Effects of ammonia on growth and morphology of thermophilic hydrogen-oxidizing methanogenic bacteria

Abstract: Seven bacteriophage (Φ1R, Φ10W, Φ3R, Φ30W, Φ1261 M, Φ1261 V and Φgor3V), specific for the Rhizobium galegae species and representing three morphotypes, were isolated from different locations in Finland and in New Zealand. DNA was isolated from these phage and from phage Φ1R-3 and Φ1R', which were derived from Φ1R in the laboratory, and analyzed by restriction endonuclease digestion and dot blot DNA hybridization. The sizes of the phage DNAs were estimated to range from 45.1–114.6 kb. The restriction patterns revealed four different phage genotypes, which correlated with the isolation hosts. DNA hybridization showed that the four genotypes were distantly related. The genotypes were distinguished when purified phage protein was analyzed in SDS-PAGE gels.     

The archaeal halophilic virus-encoded Dam-like methyltransferase M. phiCh1-I methylates adenine residues and complements dam mutants in the low salt environment of Escherichia coli

The genome of the archaeal virus phiCh1, infecting Natrialba magadii (formerly Natronobacterium magadii), is composed of 58.5 kbp linear ds DNA. Virus particles contain several RNA species in sizes of 100-800 nucleotides. A fraction of phiCh1 genomes is modified within 5'-GATC-3' and related sequences, as determined by various restriction enzyme digestion analyses. High performance liquid chromatography revealed a fifth base, in addition to the four nucleosides, which was identified as N6-methyladenosine. Genetic analyses and subsequent sequencing led to the identification of a DNA (N6-adenine) methyltransferase (mtase) gene. The protein product was designated M.phiCh1-I. By the localization of the most conserved motifs (a DPPY motif occurring before FxGxG), the enzyme was placed within the beta-subgroup of the (N6-adenine) methyltransferase class. The mtase gene of phiCh1 was classified as a 'late' gene, as determined by measuring the kinetics of mRNA and protein expression in N. magadii during the lytic cycle of phiCh1. After infection of cells, M.phiCh1-I mRNA and protein could be detected in lower amounts than in the situation of virus induction from lysogenic cells. Consequently, only about 5% of the phiCh1 progeny genomes after infection of N. magadii carry the M.phiCh1-I methylation in contrast to 50% of virus genomes generated by induction of phiCh1-lysogenic N. magadii cells. Heterologous expression of the mtase from a halophile with 3 M cytoplasmic salt concentration showed an unexpected feature: the protein was active in the low environment of Escherichia coli and was able to methylate DNA in vivo. Interestingly, it seemed to exhibit a higher sequence specificity in E. coli that resulted in adenine methylation exclusively in the sequence 5'-GATC-3'. Additionally, expression of M.phiCh1-I in dam- E. coli cells led to a complete substitution of the function of M.Dam in DNA mismatch repair.     

Structure of the intracellular part of the motility apparatus of halobacteria

he electron microscopic study of the structure of the motility apparatus of the archaea Halobacterium salinarium 4W12 and Natronobacterium magadii confirmed our earlier observation that the motility apparatus of halobacteria contains an intracellular disk-shaped lamellar structure (DLS). Polar cap structures (PCSs) isolated from the halobacterium were preliminarily identified as the DLSs. The PCSs in complexes with flagella were also isolated from the haloalkaliphilic bacterium N. magadii. The specific structure of the archaeal motility apparatus is discussed.     

Isolation of a halobacterial phage with a fully cytosine-methylated genome

Summary A new bacteriophage from Halobacterium halobium has been isolated and partially characterized. It is not homologous to the phage H (Schnabel, et al. 1982) which infects the same bacterium, though it appeared spontaneously in a culture of H adapted to H. halobium NRL/JW. The size and morphology of N are comparable to that of other known halophages. The genome of N consists of linear double-stranded DNA, 56 kb in size, whose dCMP is totally replaced by 5-methyl-dCMP. This is the second case of a fully cytosine-methylated genome, the bacteriophage XP12 from Xanthomonas oryzae, being so far the only one reported. Like H, the N, genome seems to have terminal redundancy and circular permutation. N is the first halobacterial phage which survives prolonged exposure to low ionic strength environments. After 48 h incubation in distilled water a loss in infectivity of less than 50% is observed.     

