Is abortive infection by bacteriophage BF23 of Escherichia coli harboring ColIb plasmids due to cell killing by internally liberated colicin Ib?

Infection of Escherichia coli harboring ColIb+ plasmids with bacteriophage BF23+ is abortive and resulted in changes of membrane permeability as measured by efflux of nucleotides and K+. A single pre-early gene product of BF23+ was necessary and sufficient to elicit the abortive response. Appropriate mutations in this pre-early gene allowed a productive infection in ColIb+ cells. Appropriate mutations in the ColIb plasmid also allowed a productive infection with BF23+. A comparison of changes occurring during abortive infection and during killing of sensitive cells by external colicin Ib or Ia, together with certain genetic data, has led to the conclusion that membrane changes accompanying the two phenomena are the result of a common mechanism, namely, the interaction of free colicin with the cytoplasmic membrane.     

Genes 1.2 and 10 of bacteriophages T3 and T7 determine the permeability lesions observed in infected cells of Escherichia coli expressing the F plasmid gene pifA.

Infections of F plasmid-containing strains of Escherichia coli by bacteriophage T7 result in membrane damage that allows nucleotides to exude from the infected cell into the culture medium. Only pifA of the F pif operon is necessary for "leakiness" of the T7-infected cell. Expression of either T7 gene 1.2 or gene 10 is sufficient to cause leakiness, since infections by phage containing null mutations in both of these genes do not result in permeability changes of the F-containing cell. Even in the absence of phage infection, expression from plasmids of either gene 1.2 or 10 can cause permeability changes, particularly of F plasmid-containing cells. In contrast, gene 1.2 of the related bacteriophage T3 prevents leakiness of the infected cell. In the absence of T3 gene 1.2 function, expression of gene 10 causes membrane damage that allows nucleotides to leak from the cell. Genes 1.2 and 10 of both T3 and T7 are the two genes involved in determining resistance or sensitivity to F exclusion; F exclusion and leakiness of the phage-infected cell are therefore closely related phenomena. However, since leakiness of the infected cell does not necessarily result in phage exclusion, it cannot be used as a predictor of an abortive infection.     

Early Abortive Lysis by Phage BF23 in Escherichia coli K-12 Carrying the Colicin Ib Factor

Growth of phage BF23 was restricted in Escherichia coli K-12 strains carrying a colicin I factor (ColIb); most infected cells lysed early without producing progeny phages. Either addition of chloramphenicol before phage infection or ultraviolet irradiation of phage prevented early abortive lysis, an indication that certain phage functions are required for this phenomenon. Very little or no phage-induced lysozyme was synthesized in the infected ColI(+) cells. This result suggests that early abortive lysis was not due to the lysozyme action. A small fraction (0.05) of BF23-infected ColI(+) cells showed normal phage growth. This "escaped growth" may reflect the physiological state of the host bacteria rather than the heterogeneity of the infecting phage. Host-controlled modification was not observed. A phage mutant, BF23hI, able to grow on ColI(+) cells, was isolated and was characterized to be recessive to the wild-type BF23 in its ability to undergo early abortive lysis. Among the T series phages, T5 induced early abortive lysis, and growth of T5 was restricted upon infection to ColI(+) cells. These results and the other observations, including the occurrence of phenotypic mixing between BF23 and T5, suggest that these two phages are related to each other even though the receptor sites for BF23 and T5 are apparently different.     

Amino acid and sugar transport in Escherichia coli (ColIb) during abortive infection by bacteriophage T5.

T5 bacteriophage cannot replicate in Escherichia coli containing the colicinogenic factor ColIb. We show that active transport of proline and glutamine begins to decline at about 10 min after infection, the same time at which macromolecular synthesis stops during abortive infection. Uptake of alpha-methylglucoside is stimulated, however, and this change is evident even by 5 min after infection. These changes in membrane function do not occur during infections that are productive because of mutations on the plasmid or phage. The results suggest that the abortive infection is caused by membrane depolarization.     

