme to begin to degrade the bacterial chromosome, but simultaneously prevents its degradative action on the ends of minor DNA species, such as unprotected infecting phage chromosomes. Degradation of the chromosomal DNA, which occurs during the early postirradiation period, ceases about 60 min after gamma ray exposure. The reappearance of the nucleolytic action of RecBCD enzyme on T4 2 ^– DNA accompanies the cessation of degradation of bacterial DNA. Both, this cessation and the reappearance of the nucleolytic action of RecBCD enzyme on T4 2 ^– DNA depend on a functional recA gene product. These results suggest that postirradiation DNA degradation is controlled by the recA-dependent removal of RecBCD enzyme from the damaged chromosome. By making use of the temperature-sensitive mutant recB270, we showed that RecBCD-mediated repair of gamma ray-induced lesions occurs during the early postirradiation period, i.e. during postirradiation DNA degradation. It is shown that the RecD subunit of RecBCD enzyme also participates in this repair.     

Intermediates in genetic recombination of bacteriophage T7 DNA. Biological activity and the roles of gene 3 and gene 5

When Escherichia coli cells were infected with ³²P- and 5-bromodeoxyuridine-labeled T7 bacteriophage defective in genes 1.3, 2.3, 4 and 5, doubly branched T7 DNA molecules with “H” or “X”-like configurations were found in the half-heavy density fractions. Physical study showed that they are dimeric molecules composed of two parental DNA molecules (Tsujimoto & Ogawa, 1977a). The transfection assay of these molecules revealed that they were infective. Genetic analysis of progeny in infective centers obtained by transfection of dimeric molecules formed by infection of genetically marked T7 phage showed that these dimeric molecules were genetically biparental.To elucidate the roles of the products of gene 3 (endonuclease I) and gene 5 (DNA polymerase) of phage T7 in the recombination process, the ³²P/BrdUrd hybrid DNA molecules which were formed in the infected cells in the presence of these gene products were isolated, and their structures were analyzed. The presence of T7 DNA polymerase seems to stimulate and/or stabilize the interaction of parental DNAs. At an early stage of infection few dimeric molecules were formed in the absence of T7 DNA polymerase, whereas a significant number of doubly branched molecules were formed in its presence. With increasing incubation time, the multiply branched DNA molecules with a high sedimentation velocity accumulated.In contrast to the accumulation of multiply branched molecules in phage with mutations in genes 2, 3 and 4, almost all of the ³²P/BrdUrd hybrid DNA formed in phage with mutations in genes 2 and 4 were monomeric linear molecules. Shear fragmentation of monomeric linear ³²P/BrdUrd-labeled DNA shifted the density of [³²P]DNA to almost fully light density. It was also found that approximately 50% of [³²P]DNA was linked covalently to BrdUrd-labeled DNA. These linear monomer DNA molecules had infectivity and some of those formed by infection of genetically marked parents yielded recombinant phages. Therefore the gene 3 product seems to process the branched intermediates to linear recombinant molecules by trimming the branches.     

T7 Protein Synthesis in F′ Episome-Containing Cells: Assignment of Specific Proteins to Three Translational Groups

Synthesis of many T7 proteins is prevented in F′ episome-containing cells. In order to quantitate the degree of inhibition, we measured the activity of several T7 proteins in extracts prepared from T7-infected F⁻ and F′ cells and cells containing F factors mutant in phage inhibition [F′(PIF⁻2A) and F′(PIF⁻2A,2B)]. In addition, we were able to assign specific T7 proteins to the three translational units previously defined by polyacrylamide gel analysis of T7 proteins made in F⁻ and episome-containing cells. After T7 infection, the presence of the wild-type F′ (PIF⁺) episome led to greater than 90% inhibition of T7 DNA polymerase (product of gene 5), T7 lysozyme (gene 3.5), and gene 10 capsid protein synthesis. Nearly normal amounts of T7 RNA polymerase (gene 1) were made in these cells. T7 infection of cells containing the mutant F′ (PIF⁻2A) episome led to normal synthesis of T7 RNA polymerase and T7 DNA polymerase; T7 lysozyme was synthesized at 30% of the maximal level in these cells; T7 gene 10 capsid protein synthesis was inhibited by 90%, and T7 DNA synthesis was arrested in these cells. T7 infection of cells containing the mutant F′ (PIF⁻2A,2B) episome led to synthesis of normal levels of the enzymes assayed.     