Virulence as a consequence of genome instability of a novel temperate bacteriophage, ΦRsG1, of Rhodobacter sphaeroides Y

A novel temperate bacteriophage, designated RsG1, was isolated from Rhodobacter sphaeroides Y (previously designated Rhodopseudomonas sphaeroides) following exposure to mitomycin C. The phage morphology, as revealed from electron microscopy, showed a hexagonal head (90 by 46.5 nm) connected with a tail (116 by 9.4 nm), to which a collar was proximally attached. A morphologically similar phage was also produced by spontaneous lysis of the cells. While RsG1 did not grow on any other bacterial strain tested, spontaneously produced phage particles propagated (and formed plaques) on R. sphaeroides Y still carrying RsG1 in the prophage state. The genome of RsG1 consisted of double stranded linear DNA with cohesive ends and a GC-content of 71.8 mol%. The DNA molecules formed circles in vitro with a mean contour length of 17.18±0.4 m, which corresponds to a size of 49 kbase pairs (kb). On the other hand, DNA extracted from the virulent phage particles was heterogeneous and consisted of two DNA species of different size, occurring in a ratio of about 1:1. These molecules also circularized having contour lengths of 17.18±0.4 m and 14.02±0.41 m corresponding to 49 and 40 kb, respectively. Restriction digest analysis of the two DNA species and DNA from RsG1 indicated that they are similar, and allowed the indentification of an 11.5 kb EcoRI fragment that carries the cohesive ends. Because DNA from RsG1 and the 49 kb DNA of the virulent phage particles were indistinguishable with the criteria applied, it is suggested that phage particles containing the 40 kb DNA represent the virulent type of phage, termed RsG1.1.     

Properties of R plasmid R772 and the corresponding pilus-specific phage PR772.

R plasmid R772 was isolated from a strain of Proteus mirabilis and is a self-transmissible P-1 incompatibility group plasmid having a molecular weight of about 27 x 10(6). It renders bacterial hosts resistant to kanamycin. Phage PR772 was isolated as a phage dependent on the presence of R772 in bacterial hosts. It is hexagonal-shaped with a diameter of 53 nm, has a thick inner membrane and no tail. Vaguely defined appendages are sometimes apparent at some vertices and the phage possesses double-stranded DNA. The DNA has a guanine plus cytosine molar content of 48%. The phage is sensitive to chloroform and has a buoyant density of 1.26 g cm(-3). These observations suggested that the inner membrane of the phage could contain lipid. Phage PR772 differs in morphology from the double-stranded DNA plasmid-specific phages PR4 and PRR1 which adsorb to tips and sides, respectively, of sex pili coded for by P-1 incompatibility group plasmids. Phage PR772 formed clear plaques which varied in diameter. Serologically, phages PR772 and PR4 are possibly related though very distantly, but the two phages have identical host ranges. Phage PR772 adsorbed by one of its apices to tips of sex pili coded for by plasmid R772 in Escherichia coli. It also formed plaques on Salmonella typhimurium Proteus morganii and Providence strains harbouring this plasmid as well as strains of E. coli carrying plasmids of incompatibility groups N or W. The phage produced areas of partial clearing on lawns of P. mirabilis PM5006 harbouring plasmid R772, the P-1 incompatibility group plasmid RP4, the W group plasmid RSa or the N group plasmid N3, and on lawns of Providence strain P29 carrying plasmid RP4.     

Effect of chitosan oligomer on phage particles and reproduction of phage 1-97A in Bacillus thuringiensis culture]

The causes of bacteriophage 1-97A inactivation by the chitosan oligomer with a polymerization degree of 15 and the influence of the oligomer on the phage reproduction in the culture of Bacillus thuringiensis subsp. galleriae, strain 1-97, were studied. The study of the inactivation kinetics showed that, in 1 h, virtually all chitosan was bound to the phage particles, causing, as evidenced by electron microscopy, DNA release from the phage head, destruction of the phage particles, and agglutination of the phage particles or of their tails in the region of the endplate. High-polymeric chitosan caused more pronounced destruction of the phage particles than the oligomer. It was established that chitosan prevented the production of complete phage particles. One of the mechanisms of such an influence may be the production in the presence of chitosan of phage particles devoid of DNA.     

Characterization of Phages Virulent for <Emphasis Type="Italic">Robinia pseudoacacia</Emphasis> Rhizobia

Three lytic phages (ΦRP1, ΦRP2, and ΦRP3) specific for Robinia pseudoacacia rhizobia were isolated from the soil under black locust. They were characterized by their morphology, host range, and some other properties including DNA molecular weights. Studied phages have been found to belong to Siphoviridae family that comprises viruses with long, and noncontractile tails. They had broad host ranges and effectively lysed not only Robinia pseudoacacia microsymbionts but also different Mesorhizobium species. The phages were homogenous in latent periods (300 min) but heterogeneous in burst sizes (100–200 phage particles per one infected cell) and rise periods (90–120 min). They showed a distinct adsorption rate to Robinia pseudoacacia rhizobia (70.4–93.94%). The molecular weights of phage DNAs estimated from restriction enzyme digests were in the range from ca. 82 kb to ca. 105 kb.     

