Covert fi− R Factors in fi− R+ Strains of Bacteria

The presence of an fi(-) sex factor can be detected by propagation of the I-specific phage If1. By use of this method of detection, a high proportion of strains with fi(+) R factors were shown also to carry an fi(-) factor which was frequently a second R factor. In some doubly R(+) strains, the fi(+) and the fi(-) factor were observed to be transferred independently at conjugation.     

Non-Essentiality of the recA− Mutation in the Phenomenon of Bacteriophage M13-Induced Elimination of F′ Factors

The elimination of F' factors promoted by coliphage M13 infection can occur in recA(+) as well as recA(-) merodiploid strains of Escherichia coli K-12.     

Superinfection with R Factors by Transduction in Escherichia coli and Salmonella typhimurium

Superinfection immunity is found in the conjugal transfer of R factors between two fi(+) R factors and between two fi(-) R factors (fi = fertility inhibition), as we reported previously. In contrast, no reduction in the frequencies of transduction of an fi(+) R factor 222 was caused by the presence of fi(+) R factors in the recipients in transduction systems with phage P1kc in Escherichia coli K-12 and with phage P22 in Salmonella typhimurium LT-2. The absence of superinfection immunity in transduction may be due to the difference in the route of entry of the R factor. The frequencies of transduction of an fi(+) R factor were reduced, although slightly, by the presence of fi(-) R factors in the recipients. This reduction is probably due to host-controlled restriction of the entering fi(+) R factor by the fi(-) R factors in the recipients, since transduction of an fi(+) R factor by the transducing phage propagated on the strain carrying both fi(+) and fi(-) R factors was not reduced by the presence of homologous fi(-) R factors in the recipients. The fi(+) R factor 222, when transduced to the recipient strains carrying other R factors, recombined genetically at high frequencies with these resident R factors, regardless of their fi type.     

Comparisons of F Factors and R Factors: Existence of Independent Regulation Groups in F Factors

The similarity of sex pili mediated by F factors and R(fi(+)) factors and the ability of R(fi(+)) factors to control by repression the functioning of pilus genes encoded by the F factor suggested that F factors and R(fi(+)) factors are closely related. Further comparisons of the episomal properties of F factors and R(fi(+)) factors, however, indicated many differences. F factors contain information for a restriction system for phages phiII and T7. Cells containing R factors are sensitive to these phages. Furthermore, R(fi(+)) factors do not repress the F factor phiII restriction system in cells containing both an R(fi(+)) factor and an F factor. R factors and F factors are heteroimmune episomes. In addition, an R(fi(+)) factor in cells containing both an R factor and an F factor does not fully repress the expression of F-factor immunity to an incoming second F factor. R-factor and F-factor replication systems are not identical. Wild-type F-factor replication genes will complement the mutant F(ts114)lac(+) replication genes in cells containing two F factors. The F(ts114)lac(+) episome is retained when these cells are grown at 42 C; however, cells containing an R(fi(+)) factor and F(ts114)lac(+) lose the F(ts114)lac(+) when grown at 42 C, at the same rate as cells containing only the F(ts114)lac(+). The replication system of the R(fi(+)) factor will not complement the mutant F(ts114)lac(+) replication system.     

Increased Fragility of Escherichia coli After Infection with Bacteriophage M13

Male strains of Escherichia coli infected with filamentous phage M13 released the progeny phage particles from intact cells. At the same time, the cells continued to grow and multiply at a slightly lower rate than the uninfected cells. Concomitant with the phage release, lipopolysaccharide from the cell wall of the infected cells was also released. The buoyant density of E. coli HfrC in diaginol, 1.25 g/cc, did not change as a result of infection. Detergents like sodium dodecyl sulfate and Sarkosyl specifically lysed the infected cells. The infected cells showed enhanced fragility as indicated by inactivation by various stresses, namely heat, osmotic shock, and freezing and thawing. It is concluded that the infection with M13 causes certain alterations in the surface structure of E. coli, thus making the cells more fragile.     

Stability of the carrier state in bacteriophage M13-infected cells.

