Barbara Karska-Wysocki

Antibacterial activity of Lactobacillus acidophilus and Lactobacillus casei against methicillin-resistant Staphylococcus aureus (MRSA).

Methicillin-resistant Staphylococcus aureus (MRSA) is a multidrug-resistant microorganism and the principal nosocomial pathogen worldwide. The antibacterial activity of lactic acid bacteria against MRSA from ten human clinical isolates as well as MRSA standard strain ATCC 43300 was tested in vitro. The Lactobacillus (Lb.) strains (Lb. acidophilus CL1285(®) and Lb. casei LBC80R) as pure cultures, which came from commercial food products were employed. The growth inhibitory effect produced by the antimicrobial activity of the lactic acid bacteria on the MRSA strains was tested on solid medium using agar diffusion methods as well as a using a liquid medium procedure that contained a mixture of MRSA and lactic acid bacteria cultures. In the latter instance, we were able to demonstrate that the direct interaction of lactic acid bacteria and MRSA in such a mixture led to the elimination of 99% of the MRSA cells after 24 h of their incubation at 37°C.

Inactivation of the T7 coliphage by monofunctional alkylating agents: Action on phage adsorption and injection of its DNA

Alkylation by ethyl or methyl methanesulfonate to an extent that inactivates more than 99.5% of T7 coliphages has no effect on phage adsorption on Escherichia coli B cells, but decreases the amount of phage DNA injected into the host cells. Depurination interferes with the injection of the phage DNA. Failure to inject the whole phage genome thus appears to be a cause of the immediate as well as of the delayed inactivation of the T7 coliphage treated by monofunctional alkylating agents; the hypothesis that it is the only cause of inactivation, although not very likely, cannot be excluded at the present time.

Role of 3-methyladenine-DNA glycosylase in host-cell reactivation of methylated T7 bacteriophage

Purified T7 phage, treated with methyl methanesulfonate, was assayed on four Escherichia coli K12 host cells: (1) AB1157, wild-type; (2) PK432-1, lacking 3-methyladenine-DNA glycosylase (tag); (3) NH5016, lacking apurinic endonuclease VI (xthA); (4) p3478, lacking DNA polymerase I (polA), the latter three strains being deficient in enzymes of the base excision repair pathway. For inactivation measured immediately after alkylation, phage survival was lowest on strains PK432-1 and p3478; for delayed inactivation, measured after partial depurination of alkylated phage, survival was much lower on strain p3478 than on PK432-1. These results demonstrate the important role played by 3-methyladenine-DNA glycosylase in the survival of methylated T7 phage. Quantitative analysis of the data, using the results of Verly et al. (Verly, W.G., Crine, P., Bannon, P. and Forget, A. (1974) Biochim. Biophys. Acta 349, 204-213) to correlate the dose with the number of methyl groups introduced into phage DNA, revealed that 5-10 3-methyladenine residues per T7 DNA constituted an inactivation hit for the tag mutant. Thus, 3-methyladenine may be as toxic a lesion as an apurinic site.

Characterization of morphogenetic intermediates and progeny of normal and alkylated bacteriophage T7

Analysis of thin sections of Escherichia coli B cells infected by normal (nonalkylated) or alkylated bacteriophage T7 showed that alkylation altered phage morphogenesis. To understand these morphogenetic alterations, we have isolated phage-related particles from infected-cell lysates by differential and sucrose gradient centrifugation. Cells infected by normal and by alkylated phage produced mature phage particles, empty heads, and proheads; however, production of proheads and mature phage particles was less in the case of alkylated phage. These lysates also contained sedimentable material which migrated more slowly than empty heads on sucrose gradients. In the case of alkylated phage, this peak contained radioactive material in amounts nearly equal to that in either proheads or empty heads; for normal phage, this peak represented a smaller fraction of the total radioactivity. Examination of the gradient fractions by electron microscopy revealed appreciable quantities of phage tails and tail-related particles. The same gradient fractions contained phage tail proteins: gene products (gps) 11, 12, and 17 as well as smaller amounts of gp 8, the head-tail connector. In addition, these fractions contained two other proteins which we believe to be of bacterial origin. These proteins may be related to tail formation or function as part of the phage receptor. On the basis of our data, we propose an alternative morphogenetic pathway for T7 tail formation, a pathway which would involve formation of a complex of tail proteins prior to association with the phage head.

Mechanism of inhibition of bacteriophage T7 DNA synthesis in Escherichia coli B cells infected by alkylated bacteriophage T7

Quantitative analysis of DNA replication, in E. coli B cells infected by methyl methanesulfonate-treated bacteriophage T7, showed that production of phage DNA was delayed and decreased. The cause of the delay appeared to be a delay in host-DNA breakdown, the process which provides nucleotides for phage-DNA synthesis. In addition, reutilisation of host-derived nucleotides was impaired. These observations can be accounted for by a model in which methyl groups on phage DNA slow down DNA injection and also reduce the replicational template activity of the DNA once it has entered the cell. Repair of alkylated phage DNA may be required not only for replication but also for normal injection of DNA.

Treatment of ultracentrifuge tubes in a glow discharge makes their surfaces wettable

After exposure to a glow discharge, Ultra-Clear ultracentrifuge tubes become wettable and hence suitable for use with conventional gradient formers. Tubes treated by this method can thus replace the formerly widely used cellulose nitrate tubes which are no longer available.