High-Frequency Phage-Mediated Gene Transfer among Escherichia coli Cells, Determined at the Single-Cell Level

Recent whole-genome analysis suggests that lateral gene transfer by bacteriophages has contributed significantly to the genetic diversity of bacteria. To accurately determine the frequency of phage-mediated gene transfer, we employed cycling primed in situ amplification-fluorescent in situ hybridization (CPRINS-FISH) and investigated the movement of the ampicillin resistance gene among Escherichia coli cells mediated by phage at the single-cell level. Phages P1 and T4 and the newly isolated E. coli phage EC10 were used as vectors. The transduction frequencies determined by conventional plating were 3 × 10⁻⁸ to 2 × 10⁻⁶, 1 × 10⁻⁸ to 4 × 10⁻⁸, and <4 × 10⁻⁹ to 4 × 10⁻⁸ per PFU for phages P1, T4, and EC10, respectively. The frequencies of DNA transfer determined by CPRINS-FISH were 7 × 10⁻⁴ to 1 × 10⁻³, 9 × 10⁻⁴ to 3 × 10⁻³, and 5 × 10⁻⁴ to 4 × 10⁻³ for phages P1, T4, and EC10, respectively. Direct viable counting combined with CPRINS-FISH revealed that more than 20% of the cells carrying the transferred gene retained their viabilities. These results revealed that the difference in the number of viable cells carrying the transferred gene and the number of cells capable of growth on the selective medium was 3 to 4 orders of magnitude, indicating that phage-mediated exchange of DNA sequences among bacteria occurs with unexpectedly high frequency.     

Properties and products of the cloned int gene of bacteriophage P2

Summary Fragments of DNA of the temperate phage P2, generated by treatment with the restriction enzyme PstI, have been cloned into the plasmid pBR322. One such fragment, which has its endpoints within phage genes T and C, carries the structural P2 int gene as well as its promoter and the phage att site. When introduced into a suitable bacterial host, the cloned fragment mediates the integration and excision of int ^- mutants of P2 and recombination within the phage att site in mixed infection. All these activities are independent of the orientation of the fragment within the plasmid.When introduced into minicells, the fragment produces, in addition to the products of genes D and U, a protein of 35–37,000 daltons identified as the int protein. A study of the map location of two amber int mutants, together with the sizes of the polypeptides they produce, indicates that the P2 int gene is transcribed from right to left on the P2 map, i.e. starting near gene C and proceeding toward att.     

Active protection by bacteriophages T3 and T7 againstE. coli B-and K-specific restriction of their DNA

Summary The bacteriophages T3 and T7 are not modified and restricted byE. coli strains with different host specificity (E. coli B, K, O) in vivo. The phages code for a gene product with the ability toovercomeclassicalrestriction (ocr):ocr ^– mutants are subject to modification and restriction via DNA methylation vs cleavage. The T3 genome possesses recognition sites for the restriction endonuclease R.EcoB which, unless the DNA is B-specifically modified, trigger 5–7 DNA cleavages. Theocr gene function of T3 and T7 is located within the gene 0.3 region of these phages and is not identical with thesam (SAMase) function of T3. The mechanisms ofocr protection remains unclear, while it is certain that this protection by the gene 0.3 protein is exerted in the infected cell and not through over-all modification in the preceding growth cycle of the phage.     

Genetic deletions between directly repeated sequences in bacteriophage T7

Summary DNA sequence analysis of genetic deletions in bacteriophage T7 has shown that these chromosomal rearrangements frequently occur between directly repeated DNA sequences. To study this type of spontaneous deletion in more quantitative detail synthetic fragments of DNA, made by hybridizing two complementary oligonucleotides, were introduced into the non-essential T7 gene 1.3 which codes for T7 DNA ligase. This insert blocked synthesis of functional ligase and made the phage that carried an insert unable to form plaques on a host strain deficient in bacterial ligase. The sequence of the insert was designed so that after it is put into the T7 genome the insert is bracketed by direct repeats. Perfect deletion of the insert between the directly repeated sequences results in a wild-type phage. It was found that these deletion events are highly sensitive to the length of the direct repeats at their ends. In the case of 5 bp direct repeats excision from the genome occurred at a frequency of less than 10⁻¹⁰, while this value for an almost identical insert bracketed by 10 bp direct repeats was approximately 10⁻⁶. The deletion events were independent of a hostrecA mutation.     