Bacteriophage M13-infected carrier cells were shown to be unstable to prolonged growth under all conditions. Carrier Hfr cells were transferred in dilute culture (10(3) to 10(4)/ml), where reinfection was impossible and the physiology of the cell was minimally altered. After an initial period of about 10 generations, during which all cells in the culture remained infected, there was exponential decay in the proportion of infected cells in the culture. Uninfected cells that appeared were M13 sensitive. Hfr and F' males were also transferred serially at high cell densities (10(7) to 10(9)/ml), where high levels of phage should permit reinfection. The proportion of phage-producing cells in the cultures remained constant for 7 to 15 generations and then dropped exponentially on further growth. Non-phage-producing cells appearing in the culture were refractory to infection by M13; in some cases cells scored as non-phage producers for 20 generations were observed to produce phage on further growth in liquid culture. F'trp+ males infected with M13 lost trp+ function almost immediately; this was not regained in these experiments. Infected cells grown in dilute culture or on plates remained infected longer, produced more PFU per cell for a longer period, and retained trp+ function in F'trp+ males for over 90 generations. Non-phage-producing cells that appeared were sometimes phage resistant, sometimes phage sensitive. The existence of a phage-related material accumulating at high cell densities and affecting expression of free episomes, episomal expression in Hfr males, and phage synthesis itself is suggested.     

Mucosal and peripheral Lin- HLA-DR+ CD11c/123- CD13+ CD14- mononuclear cells are preferentially infected during acute simian immunodeficiency virus infection

Massive infection of memory CD4 T cells is a hallmark of early simian immunodeficiency virus (SIV) infection, with viral infection peaking at day 10 postinfection (p.i.), when a majority of memory CD4 T cells in mucosal and peripheral tissues are infected. It is not clear if mononuclear cells from the monocyte and macrophage lineages are similarly infected during this early phase of explosive HIV and SIV infections. Here we show that, at day 10 p.i., Lin(-) HLA-DR(+) CD11c/123(-) CD13(+) CD14(-) macrophages in the jejunal mucosa were infected, albeit at lower levels than CD4 memory T cells. Interestingly, Lin(-) HLA-DR(+) CD11c/123(-) CD13(+) CD14(-) macrophages in peripheral blood, like their mucosal counterparts, were preferentially infected compared to Lin(-) HLA-DR(+) CD11c/123(-) CD13(+) CD14(+) monocytes, suggesting that differentiated macrophages were selectively infected by SIV. CD13(+) CD14(-) macrophages expressed low levels of CD4 compared to CD4 T cells but expressed similar levels of CCR5 as lymphocytes. Interestingly, CD13(+) CD14(-) macrophages expressed Apobec3G at lower levels than CD13(+) CD14(+) monocytes, suggesting that intracellular restriction may contribute to the differential infection of mononuclear subsets. Taken together, our results suggest that CD13(+) CD14(-) macrophages in mucosal and peripheral tissues are preferentially infected very early during the course of SIV infection.     

Recombination Between a Thermosensitive Kanamycin Resistance Factor and a Nonthermosensitive Multiple-Drug Resistance Factor

The thermosensitive kanamycin (KM) resistance factor, R(KM)(t), and a nonthermosensitive multiple-drug resistance factor, R(100), were simultaneously introduced into Escherichia coli and Salmonella typhimurium. The temperature sensitivity of both R factors remained unchanged as long as they replicated independently. Under certain conditions, however, a new thermosensitive R factor harboring resistance markers for kanamycin, streptomycin (SM), and sulfanilamide (SA) was obtained by recombination between the R(KM)(t) and R(100) factors. R factors carrying resistance markers for KM and SA, or for SM and SA, were obtained from the recombinant R(KM SA SM)(t) by spontaneous segregation. Though the R(100) factor has been known as an fi(+) (positive for F-mediated fertility inhibition of its host) type and it does not restrict any coexisting phages, the thermosensitive recombinants of R(100) with R(KM)(t) and their segregants were found to be fi(-) and to restrict the replication of all T-even phages, as does the R(KM)(t) factor. Double infection immunity was not observed between the R(KM)(t) and R(100) factors.     

Episome-mediated Transfer of Drug Resistance in Enterobacteriaceae X. Restriction and Modification of Phages by fi R Factors