Sequence analysis of Escherichia coli O157:H7 bacteriophage ΦV10 and identification of a phage-encoded immunity protein that modifies the O157 antigen

Bacteriophage ΦV10 is a temperate phage, which specifically infects Escherichia coli O157:H7. The nucleotide sequence of the ΦV10 genome is 39 104 bp long and contains 55 predicted genes. ΦV10 is closely related to two previously sequenced phages, the Salmonella enterica serovar Anatum (Group E1) phage ɛ15 and a prophage from E. coli APEC O1. The attachment site of ΦV10, like those of its two closest relatives, overlaps the 3' end of guaA in the host chromosome. ΦV10 encodes an O -acetyltransferase, which modifies the O157 antigen. This modification is sufficient to block ΦV10 superinfection, indicating that the O157 antigen is most likely the ΦV10 receptor.     

Characterization of phage isolates from a phage-carrying culture of Leuconostoc oenos 58N

Summary During large-scale cultivation of Leuconostoc oenos strain 58N, growth inhibition was detected and attributed to the presence of the virulent phage P581. To determine if this phage originated from a temperate phage, L. oenos 58N was exposed to mitomycin C, and this treatment led indeed to release of phages (P58II). Further examination of the lytic potential of phages P581 and P58II revealed that these two phages were able to lyse the same strains of L. oenos with the exception of the original host strain, which was only sensitive to P581. Results of DNA/DNA hybridization experiments failed to show homology between the DNA of phage P58II and the chromosomal DNA of L. oenos 58N. A phage-free culture of L. oenos 58N could be obtained after repeated subculture. These results indicate that the original L. oenos 58N was in a special type of phage-carrier state. Phages P58I and P58II were compared on the basis of morphology, lytic spectra, restriction enzyme analysis, DNA homology, genome size and protein structure and proved to be identical. It is assumed that P58I arose from the phage-carrier culture of L. oenos 58N and became virulent by some mutational event.Offprint requests to: E. K. Arendt     

Wide host range and strong lytic activity of Staphylococcus aureus lytic phage Stau2

In searching for an alternative antibacterial agent against multidrug-resistant Staphylococcus aureus, we have isolated and characterized a lytic staphylophage, Stau2. It possesses a double-stranded DNA genome estimated to be about 134.5 kb and a morphology resembling that of members of the family Myoviridae. With an estimated latency period of 25 min and a burst size of 100 PFU/infected cell, propagation of Stau2 in liquid culture gave a lysate of ca. 6 × 10(10) PFU/ml. It was stable at pH 5 to 13 in normal saline at room temperature for at least 4 weeks and at -85°C for more than 2 years, while 1 × 10(9) out of 2 × 10(12) PFU/ml retained infectivity after 36 months at 4°C. Stau2 could lyse 80% of the S. aureus isolates (164/205) obtained from hospitals in Taiwan, with complete lysis of most of the isolates tested within 3 h; however, it was an S. aureus-specific phage because no lytic infection could be found in the coagulase-negative staphylococci tested. Its host range among S. aureus isolates was wider than that of polyvalent phage K (47%), which can also lyse many other staphylococcal species. Experiments with mice demonstrated that Stau2 could provide 100% protection from lethal infection when a multiplicity of infection of 10 was administered immediately after a challenge with S. aureus S23. Considering these results, Stau2 could be considered at least as a candidate for topical phage therapy or an additive in the food industry.     

Characterization of SE1, a new general transducing phage of Salmonella typhimurium

A transducing phage, SE1, which is able to infect Salmonella typhimurium was isolated from a Salmonella enteritidis strain. SE1 is a temperate phage which is heteroimmune with respect to phages P22, L, KB1 and ES18. It is similar in morphology and size to phages P22, L and KB1 and is serologically related to phages P22 and L but not to KB1. Efficiencies of generalized transduction effected by phage SE1 are similar to those for P22HT (int7), a mutant which mediates a high frequency of chromosomal gene transduction. The lengths of chromosomal DNA transduced by SE1 and P22HT (int7) are similar. Furthermore, the SE1 prophage does not exclude the transducing particles from cells it has lysogenized; consequently it is possible to use both SE1 lysogens and non-lysogenic strains as recipients in SE1-mediated transduction experiments, and obtain similar transduction efficiencies. However, the SE1 prophage gives rise to a lysogenic conversion that decreases the rate of adsorption of SE1 and L phages by about 50%, but does not affect adsorption of P22. Altogether these results suggest that phage SE1 may be a useful tool in the genetic manipulation of S. typhimurium.     