A T7 amber mutant defective in DNA-Binding protein

Summary A T7 amber mutant, UP-2, in the gene for T7 DNA-binding protein was isolated from mutants that could not grow on sup ⁺ ssb-1 bacteria but could grow on glnU ssb-1 and sup ⁺ ssb ⁺bacteria. The mutant phage synthesized a smaller amber polypeptide (28,000 daltons) than T7 wild-type DNA-dinding protein (32,000 daltons). DNA synthesis of the UP-2 mutant in sup ⁺ ssb-1 cells was severely inhibited and the first round of replication was found to be repressed. The abilities for genetic recombination and DNA repair were also low even in permissive hosts compared with those of wild-type phage. Moreover, recombination intermediate T7 DNA molecules were not formed in UP-2 infected nonpermissive cells. The gene that codes for DNA-binding protein is referred to as gene 2.5 since the mutation was mapped between gene 2 and gene 3.     

DNA,RNA and protein synthesis in ØLL55-infected Lactobacillus lactis

Lactobacillus lactis cells were infected with the bacteriophage ØLL55. The changes in DNA, RNA and protein synthesis were studied by following a long-term (over 3 h) incorporation of radioactive precursors into acid-insoluble material. Stimulation of DNA synthesis caused by phage occurred 30–35 min after infection and thymidine incorporation continued for about 70 min ceasing 10–20 min before the cells started to lyse. Cumulative (¹⁴C)-uracil incorporation into RNA continued at the level of uninfected cells for 30–40 min before starting to slow up. Protein synthesis in the infected cells followed that of a control culture for 40–50 min before the further incorporation of (¹⁴C)-leucine began to decrease.The additions of antibiotic inhibitors of RNA and protein synthesis (rifampicin and chloramphenicol, respectively) at various times before or during the prereplicative period showed that rifampicin, added up to 15 min after infection and chloramphenicol, added as late as 20–25 min after infection completely prevented the initiation of phage-genome replication. The later addition of these drugs did not prevent the out-burst of thymidine up-take, but promoted, however, a deduction in the initiations of new replication cycles. The results indicate that certain genes of ØLL55 genome must be expressed at the early stages of infection to confirm a proper onset and continuation of phage DNA replication.Abbreviations Rif rifampicin - CAL chloramphenicol - TCA trichloroacetic acid - cpm counts per minute     

Infection of transformable cells ofHaemophilus influenzae by bacteriophage and bacteriophage DNA

Summary A phage HP1, infecting transformable cells ofHaemophilus influenzae Rd, has been isolated. The general properties of the wild type and of a clear plaquemutantc1 employed for most of the experiments are described. Phage DNA is infective for transformableHaemophilus cells with an efficiency (plaqueforming units of the original phage recovered as DNA-infected cells) of up to 6×10^–3. The competence ofHaemophilus cells for infection with phage DNA parallels the competence for transformation with bacterial DNA.Both HP1 and thec1 mutant are able to lysogenize their host, and the lysogenic cells are readily induced by UV. Competent non-lysogenicHaemophilus cells can be infected by DNA of lysogenic cells, thereby giving rise to phage progeny. Thus, the phage genetic material can be introduced into competentHaemophilus cells in three different ways: injection from intact phage, and infection with either phage DNA or with bacterial DNA carrying the prophage.The UV inactivation curves for infectious phage DNA and for complete phages are similar, both indicating the occurrance of host-cell reactivation. Photoreactivationin vitro of infectious phage DNA takes place to about the same high extent as observed with bacterial transforming DNA.The usefulness of this system for investigating bacterial transformation and biological effects ofin vitro treatment of DNA is discussed.with the technical assistance ofSandra J. Antoine With 4 Figures in the TextPreliminary report presented at the 7th Annual Bacterial Transformation Meeting, Aspen, Colorado, June 17–19, 1963.Supported by a travel grant from the Deutsche Forschungsgemeinschaft.Supported by Research Carreer Development Award GM-K3-7500 and Research Grant RH 00221 from the U.S. Public Health Service.     