Polyoma T (tumor) antigen species in abortively and stably transformed cells

Stable neoplastic transformation of cells by polyoma virus requires the participation of two viral genes, designated ts-a and hr-t. The effects of mutations in these two genes on the patterns of T-antigen synthesis during productive infection have been previously described: ts- a mutants are affected in the “large” (100K) nuclear T antigen, and hr-t mutants are affected in the “middle” (36K, 56K, 63K) and “small” (22K) T agtigens. The latter are associated predominantly with the plasma membrane (56K) and cytosol fractions, rrespectively. Here we examine the expression of the various forms of polyoma T antigen in nonproductive infection (abortive transformation) as well as in stably transformed cell lines of different species. The results on abortive transformation are essentially the same as those described above for productive infection. In stably transformed cells, the middle and small T antigens are seen to various extents. The large T antigen, however, is often absent or present below the level of detection. Clones lacking the large T antigen are found most often among mouse transformants, but are also seen among rat transformants. Retention of the 100K species in transformed cells therefore appears to be, at least in part, an inverse function of the level of permissivity of the host toward productive viral infection. These findings indicate that the induction of the transformed phenotype in both abortively and stably transformed cells generally does not require the large T antigen, but rather the products of the hr-t gene.     

Expression of gene 1.2 and gene 10 of bacteriophage T7 is lethal to F plasmid-containing Escherichia coli.

Plasmids expressing bacteriophage T7 gene 1.2 or gene 10 DNA transform F plasmid-containing strains of Escherichia coli only at low efficiency, though they transform plasmid-free strains normally. The gene products T7 gp1.2 and T7 gp10 appear to be the toxic agents, and their effects are directed towards the product of the F pifA gene, PifA. T7 gp1.2 and gp10 are also the two targets of the pif exclusion system of F, and their synthesis normally triggers the abortive infection of T7 in pifA+ hosts. The properties of plasmids containing T7 gene 1.2 or 10 suggest that they can be used to study the molecular mechanisms of phage exclusion in model systems that avoid the pleiotropic dysfunctions associated with an abortive infection.     

Synthesis of the capsid protein inhibits development of bacteriophage T3 mutants that abortively infect F plasmid-containing cells

Mutants of bacteriophage T3 that lack gene 1.2 resemble wild-type phage T7 in that they are unable productively to infect F plasmid-containing cells of Escherichia coli. Pseudorevertants of a T3 gene 1.2 deletion mutant that have regained the ability to plate efficiently on male cells have been isolated and characterized. At least two mutations in the gene for the major capsid protein are necessary for these phages to bypass F-mediated restriction. One mutation serves to reduce the rate of synthesis of the capsid protein; a second mutation apparently alters an unknown property that is intrinsic to the free, or unassembled form of the protein. During the abortive infection of an F-containing host, synthesis of the wild-type capsid protein directly inhibits further phage development.     

Phage operon involved in sensitivity to the Lactococcus lactis abortive infection mechanism AbiD1.

Phage bIL66 is unable to grow on Lactococcus lactis cells harboring the abortive infection gene abiD1. Spontaneous phage mutants able to grow on AbiD1 cells were used to study phage-Abi interaction. A 1.33-kb DNA segment of a mutant phage allowed growth of AbiD1s phages in AbiD1 cells when present in trans. Sequence analysis of this segment revealed an operon composed of four open reading frames, designated orf1 to orf4. The operon is transcribed 10 min after infection from a promoter presenting an extended -10 consensus sequence but no -35 sequence. Analysis of four independent AbiD1r mutants revealed a different point mutation localized in orf1, implying that this open reading frame is needed for sensitivity to AbiD1. However, the sensitivity is partly suppressed when orf3 is expressed in trans on a high-copy-number plasmid, suggesting that AbiD1 acts by decreasing the concentration of an available orf3 product.     

Characterization of multi-layered membrane generated by rabies virus

Electron microscopy revealed multi-layered membranes within the cytoplasmic inclusion (accumulation of nucleocapsids) produced by rabies virus. When infected BHK cells were maintained at 31 C, an enhancement in production of these membranes occurred in approximately 60% of inclusion-containing cells. Multi-layered membranes were composed of an alternate array of two different layers; an electron-dense, thin membrane and a less dense layer which was thicker. SDS-polyacrylamide gel electrophoresis and immune electron microscopy of isolated multi-layered membrane preparations demonstrated that the structures contained viral G and M2 polypeptides. Our observations suggest that these membranous structures are not a degenerative product of rabies virus infection but rather are related to the replication of viral envelope constituents, although they represent themselves to be an abortive form of viral assembly.     

Factors Influencing the Production of Intermediate Particles During Alkaline Degradation of Tobacco Mosaic Virus: Time, pH, Salt Concentration, and Temperature

When T5 bacteriophage infect a colicin Ib-containing host, a variety of membrane changes and inhibition of macromolecular synthesis occur. This work shows that all these changes also occur when a mutant of T5 that can only inject 8% of its DNA is used. This indicates that all the information necessary for the abortive infection is present on this 8% (first-step-transfer) DNA.     