Watanabe, Tsutomu (Keio University, Tokyo, Japan), Toshiya Takano, Toshihiko Arai, Hiroshi Nishida, and Sachiko Sato. Episome-mediated transfer of drug resistance in Enterobacteriaceae. X. Restriction and modification of phages by fi(-) R factors. J. Bacteriol. 92:477-486. 1966.-An fi(-) R factor, which restricts phages lambda, T1, and T7 without modifying them, was found to restrict and not to modify an F(-)-specific phage, W-31, in Escherichia coli K-12, but not to restrict phage P-22 in Salmonella typhimurium LT-2, whereas other fi(-) R factors restricted and modified P-22 but not W-31; fi(+) R factors did not restrict these phages. Transduction and lysogenization with phages lambda and P-22 were reduced by these fi(-) R factors in K-12 and LT-2, respectively, and the transducing phages lambda and P-22 were modified by these fi(-) R factors. Spontaneous as well as ultraviolet-induced production of phage P-22 and zygotic induction of phage lambda were not significantly affected by any R factor. Injection of the nucleic acids of phages T1 and lambda was not affected by R factors, but the injected phage nucleic acids were rapidly broken down in the bacteria carrying fi(-) R factors. The nucleic acids of the modified phages were not broken down in these bacteria. It was assumed from these results that the mechanism of restriction of phages by fi(-) R factors is due to the breakdown of the injected phage nucleic acids by a deoxyribonuclease(s), presumably located near the cell surface in the cells carrying fi(-) R factors. The deoxyribonuclease(s), formed in the cells carrying the nonmodifying fi(-) R factor, is considered to be different from that synthesized in the cells carrying the modifying fi(-) R factors. It was further shown that the average burst sizes of the unmodified as well as modified phages are slightly reduced by the presence of the fi(-) R factors.     

Genetic Stability of Various Resistance Factors in Escherichia coli and Salmonella typhimurium

Genetic stability of R factors was studied in Salmonella typhimurium LT-2 and Escherichia coli K-12. It was found that fi(+) R [or R(f)] factors were unstable in LT-2, losing their drug-resistance markers at high frequencies, and were stable in K-12; fi(-) R [or R(i)] factors were stable in both hosts. Both fi(+) and fi(-) R factors were genetically stable also in recombination-deficient mutants of K-12. An fi(+) R factor, which was unstable in S. typhimurium LT-2 wild type, was relatively stable in a recombination-deficient mutant of LT-2. In the spontaneous loss of the drug-resistance markers of fi(+) R factors in LT-2, the markers for sulfanilamide, streptomycin, and chloramphenicol resistance were lost together at high frequencies and the tetracycline marker was retained stably. The remaining drug-resistance markers of the spontaneous segregants of LT-2 were transmissible to K-12 by mixed cultivation, indicating that they were still in the form of R factors.     

Episome-mediated transfer of drug resistance in Enterobacteriaceae. IX. Recombination of an R factor with F

Watanabe, Tsutomu (Keio University, Tokyo, Japan), and Chizuko Ogata. Episome-mediated transfer of drug resistance in Enterobacteriaceae. IX. Recombination of an R factor with F. J. Bacteriol. 91:43-50. 1966.-R factors can be transduced in Salmonella typhimurium with phage P-22, and a majority of the drug-resistant transductants are unable to transfer their drug resistance by cell-to-cell contact, as we have previously reported. Several exceptional types of transductants of S. typhimurium, with the markers of resistance to sulfonamide, streptomycin, and chloramphenicol, were recently obtained by transduction with phage P-22 of a four-drug-resistance R factor carrying the markers of resistance to sulfonamide, streptomycin, chloramphenicol, and tetracycline. They were exceptional in that they had low conjugal transferability of their drug resistance. When one of these exceptional transductants (38R) was transferred to an F(+) strain of Escherichia coli K-12, 38R acquired high transferability in its further transfer. This high transferability was found to be due to the recombination of 38R with F. Transductant 38R was of the fi(+) (fi = fertility inhibition) type, and did not show superinfection immunity against fi(+) and fi(-) R factors. The recombinant 38R.F was genetically very stable and resistant to elimination with acridines. It did not show superinfection immunity against fi(+) and fi(-) R factors, but did show superinfection immunity against F. Further, 38R.F did not restrict a female-specific phage (W-31), unlike wild-type F. F(-) and R(-) segregants were isolated from this recombinant 38R.F, and these segregants exhibited genetic characteristics different from the original R, its transductant 38R, and wild-type F.     

Myxoma virus M141R expresses a viral CD200 (vOX-2) that is responsible for down-regulation of macrophage and T-cell activation in vivo