DNA relatedness among bacteriophages of the morphological group C3

Six bacteriophages with an elongated head and a short, noncontractile tail were compared by DNA-DNA hybridization, seroneutralization kinetics, mol% G+C and molecular weight of DNA, and host range. Three phage species could be identified. Phage species 1 containedEnterobacter sakazakii phage C2,Erwinia herbicola phages E3 and E16P, andSalmonella newport phage 7–11. These phages had a rather wide host range (4 to 13 bacterial species). DNA relatedness among species 1 phages was above 75% relative binding ratio (S1 nuclease method, 60°C) when labeled DNA from phage C2 was used, and above 41% when labeled DNA from phage E3 was used. Molecular weight of DNA was about 58×10⁶ (C2) to 67 ×10⁶ (E3). The mol% G+C of DNA was 43–45. Anti-C2 serum that neutralizes all phages of species 1 does not neutralize phages of the other two species. Species 2 contains only coliphage Esc-7-11, whose host range was only oneEscherichia coli strain out of 188 strains of Enterobacteriaceae studied; it was unrelated to the other two species by seroneutralization and DNA hybridization. DNA from phage Esc-7-11 had a base composition of 43 mol% G+C and a molecular weight of about 45×10⁶. Species 3 contains onlyProteus mirabilis phage 13/3a. Its host range was limited to swarmingProteus species. Species 3 was unrelated to the other two species by seroneutralization and DNA hybridization. DNA from phage 13/3a had a base composition of 35 mol% G+C and molecular weight of about 53×10⁶. It is proposed that phage species be defined as phage nucleic acid hybridization groups.     

Site-specific integration of genes into hot spots for recombination flanking aadA in Tn21 transposons.

Summary Tn21-related transposons are widespread among bacteria and carry various resistance determinants at preferential sites, hs1 and hs2. In an in vivo integrative recombination assay it was demonstrated that these hot spots direct the integration of aminoglycoside resistance genes like aadB from Klebsiella pneumoniae and aacAI from Serratia marcescens, in a recA ^– background. The maximum required recognition sequence which must be present in both the donor and recipient plasmids is 5 CTAAAACAAAGTTA 3 (hs2). The double-site-specific recombination occurred with a frequency of 10^–5–10^–6. The resulting structures include not only replicon fusion products but also more complex structures carrying two copies of the donor plasmid or simply the donor gene flanked by hs elements. hs1 and hs2 are thought to act as recognition sites for a trans-acting site-specific recombinase. By the use of Tn21 deletion derivatives, it has been shown that the recombinase is not encoded by Tn21. This new integrative recombination system is involved in the acquisition of new genes by Tn21-related transposons and their spread among bacterial populations.     

Preferential generalized transduction by bacteriophage Mu

Summary The generalized transduction by bacteriophage Mu was found to be preferential for the 0–1 min segment of the E. coli K12 chromosome. This transduction pattern is obtained with phage lysates grown on all F^-, F⁺ and Hfr tested, and is not marker-specific.Phages grown by both lytic infection and by heat induction of prophages at different locations of the host's chromosome show the same transduction pattern, indicating that generation of transducing DNA does not directly depend on excision events. Conjugation of independently obtained Muc ⁺-lysogenic strains of HfrC with a multiauxotrophic F^- recipient strain lysogenic for a Mucts62 prophage, shows that transfer of the temperature-resistance character (Muc ⁺) is not preferentially linked to the 0–1 min segment. The lysogenizing integrations do therefore not take place within the segment preferentially transduced by the phage.A model¹ for the generation of the transducing DNA is proposed, which assumes that for its replication, Mu DNA is integrated close to the 0–1 min segment of the host chromosome, which is then preferentially replicated and packaged into the phage heads.     