Multiple density classes of phage P1 due to tetramer formation

Summary Stocks of coliphage P1 contain infective phage particles (P1), a smaller morphological variant (pP1) and single phage tails. In crude stocks and under certain conditions these particles form stable aggregates of four by adhesion of their base plates. It happens that all the aggregates of P1, pP1 and tails having densities above 1.41 g/cm³ are distributed around five values: 1.422, 1.435, 1.450, 1.459 and 1.473 g/cm³. Consequently they form five rather distinct bands when examined by analytical centrifugation. Formation and dissociation of tetramers results in loss and recovery of phage infectivity. Tetramers formed of four P1 particles have a sedimentation constant of 1,185 S as compared to 715 S for single P1 particles. Within the limits of our methods we could not detect any P1 or pP1 particles containing amounts of DNA different from 10^–16 g and 4×10^–17 g, respectively.     

Mapping of the c-region of phage phi80

A set of c-mutants of the phage phi80 is isolated. These mutants fit into three genes. According to plaque morphology and frequency of lysogenization of mutants, the genes were named cI, cII and cIII as it was previously done for phage lambda. Their order, determinated by mutant phage crosses, is cIII-sus326-cI-cII-sus250. Sus326 is a mutation in the gene 15, so it is probably an analogue of the N gene of the phage lambda. Thermoinducible mutants of the phage phi80 cts11 and cts12 correspond to the mutant types cItsB and cItsA of the phage lambda and they complement each other. Thus, it is supposed that phi80 phage repressor molecules consist of few protein subunits.     

Growth and phage production of B. megatherium. I. Growth of cells after infection with C phage. II. Rate of growth,phage yield,and RNA content of cells. III. Effect of various substances on growth rate and phage production

I. Lysogenic B. megatherium 899a (de Jong, 1931) produces two types of phage (Gratia, 1936 c) T and C. The T phage forms cloudy plaques and gives rise to fresh lysogenic strains (Gratia, 1936 b) when added to the sensitive strain of megatherium. It may or may not cause lysis, depending on the media (Northrop, 1951). The C phage occurs very rarely) forms clear plaques, does not give rise to lysogenic strains, and causes complete lysis of the sensitive strain under all conditions tested, provided infection occurs. If C phage is added to the sensitive strain, and the mixture allowed to stand, or made into a hanging drop preparation, the infected cells stop growing and lyse completely after 60 to 80 minutes with the liberation of from 50 to 200 phage particles per cell. If, however, C phage is added to a rapidly growing culture of B. megatherium and the suspension shaken at 34°, the cells continue to grow and divide for 50 to 60 minutes, after infection has occurred. They then lyse, with the liberation of from 1000 to 2500 phage particles per cell. II. The following determinations have been made on megatherium sensitive cells growing in 5 per cent peptone at different stages of growth. (1) Growth rate of infected and uninfected cells; (2) RNA, DNA, and protein content; (3) volume of the cell; (4) phage yield per cell by plaque count; (5) phage yield per cell by cell and plaque count; (6) lysis time. The growth rate decreases as the cell concentration increases. The lysis time and the protein N per cell are nearly independent of the growth rate; all the other values increase as the growth rate increases. The ratio See PDF for Equation is nearly constant. RNA and DNA per cell increase less rapidly than the volume, so that NA per unit volume is not constant, but decreases as the size of the cell increases. The phage yield measured under conditions in which the infected cells do not grow (by plaque count) is very nearly proportional to the size of the cell. The phage yield per cell, under conditions in which the infected cells do grow, increases more rapidly than the size of the cells. The phage yield per cell under these conditions may be calculated by the equation See PDF for Equation The determining factor for the variation in phage yield is the growth rate of the cells. This, in turn, is determined by the composition of the medium. III. The growth and phage production of megatherium 899a have been determined in the presence of the following substances: aureomycin, bacitracin, chloromycetin, gramicidin, Merck AB631, Merck AB191, Merck AB624, penicillin, streptomycin, terramycin, tyrothricin, usnic acid, acetone, chloroform, ethyl alcohol, formaldehyde, gentian violet, glycerin, maleic hydrazide, methyl alcohol, phenyl mercuric acetate, sodium fluoride, sulfanilamide, toluene, and urethane. In every case, the lowest concentration of the substance which completely inhibits growth, is also the lowest concentration which completely inhibits phage production. One antibiotic, Merck AB81, causes increased phage production in concentrations which partially inhibit growth, and low phage production in concentrations which completely inhibit growth (as determined by turbidity). Short exposure to ultraviolet light also decreases the growth rate, with increase in phage production. Longer exposure, which completely inhibits growth (as determined by turbidity) results in lysis and phage liberation.     