M141R is a myxoma virus gene that encodes a cell surface protein with significant amino acid similarity to the family of cellular CD200 (OX-2) proteins implicated in the regulation of myeloid lineage cell activation. The creation of an M141R deletion mutant myxoma virus strain (vMyx141KO) and its subsequent infection of European rabbits demonstrated that M141R is required for the full development of a lethal infection in vivo but is not required for efficient virus replication in susceptible cell lines in vitro. Minor secondary sites of infection were detected in the majority of rabbits infected with the M141R deletion mutant, demonstrating that the M141R protein is not required for the dissemination of virus within the host. When compared to wild-type myxoma virus-infected rabbits, vMyx141KO-infected rabbits showed higher activation levels of both monocytes/macrophages and lymphocytes in situ through assessments of inducible nitric oxide synthase-positive and CD25(+) infiltrating cells in infected and lymphoid tissues. Purified peripheral blood mononuclear cells from vMyx141KO-infected rabbits demonstrated an increased ability to express gamma interferon upon activation by phorbol myristate acetate plus ionomycin compared to cells purified from wild-type myxoma virus-infected rabbits. We concluded that the M141R protein is a bona fide CD200-like immunomodulator protein which is required for the full pathogenesis of myxoma virus in the European rabbit and that its loss from the virus results in increased activation levels of macrophages in infected lesions and draining lymph nodes as well as an increased activation level of circulating T lymphocytes during infection. We propose a model whereby M141R transmits inhibitory signals to tissue macrophages, and possibly resident CD200R(+) dendritic cells, that reduce their ability to antigenically prime lymphocytes and possibly provides anergic signals to T cells directly.     

Mechanisms of antibiotic resistance determined by resistance-transfer factors

Unowsky, Joel (Northwestern University Medical School, Chicago, Ill.), and Martin Rachmeler. Mechanisms of antibiotic resistance determined by resistance-transfer factors. J. Bacteriol. 92:358-365. 1966.-This study was concerned with the mechanism of expression of drug resistance carried by resistance-transfer (R) factors of two types: fi(-) (negative fertility inhibition) and fi(+) (positive fertility inhibition). The levels of drug resistance determined by R factors used in this study were similar to those reported by other investigators. A new finding was that Escherichia coli carrying the fi(-) episome was resistant to 150 to 200 mug/ml of streptomycin. The growth kinetics of R factor-containing cells were similar in the presence or absence of streptomycin, chloramphenicol, and tetracycline, but a period of adaptation was necessary before cells began exponential growth in the presence of tetracycline. By use of radioactive antibiotics, it was shown that cells containing the fi(-) episome were impermeable to tetracycline and streptomycin, whereas cells containing the fi(+) episome were impermeable only to chloramphenicol. Cell-free extracts from fi(+) and fi(-) cells were sensitive to the antibiotics tested in the polyuridylic acid-stimulated incorporation of phenylalanine into protein.     

Effect of Bacillus subtilis BsuM restriction-modification on plasmid transfer by polyethylene glycol-induced protoplast fusion

Polyethylene glycol (PEG)-induced cell fusion is a promising method to transfer larger DNA from one cell to another than conventional genetic DNA transfer systems. The laboratory strain Bacillus subtilis 168 contains a restriction (R) and modification (M) system, BsuM, which recognizes the sequence 5'-CTCGAG-3'. To study whether the BsuM system affects DNA transfer by the PEG-induced cell fusion between R(+)M(+) and R(-)M(-) strains, we examined transfer of plasmids pHV33 and pLS32neo carrying no and eight BsuM sites, respectively. It was shown that although the transfer of pLS32neo but not pHV33 from the R(-)M(-) to R(+)M(+) cells was severely restricted, significant levels of transfer of both plasmids from the R(+)M(+) to R(-)M(-) cells were observed. The latter result shows that the chromosomal DNA in the R(-)M(-) cell used as the recipient partially survived restriction from the donor R(+)M(+) cell, indicating that the BsuM R(-)M(-) strain is useful as a host for accepting DNA from cells carrying a restriction system(s). Two such examples were manifested for plasmid transfer from Bacillus circulans and Bacillus stearothermophilus strains to a BsuM-deficient mutant, B. subtilis RM125.     

BALB/c mice deficient in CD4 T cell IL-4Rα expression control Leishmania mexicana Load although female but not male mice develop a healer phenotype

Immunologically intact BALB/c mice infected with Leishmania mexicana develop non-healing progressively growing lesions associated with a biased Th2 response while similarly infected IL-4Rα-deficient mice fail to develop lesions and develop a robust Th1 response. In order to determine the functional target(s) for IL-4/IL-13 inducing non-healing disease, the course of L. mexicana infection was monitored in mice lacking IL-4Rα expression in specific cellular compartments. A deficiency of IL-4Rα expression on macrophages/neutrophils (in LysM(cre)IL-4Rα(-/lox) animals) had minimal effect on the outcome of L. mexicana infection compared with control (IL-4Rα(-/flox)) mice. In contrast, CD4(+) T cell specific (Lck(cre)IL-4Rα(-/lox)) IL-4Rα(-/-) mice infected with L. mexicana developed small lesions, which subsequently healed in female mice, but persisted in adult male mice. While a strong Th1 response was manifest in both male and female CD4(+) T cell specific IL-4Rα(-/-) mice infected with L. mexicana, induction of IL-4 was manifest in males but not females, independently of CD4(+) T cell IL-4 responsiveness. Similar results were obtained using pan-T cell specific (iLck(cre)IL-4Rα(-/lox)) IL-4Rα(-/-) mice. Collectively these data demonstrate that upon infection with L. mexicana, initial lesion growth in BALB/c mice is dependent on non-T cell population(s) responsive to IL-4/IL-13 while progressive infection is dependent on CD4(+) T cells responsive to IL-4.     