Ion fluxes during T5 bacteriophage infection of Escherichia coli

When T5 bacteriophage infects Escherichia coli B, ⁴²K⁺ is immediately released from cells that have been preloaded with this ion. The rate of ion release and the total amount released are dependent on the multiplicity of infection and are not diminished by the use of mutants which can only inject 8% of their DNA. Normally, the ion release stops at about 6 min postinfection. If the host cells contain the colicinogenic factor, Col Ib, so that the infection is abortive, K⁺ release continues. Evidence is presented to show that this continued ion release cannot be explained by a “damage and repair” hypothesis. The results are, however, consistent with the interpretation of membrane depolarization due to ion pore formation as the cause of the abortive infection.     

Human cytomegalovirus gene expression is silenced by Daxx-mediated intrinsic immune defense in model latent infections established in vitro

In addition to productive lytic infections, herpesviruses such as human cytomegalovirus (HCMV) establish a reservoir of latently infected cells that permit lifelong colonization of the host. When latency is established, the viral immediate-early (IE) genes that initiate the lytic replication cycle are not expressed. HCMV IE gene expression at the start of a lytic infection is facilitated by the viral pp71 protein, which is delivered to cells by infectious viral particles. pp71 neutralizes the Daxx-mediated cellular intrinsic immune defense that silences IE gene expression by generating a repressive chromatin structure on the viral major IE promoter (MIEP). In naturally latently infected cells and in cells latently infected in vitro, the MIEP also adopts a similar silenced chromatin structure. Here we analyze the role of Daxx in quiescent HCMV infections in vitro that mimic some, but not all, of the characteristics of natural latency. We show that in these "latent-like" infections, the Daxx-mediated defense that represses viral gene expression is not disabled because pp71 and Daxx localize to different cellular compartments. We demonstrate that Daxx is required to establish quiescent HCMV infections in vitro because in cells that would normally foster the establishment of these latent-like infections, the loss of Daxx causes the lytic replication cycle to be initiated. Importantly, the lytic cycle is inefficiently completed, which results in an abortive infection. Our work demonstrates that, in certain cell types, HCMV must silence its own gene expression to establish quiescence and prevent abortive infection and that the virus usurps a Daxx-mediated cellular intrinsic immune defense mechanism to do so. This identifies Daxx as one of the likely multiple viral and cellular determinants in the pathway of HCMV quiescence in vitro, and perhaps in natural latent infections as well.     

Synthesis of the tobacco mosaic virus in blocked spreading of infection

The possibility of infection of tobacco upper leaves with tobacco mosaic virus (TMV) was examined in experiments where the inoculum was imbibed through the cut stem. The inoculum used were: a) a preparation of a virus-specific informosome-like ribonucleoproteins (vRNP) isolated from TMV-infected plants; b) a TMV preparation; or c) a mixture of TMV and vRNP. Multiplication of TMV in upper leaves was observed in neither of the variants; nevertheless in the vascular tissue and/or probably in adjoining parenchymal cells, two kinds of RNA were synthesized: of mol. w. (1.1--1.3) X 10(6) and (0.6--0.8) X 10(6). These RNA were not found in healthy plants in the presence of actinomycin D. The synthesis of genomic TMV RNA is suppressed under these conditions. Thus, some kind of abortive TMV infection takes place under the condition of experimental inoculation of plants through a cut stem. Molecular hybridization with the DNA of recombinant plasmid containing a nucleotide sequence complementary to the 3'-portion of genomic TMV RNA proves that short RNAs synthesized under the abortive infection conditions are TMV-specific. The experiments with differential temperature treatment of N-gene-containing plants under abortive infection conditions suggest that necrotization is not necessarily induced by genomic TMV RNA synthesis.     

Molecular analysis of the UV protection and mutation genes carried by the I incompatibility group plasmid TP110.

The abortive infection of bacteriophage T7 in Shigella sonnei D2 371-48 is characterized by a premature inhibition of phage DNA replication and nucleolytic breakdown of all phage DNA. Mutations in T7 gene 10 which are recessive to the presence of the wild-type allele can alleviate the restriction of phage growth. Phage T3 productively infects S. sonnei D2 371-48, as does a T7-T3 hybrid phage that contains, in particular, a gene 10 of T7 origin. It is the presence of T3 DNA ligase that allows phage growth on S. sonnei D2 371-48, and this enzyme can also rescue wild-type T7 from the abortive infection. T7+ is therefore functionally ligase deficient during the infection of S. sonnei D2 371-48; this deficiency is a result of the expression of the phage capsid protein, but it is independent of the assembly of the protein into a procapsid or other morphogenetic structure.