Ribosomes after infection with bacteriophage T4 and T7

Summary The synthesis of E. coli ribosomal proteins ceases after infection with bacteriophages T4 or T7 as does the synthesis of most other host proteins. The shut-off does not affect all ribosomal proteins to the same extent. After T7 infection no new proteins were detected in NH₄Cl-washed ribosomal particles. Bacteriophage T4, however, induces 3–4 new protein bands demonstrated by one-dimensional gel electrophoresis. The appearance of these bands is prevented by the addition of rifampicin at the time of infection but not when rifampicin is added one minute after infection. The NH₄Cl-washed ribosomal particles present at the time of T7 or T4 infection do not show any structural changes by sedimentation, subunit dissociation, or protein analysis on two-dimensional polyacrylamide gels. However, by labeling the T7 infected cells with ³²P-phosphate, it is seen that the ribosomes become phosphorylated. The ³²P-label comigrates with ribosomal proteins. This phosphorylating activity depends on a T7 gene. The T7 protein phosphokinase utilizes ribosomes as phosphate acceptor in vitro. The T7 ribosomes (NH₄Cl-washed) still function in vitro as do ribosomal particles from uninfected cells.Paper No. 83 on Ribosomal Proteins. Preceding paper is by Isono et al., Mol. gen. Genet. 127, 191–195 (1973).     

On the relationship between host-cell reactivation and UV-reactivation in UV-inactivated phages

Summary Host-cell reactivation (HCR) and UV-reactivation (UVR) were studied in phage T1, T3 and , using as host bacteriaE. coli B, C, andK12S, as well as their non-hostreactivating mutantsB _s–1 (Ellison et al. 1960),C syn ^–(Rörsch et al. 1962), andK12S hcr ^–. The experiments gave further support to the idea that HCR is an enzymatic process. It repairs about 80 to 90 percent of otherwise lethal UV-lesions not only in phage DNA, but also in bacterial DNA. Thehcr ^– mutant isolated fromK12S for the purpose of this investigation, and thesyn ^– mutant of ColiC show a very small extent of HCR; they are not completely deficient for the HCR-enzyme.A correlation exists between the occurrence of HCR and UVR. UVR is absent in those cases where no HCR is observed. In systems with residual HCR-activity (hcr ^– andsyn ^– cells) UVR is less pronounced and has its maximum at lower UV-doses than in systems with full HCR-activity. UVR occurs also in unirradiated host-reactivating cells, if a large number of additional UV-lesions is introduced by means of superinfecting homologous phage. This effect is not observed in non-hostreactivating strains. The hypothesis is discussed that UVR is not a specific repair phenomenon by itself, but is the result of inhibition of cellular processes tending to decrease the survival.With 7 Figures in the TextThe work was supported by the Deutsche Forschungsgemeinschaft     

Characteristics of five bacteriophages of yellow-pigmented enterobacteria

Four bacteriophages (C2, C2F, E3, and E16P) belonging to morphological group C3 and one belonging to morphological group A3 (E16B) were purified by deuterium oxide gradient centrifugation and cesium chloride gradient centrifugation. Morphological group C3 phages had a densityd=1.534–1.541 and group A3 phage (E16B) had a densityd=1.492 in CsCl. Phages of morphological group C3 isolated onEnterobacter sakazakii (C2, C2F) and onErwinia herbicola (E3, E16P) were compared withSalmonella newport phage 7-11 with respect to host-range, genome size, antigenic relatedness, and ultraviolet and heat susceptibility. Phages C2 and C2F could multiply inEnterobacter cloacae, E. sakazakii, Erwinia herbicola, E. rhapontici, andLevinea malonatica; whereas phages E3, E16P, and 7-11 could multiply on these same species and onEscherichia coli and severalSalmonella serotypes. Molecular weights of phage DNAs were determined to be 58×10⁶ (C2), 60×10⁶ (7-11), 67×10⁶ (E3), and 39×10⁶ (E16B).All studied phages of morphological group C3 (includingSalmonella newport phage 7-11) were neutralized by anti-phage C2 serum. Despite differences in neutralization kinetics and in ultraviolet and heat sensitivities, these phages of morphological group C3 constitute one phage species. Phage E16B (morphological group A3) had a host-range limited toEnterobacter cloacae, Erwinia herbicola, andE. rhapontici; it was antigenically unrelated to the preceding phage group C3, and showed ultraviolet and heat susceptibility close to that of coliphage T4.     