Infection of rat brain cell aggregates with neurovirulent and nonneurovirulent strains of herpes simplex virus type 1

Rat brain cell aggregates represent a three-dimensional tissue culture system of brain tissue in the form of small, multicellular spheroids. In the present work, we have infected these "minibrains" with neurovirulent, nonneurovirulent, and nonreplicating strains of HSV-1. The neurovirulent strains 17(+) and KOS(M) spread rapidly through the aggregates, while the nonreplicating ICP4 deletion mutant KD6 infected cells only at the periphery of the aggregates. Spread and replication of the nonneurovirulent strains RE6 and tk-7, and to some extent also of R13/1, were restricted. The interaction between different strains of HSV-1 and the rat brain cell aggregates is thus comparable to that seen in the brain, suggesting that the aggregates represent a useful tool for studying HSV-1 infection of brain tissue in vitro.     

Replication of bacteriophage M13 IX. Requirement of the Escherichia coli dnaG function for M13 duplex DNA replication.

Temperature-shift experiments with an Escherichia coli dnaG strain indicate a requirement for the dnaG function for M13 phage production only at an early stage of infection. Mutant cells infected at nonpermissive temperature form the parental RF (SS leads to RF) but do not replicate further. A shift to nonpermissive temperature after infection inhibits RF leads to RF replication but not RF leads to SS synthesis. The synthesis of both strands of the duplex RF was inhibited equally after a temperature shift during RF leads to RF replication. We infer that the dnaG protein is required for M13 production only during RF replication and that it is required for the synthesis of both strands of the RF.     

Loss of Colicinogeny in Escherichia coli Strains Infected by Certain Resistance Factors

The original observation that in wild-type colicinogenic Escherichia coli strains the introduction of some R factors abolish their colicin production was studied in certain col(+) strains bearing well-defined col factors. Two resistance (R) factors were used and introduced by conjugation in these strains, namely the 222 factor of Watanabe and a Salmonella typhimurium ST factor (coding for resistance to streptomycin and tetracycline only). The introduction of above mentioned R factors abolished the colicin production of col(+) strains most probably by elimination of col factors. All col factors, however, were not equally susceptible to elimination by the R factors tested, since colicin production in ML strains was abolished by infection by the 222 factor but not by the R factor of S. typhimurium ST, which is able to eliminate other col factors.     

Factors Influencing the Establishment of Persistent Infection of HVJ (Sendai Virus) in L Cells

Infection of a subline of L cells adapted to grow in suspension (Ls) with Fushimi strain of HVJ (HVJ-F) resulted in a virus carrier state. Ls cells, when cultured in monolayer, showed morphological changes following infection of HVJ-F and were detached from the glass wall. However, when the detached cells were transferred to a new environment of suspension culture within 5 days after infection, the carrier state was again established. HVJ-F caused only lethal infection in L cells maintained exclusively in monolayer (Lm). On the other hand, both Ls and Lm, irrespective of their culture conditions, were lethally infected by Nagoya 1–60 strain of HVJ. The overall results showed that culture condition as well as the kind of host cells or virus strains is an important factor regulating the establishment and maintenance of the virus carrier state.     

Curing Action of Sodium Dodecyl Sulfate on a Proteus mirabilis R+ Strain

Growth of Proteus mirabilis harboring R100-1 (fi(+)drd str(r)cml(r)tet(r)sul(r)) factors in Penassay broth containing sodium dodecyl sulfate (SDS) leads to the loss of all or part of the genetic elements in high frequencies. In media containing SDS at concentrations as low as 0.03%, both lysis of R(+) cells and elimination of the R factors occur at high frequencies. Appearance of drug-susceptible cells in R(+) cultures occurs during the exponential phase of growth; however, the frequencies of susceptible cells increase substantially after the culture reaches the stationary phase. Reconstruction experiments, coupled with other observations, suggest that the major factor in altering the frequency of drug-susceptible variants is the greater resistance of the variants to the lytic action of SDS. This resistance correlates in most cases with the loss of the transfer functions in the resistance transfer factor.