Your search keyword '"Enterococcus faecalis analysis"' showing total 4 results

1. Differential scanning calorimetry of bacteria.

Author

Miles CA, Mackey BM, and Parsons SE

Subjects

Bacillus cereus analysis, Base Composition, DNA, Bacterial, Enterococcus faecalis analysis, Escherichia coli analysis, Geobacillus stearothermophilus analysis, Pseudomonas analysis, Streptococcus analysis, Temperature, Vibrio analysis, Bacteria analysis, Calorimetry, Calorimetry, Differential Scanning

Abstract

Thermograms obtained by differential scanning calorimetry of a range of bacteria of different heat resistances were compared. Equations were derived to calculate the rate at which the numbers of viable organisms in a calorimeter decline as the temperature is raised at a constant rate. Vegetative bacteria scanned at 10 degrees C min-1 showed multi-peaked thermograms with four major peaks (denoted m, n, p and q) occurring in the regions 68-73, 77-84, 89-99 and 105-110 degrees C respectively. Exceptions were that peak m (the largest peak) occurred at 79-82 degrees C in Bacillus stearothermophilus and an additional peak, r, was detected in Escherichia coli at 119 degrees C. At temperatures below the main peak m there were major differences in thermograms between species. There was a direct relationship between the onset of thermal denaturation and the thermoresistance of different organisms. Heat-sensitive organisms displayed thermogram features which were absent in the more heat-resistant types. When samples were cooled to 5 degrees C and re-heated, a small endothermic peak, pr, was observed at the same temperature as p. Peaks p and pr were identified as the melting endotherms of DNA. In all vegetative organisms examined, maximum death rates, computed from published D and z values, occurred at temperatures above the onset of thermal denaturation, i.e. cell death and irreversible denaturation of cell components occurred within the same temperature range.

Published

1986

2. Purification and properties of LIQ 4, an antibacterial substance produced by Streptococcus faecalis var. liquefaciens K4.

Author

Kühnen E, Sahl HG, and Brandis H

Subjects

Chromatography, High Pressure Liquid, Enterococcus faecalis growth & development, Peptide Biosynthesis, Peptides isolation & purification, Anti-Bacterial Agents biosynthesis, Anti-Bacterial Agents isolation & purification, Enterococcus faecalis analysis

Abstract

An antibacterial substance (LIQ 4) produced by Streptococcus faecalis var. liquefaciens K 4 was isolated in extracellular and cell associated form. It markedly inhibited the growth of Gram-positive bacteria, whereas only a few Gram-negative bacteria were susceptible. LIQ 4 was purified by hydrophobic chromatography (Servachrome XAD-2; octyl-Sepharose CL-4B; Sephadex LH 60) and Sephacryl S-200. TLC yielded a fluorescent spot as the active component and several inactive ninhydrin-positive substances. These contaminating peptides strongly adsorbed to LIQ 4 and could only be removed by repeated reversed phase HPLC. Furthermore, HPLC separated LIQ 4 into seven closely related substances. All showed strong fluorescence under UV light, stained yellow with ninhydrin, and contained aspartate and lysine after acid hydrolysis. The molecular weight was estimated by Amicon ultrafiltration to be less than 2000. LIQ 4 was stable at 80 degrees C (30 min) and pH 2, but considerably inactivated above pH 8. It was apparently affected by proteolytic enzymes, but the activity could be fully restored upon heating.

Published

1985

3. Taxonomic studies on some group D streptococci.

Author

Farrow JA, Jones D, Phillips BA, and Collins MD

Subjects

Base Composition, DNA, Bacterial analysis, Enterococcus faecalis analysis, Enterococcus faecalis classification, Fatty Acids analysis, Nucleic Acid Hybridization, Streptococcus analysis, Vitamin K analysis, Streptococcus classification

Abstract

Biochemical, menaquinone, fatty acid and DNA analyses were conducted on a number of streptococci of serological group D. The results indicate that S. faecalis, S. faeclum, S. casseliflavus and taxa previously designated 'S. avium', 'S. durans' and "S. faecalis var. malodoratus' are distinct species. Strains previously labelled 'S. faecium var. mobilis' were shown to be identical with S. casseliflavus. The results also indicate that some group D streptococci recently isolated from chickens constitute a new species.

Published

1983

4. An electron microscopic study of the location of teichoic acid and its contribution to staining reactions in walls of Streptococcus faecalis 8191.

Author

Garland JM, Archibald AR, and Baddiley J

Subjects

3,3'-Diaminobenzidine, Cell Membrane ultrastructure, Cell Wall ultrastructure, Concanavalin A, Densitometry, Enterococcus faecalis analysis, Gold, Histocytochemistry, Lead, Peroxidases, Ruthenium Red, Staining and Labeling, Teichoic Acids physiology, Uranium, Enterococcus faecalis ultrastructure, Teichoic Acids isolation & purification

Abstract

The location of the glucosylated teichoic acid in whole cells and isolated walls of Streptococcus faecalis 8191 has been investigated using ruthenium red, gold-labelled concanavalin A and concanavalin A-peroxidase-diaminobenzidine. Dense laminae were revealed in sections of osmium-fixed walls stained with ruthenium red which corresponded to similar regions stained by uranyl and lead. Such regions were not seen after teichoic acid had been extracted, suggesting that the uptake of stain was by teichoic acid. However, these regions were not labelled on exposure to gold concanavalin A or concanavalin A-peroxidase-diaminobenzidine; these stains indicated that teichoic acid was situated between the dense laminae, although the distribution of stain could have been due to the inability of the concanavalin A stains to penetrate deeply. Chemical binding studies showed that the teichoic acid was the major uranyl binding component in isolated walls, from which it might be inferred that teichoic acid was located in the densely staining regions. However, since osmification significantly increased the binding of uranyl (and lead stains) to non-teichoic acid material, such an inference was not necessarily valid. It is concluded that the presence of teichoic acid can be demonstrated in certain regions of the wall by concanavalin A, but its presence in densely staining regions has not been established. These experiments therefore suggest that teichoic acid may not be intimately associated with the mechanisms that generate contrast patterns in stained sections of cell walls of Streptococcus faecalis.

Published

1975