Bacteriophage T4 multiplication in a glucose-limited Escherichia coli biofilm.

An Escherichia coli K-12 biofilm was grown at a dilution rate of 0.028 h(-1) for 48 h in a glucose-limited chemostat coupled to a modified Robbins' device to determine its susceptibility to infection by bacteriophage T4. Bacteriophage T4 at a multiplicity of infection (MOI) of 10 caused a log reduction in biofilm density (expressed as colony forming units (CFU) per cm2) at 90 min postinfection. After 6 h, a net decrease and equilibrium in viral titer was seen. When biofilms were exposed to T4 phage at a MOI of 100, viral titer doubled after 90 min. After 6 h, viral titers (expressed as plaque forming units (PFU) per cm2) stabilized at levels approximately one order of magnitude higher than seen at a MOI of 10. Scanning confocal laser microscopy images also indicated disruption of biofilm morphology following T4 infection with the effects being more pronounced at a MOI of 100 than at a MOI of 10. These results imply that biofilms under carbon limitation can act as natural reservoirs for bacteriophage and that bacteriophage can have some influence on biofilm morphology.

Phenotype characterization of genetically defined microorganisms and growth of bacteriophage in biofilms.

Phenotypic characterization will be a pivotal aspect of future research in understanding the biofilm mode of growth. We hope that the concepts and techniques presented in this chapter will benefit other investigators in this field. Although initial studies will necessarily involve monocultures, eventually mixed culture work will have to be performed to understand biofilm growth in the natural environment. As the study of biofilm-phage interactions is new, there is considerable fundamental work that needs to be addressed. Here, we anticipate that some phage are better adapted to growth in biofilms, some are adept in growing in mixed culture biofilms, and others are better adapted to infecting planktonic organisms. Whereas biofilms are now widely accepted as a fundamental aspect of microbial growth in nature, the field of phage ecology is quite new and an exciting challenge for the future.

Poliovirus-mediated entry of pokeweed antiviral protein.

Infection of HeLa cells with poliovirus results in cell permeabilization to pokeweed antiviral protein. Cell permeabilization was dependent on the integrity of virus capsid proteins and directly proportional to the multiplicity of infection. This study demonstrates that virus adsorption is sufficient for the entry of pokeweed antiviral protein into poliovirus-infected cells.

Cytotoxicity of pokeweed antiviral protein.

Pokeweed antiviral protein, a plant protein which inactivates eukaryotic ribosomes, was found to be cytotoxic to both HeLa and Vero cells. Cellular protein synthesis was inhibited by exposure of the cells to microM concentrations of the antiviral protein for 24 h periods or longer. The extent of the inhibition of cellular protein synthesis was dependent upon the time of exposure to pokeweed antiviral protein and was partially reversed by washing the cells at various times prior to the measurement of protein synthesis. The antiviral protein was also observed to bind nonspecifically to cells at both 4 degrees and 34 degrees C. The data indicate that the pokeweed antiviral protein is capable of slowly entering mammalian cells which results in the inhibition cellular protein synthesis.

Inhibition of herpes simplex virus DNA synthesis by pokeweed antiviral protein.

Pokeweed antiviral protein at a concentration of 3 microM inhibited both the synthesis and release of infectious herpes simplex virus type 1 in cell culture by 90 and 99%, respectively. Addition of pokeweed antiviral protein to Vero cell monolayers before virus infection was 10 to 15% more effective in reducing virus yields than was the simultaneous addition of the antiviral protein with virus inoculum. Viral DNA synthesis was inhibited by 90% in cells which had been exposed to the antiviral protein, whereas cellular DNA synthesis was unaffected. No significant inhibition in the synthesis of the majority of viral infected-cell polypeptides was observed early postinfection (7 h), with the exception of infected cell polypeptides 4 and 41, whose syntheses were reduced by 38 and 25%, respectively. At 9 to 21 h postinfection, however, the synthesis of individual infected cell polypeptides was reduced by 48 to greater than 99%.

Chemical modifications of pokeweed antiviral protein: effects upon ribosome inactivation, antiviral activity and cytotoxicity.

Pokeweed antiviral protein (PAP) is a protein known to inactivate eukaryotic ribosomes by an unknown enzymatic action and inhibit the production of mammalian viruses in tissue culture. This protein was subjected to a variety of chemical modifications to determine their effects upon ribosomal inactivation, antiviral action, and cytotoxicity. It was found that modifications of a number of different amino acid residues had similar effects upon all 3 activities. Also the inactivation of PAP with diethylpyrocarbonate was not due to its reaction with a histidine residue but to a modification of an unidentified amino acid residue.

Purification and partial characterization of another form of the antiviral protein from the seeds of Phytolacca americana L. (pokeweed).