Transduction of Plasmid Antibiotic Resistance Determinants with PseudoT-Even Bacteriophages

Transduction of antibiotic resistance determinants of the plasmid pBR322 with pseudoT-even bacteriophages RB42, RB43, and RB49 was studied. It is established that antibiotic resistance determinants of plasmid pBR322 fromEscherichia coli recA ⁺ and recA ^– donor strains do not differ significantly in respect to the efficiency of transduction. Amber mutants RB43-21, RB43-33, and a double amber mutant RB43am21am33 were obtained. These mutants facilitated transduction experiments in some cases. Transduction of antibiotic resistance markers of the vector plasmid pBR325 and recombinant plasmid pVT123, containing a DNA fragment with hoc–segE–uvsW genes of phage T4, was studied. The frequency of appearance of transductants resistant to pseudoT-even bacteriophages used in transduction was determined, and the sensitivity of resistant transductants to 32 RB bacteriophages and also to phages , T2, T4, T5, T6, T7, and BF23 was estimated. The efficiency of plating pseudoT-even bacteriophages RB42 and RB43 on strain E. coli 802 himA hip carrying mutations in genes that encode subunits of the Integration Host Factor (IHF) was shown to be higher than on isogenic strain E. coli 802. The growth of pseudoT-even bacteriophages limitedin vivo by modification–restriction systems of chromosomal (EcoKI, EcoBI), phage (EcoP1I), and plasmid (EcoRI, EcoR124I, and EcoR124II) localization was analyzed. It was shown that these phages were only slightly restricted by the type I modification–restriction systemsEcoBI, EcoR124I, and EcoR124II. Phage RB42 was restricted by systems EcoKI, EcoP1I, and EcoRI; phage RB43, by systems EcoKI and EcoRI; and phage RB49, by the EcoRI modification–restriction system.     

Recombination and hydroxyurea inhibition of DNA synthesis in yeast meiosis

Summary Hydroxyurea (HU) inhibits the premeiotic DNA replication and the meiotic events that follow, namely readiness, recombination commitment, haploidisation, sporulation commitment and ascus formation. Short incubations with HU (2–4 hrs) during the premeiotic replication (i.e. starting between 3 and 6.5 hrs in sporulation medium) allow the resumption of the replication at a normal rate following the removal of the drug. The other meiotic events are similarly delayed by the approximate length of the treatment. In these experiments, intragenic recombination in ade2 reached a higher level than in the controls (x1.3–2.0 in one pair of heteroalleles and x3.0–4.0 in another pair). The recombination response to short HU treatments was not observed for a pair of heteroalleles in ade2 that normally shows a high level of meiotic recombination (750 per 10⁶ cells), nor was the response observed in a pair of heteroalleles in lys2. HU treatments have almost no effect on sporulating cells from 8 hrs onwards. At 7–7.5 hrs the meiotic cells are very sensitive to the drug and even short treatments cause cell death and massive DNA degradation.     

Functions related to the receptor protein specified by the tsx gene of Escherichia coli

The receptor protein for the phage T6 and colicin K, coded by the tsx gene, facilitated the diffusion of all nucleosides and deoxynucleosides except cytidine and deoxcytidine through the outer membrane of Escherichia coli K-12 and Escherichia coli B. The tsx protein was coregulated with the nucleoside uptake system. Constitutive cytR and deoR mutants contained higher amounts of this protein than wild type strains. There was a good correlation between the initial rate of nucleoside uptake and the adsorption rate of phage T6. From the observation that nucleosides did not compete with each other in the translocation across the outer membrane and that they did not inhibit T6 adsorption it was concluded that the tsx protein forms a pore to which nucleosides have only little if any binding affinity.A major outer membrane protein specified by the ompA gene influenced the function of the tsx protein. Outer membranes of ompA mutants showed an enhanced binding of colicin K but the strains were colicin K insensitive (tolerant). The T6 phage adsorbed at the same rate and plated with the same efficiency as to ompA ⁺ strains. The uptake rate of thymidine and of adenosine was reduced by 16–33% in ompA mutants.The adsorption rate of phage T6 on mutants with altered lipopolysaccharide was the same or even higher than on wild type strains. However the plating efficiency was reduced ranging from 0–46%. Lipopolysaccharide plays no role in the primary adsorption of phage T6 but it is apparently required in a later step of the infection process.Non Standard Abbreviations LPS lipopolysaccharide - cAMP-CRP complex of cyclic adenosine 3,5-monophosphate (cAMP) and its receptor protein (CRP)