DNA-mediated transformation in mutants of phage group 2 Staphylococcus aureus

A large pool of antibiotic resistant and auxotrophic mutants was isolated from the Staphylococcus aureus phage group 2 strains UT0002-19 and UT0017 by (1) antibiotic gradient plates, (2) trimethoprim selection, and (3) nitrosoguanidine mutagenesis, which sometimes was coupled by enrichment with either penicillin or methicillin. Strain UT0002-19 has a chromosomal determinant for exfoliative toxin (ET), which causes "scalded skin syndrome" in man. A few mutants were isolated from the phage group 1 strain UT0080, which also produces ET. Two transformation regimens, called the broth and plate methods, were devised for the phage group 2 strains. They employed 80 alpha as helper phage, and recipient cells were incubated with transforming DNA in the presence of Ca2+. Strain UT0080 was transformed using phage 55 as helper. Maximum competence of the phage group 2 strains occurred during early logarithmic growth in trypticase soy broth, but cells grown overnight on heart infusion agar were also competent. Transformation frequencies of all markers ranged from 10(-6) to 10(-8). For phage 80 alpha, a multiplicity of infection of 4 was optimal in transforming a mutant of strain UT0002-19. Transformation of gly, lin, met, ole, rif, and ser markers in S. aureus is reported for the first time. Ery and ole markers in all three strains exhibited cross-resistance. Mapping studies, similar to those performed by DNA-mediated transformation in the phage group 3 strain 8325, can now be commenced for phage group 2 strains of S. aureus in order to elucidate the molecular genetics of this medically important bacterium.     

Properties of a mutant of Escherichia coli defective in bacteriophage lambda head formation (groE). I. Initial characterization

Three mutant strains of Escherichia coli were independently isolated based upon their inability to propagate bacteriophage λ. The strain most extensively studied, NS-1, has a pleiotropic temperature sensitive alteration that affects cell growth, stable RNA synthesis and λ propagation. Labeling experiments and colorimetric determinations of total RNA carried out in this strain demonstrate that within the first five minutes after raising the temperature to 44.5 °C the rate of total RNA accumulation is reduced to a level that is about 15% that of the control, while protein and DNA synthesis continue at nearly normal rates for at least 30 min. This effect is either due to a very rapid degradation of stable RNA species or a reduced synthesis of RNA. Although the accumulation of all stable RNA species (23, 16 and 4 S RNAs) is reduced co-ordinately to levels ranging from 12 to 16% that of the control, the synthesis of messenger RNA is affected to a lesser degree, if at all. The defect in RNA accumulation can be partially reversed by the addition of chloramphenicol at the moment of temperature shift.In addition to phage λ these strains are unable to propagate RNA phage R17 and lambdoid phages φ80, 21 and 434 at elevated temperatures. The growth of phages T4, T7, P1 and P2 is normal.A genetic analysis of strain NS-1 indicates that all of its temperature sensitive properties depend on a mutation, designated groE-1, which co-transduces with a mel (melibiose) marker. However, the expression of the RNA synthesis defect requires, in addition, a second mutation which does not co-transduce with mel.     

Smooth specific phage adsorption: endorhamnosidase activity of tail parts of P22

The tail parts of phage P22 as well as the phage particles cleave the O-antigen of its host bacterium, $\text{Salmonella typhimurium}$. The cleavage is caused by specific breakage of α-rhamnosyl 1–3 galactose linkages. Thus the tail parts of this phage consist of an enzyme, endorhamnosidase. The enzyme was not detected in nonpermissible strain infected with an amber gene 9 mutant of P22. Head without tail parts gains infectivity only after incubation with the tail parts which carry this enzymatic activity.     

Cytotoxin-converting phages, φCTX and PS21, are R pyocin-related phages

Abstract φCTX is a temperate phage of Pseudomonas aeruginosa harbouring the ctx gene that encodes cytotoxin (CTX). We identified φCTX as an R pyocin-related phage, by serological and molecular analysis, based on the findings that the infectivity of the phage was inhibited with the antisera directed R pyocins and R pyocin-related phages and that the φCTX genome showed DNA homology to the genome of PS17 (a representative of the R pyocin-related phages) as well as to the pyocin R2 genes. Another new CTX-converting, R pyocin-related phage named PS21 was isolated from a CTX-producing strain of P. aeruginosa , suggesting the distribution of the ctx gene by certain members of R pyocin-related phage family.