1. The pokeweed antiviral protein, previously identified in two forms (PAP and PAP II) in the leaves of Phytolacca americana (pokeweed) [Obrig. Irvin & Hardesty (1973) Arch. Biochem. Biophys. 155, 278-289; Irvin, Kelly & Robertus (1980) Arch. Biochem. Biophys. 200, 418-425] is a protein that prevents replication of several viruses and inactivates ribosomes, thus inhibiting protein synthesis. 2. PAP is present in several forms in the seeds of pokeweed. One of them, which we propose to call 'pokeweed antiviral protein from seeds' (PAP-S) was purified in high yield (180 mg per 100 g of seeds) by chromatography on CM-cellulose, has mol.wt. 30 000, and is similar to, but not identical with. PAP and PAP II. 3. PAP-S inhibits protein synthesis in a rabbit reticulocyte lysate with an ID50 (concentration giving 50% inhibition) of 1.1 ng/ml (3.6 x 10(-11) M), but has much less effect on protein synthesis by whole cells, with an ID50 of 1 mg/ml (3.3 x 10(-5) M), and inhibits replication of herpes simplex virus type 1.

Inhibition of herpes simplex virus multiplication by the pokeweed antiviral protein.

The pokeweed antiviral protein inhibited the multiplication of herpes simplex virus type 1 in cell culture. The extent of antiviral activity was proportional to the length of time that the antiviral protein was present postinfection. The results demonstrate that the continued presence of the pokeweed antiviral protein is necessary for the maximum inhibition of virus yields.

Temperature-sensitive mutants of bacteriophage SH-133 specific for the hydrogen bacterium Pseudomonas facilis: isolation, complementation, and partial characterization.

Seventeen temperature-sensitive mutants of bacteriophage SH-133 have been isolated following mutagenesis with UV-light, nitrosoguanidine, and ethyl methanesulfonate. The mutants were classified into 15 complementation groups according to their ability to complement each other at 32 degrees C, the nonpermissive temperature. Each mutant was studied with regard to the relationship between its ability to multiply in heterotrophically (H-) and autotrophically (A-) grown Pseudomonas facilis cells. At 27 degrees C, the permissive temperature, the plaque-forming ability of the 17 mutants and wild-type phage was reduced 10-fold in A-grown cells. At 32 degrees C, mutants belonging to 10 groups exhibited identical levels of multiplicity-dependent leak under both modes of growth. However, the infection of A-grown cells by mutants belonging to the remaining five groups resulted in as much as 500-fold inhibition of multiplicity-dependent leak when contrasted with the infection of cells grown heterotrophically. These observations indicate that the expression of five SH-133 phage cistrons is defective when multiplication proceeds under autotrophic metabolism. Seven mutants were found to differ from the wild-type phage with regard to thermal stability at 56 degrees C which suggests that they possess altered structural proteins. Four of the seven thermosensitive mutants exhibited reduced levels of multiplicity-dependent leak in A-grown cells. The data suggest that the reduction in plaque-forming ability of SH-133 in A-grown cells is caused by a defect in the expression of specific phage structural components.

DNA synthesis and DNA polymerase activity of herpes simplex virus type 1 temperature-sensitive mutants.

Fifteen temperature-sensitive mutants of herpes simplex virus type 1 were studied with regard to the relationship between their ability to synthesize viral DNA and to induce viral DNA polymerase (DP) activity at permissive (34 C) and nonpermissive (39 C) temperatures. At 34 C, all mutants synthesized viral DNA, while at 39 C four mutants demonstrated a DNA+ phenotype, three were DNA+/-, and eight were DNA-. DNA+ mutants induced levels of DP activity similar to thhose of the wild-type virus at both temperatures, and DNA+/- mutants induced reduced levels of DP activity at 39 C but not at 34 C. Among the DNA- mutants three were DP+, two were DP+/-, and three showed reduced DP activity at 34 C with no DP activity at 39 C. DNA-, DP- mutants induced the synthesis of a temperature-sensitive DP as determined by in vivo studies.

Replication of bacteriophage SH-133 in the facultative autotroph Hydrogenomonas facilis. I. Bacteriophage synthesis under heterotrophic, autotrophic, and mixotrophic growth conditions.

The ability of bacteriophage SH-133 to replicate in heterotrophically (H-) and autotrophically (A-) grown Hydrogenomonas facilis was examined. Both the synthesis of infectious phage particles and the efficiency of plating (EOP) were reduced by 90% in A-grown cells. Adsorption of phage and lethal effects on H. facilis were identical in both systems. One-step growth experiments showed that cell lysis preceded the appearance of infectious particles in A-grown cells. Burst size studies with mixotrophically grown cells did not indicate the presence of an inhibitor of phage synthesis indigenous to autotrophic metabolism. DNA synthesis was identical in H- and A-grown infected cells; however, protein synthesis was significantly reduced in A-grown infected cells when compared with protein synthesis in H-grown infected cells. The data suggest that the reduction in EOP and phage synthesis in A-grown cells is caused by a defect in viral protein synthesis which results in the limited production of an essential viral protein at the time of cell lysis.

Replication of bacteriophage SH-133 in the facultative autotroph Hydrogenomonas facilis. II. Bacteriophage synthesis and hydrogenase induction under step-up and step-down growth conditions.

Autotrophically grown infected cells are able to replicate phage SH-133 after being switched to a heterotrophic environment (step-up growth). The effect of step-down growth on phage replication varies with the choice of organic substrate. Phage replication and the induction of cellular hydrogenase occur under step-down growth from acetate but not peptone broth. The requirement of a continued source of energy for phage replication in either heterotrophically or autotrophically grown cells could be uniquely demonstrated in this phage-host system by the deletion of hydrogen from the growth medium.