Growth performances ofLactobacillus hilgardii immobilized in dextran gel and in continuous fermentation.

A variant ofLactobacillus hilgardii was immobilized by its own production of dextran gel, forming grains. The best rate of weight increase of the gel in continuous fermentation was 16.3±3.3%/h, at pH 4.8±0.1 and with a dilution rate of 0.22 to 0.26/h. Observation by scanning electron microscopy located most of the bacteria as microcolonies on the surface. A similar arrangement appeared in calcium alginate beads. The best population density (10(10) cells/g) was obtained in grains at pH 5.8, after 30h. At a similar pH value, 4.8, the growth rate was higher in alginate beads than in dextran gel but the final population density was approximately the same. Acidification rate increased faster with mixed gel at pH 5.2 than with dextran at pH 5.8.

Lactobacilli isolated from sugary kefir grains capable of polysaccharide production and minicell formation.

Homo- and heterofermentative species of Lactobacillus have been isolated from sugary kefir grains. Most of the homofermentative strains fermented tagatose and aldonitol and presented 48-54% of homology with Lactobacillus paracasei ssp. paracasei NCDO 151 (ex Lactobacillus casei). The two variants of a hetero-fermentative species, although fermenting arabinose, were related to Lactobacillus hilgardii NCDO 264 (type strain) with 88% of homology. One of them produced polysaccharide from sucrose at pH 4.8 and 30 degrees C; the best glucose conversion into polysaccharide was obtained from 3% of sucrose (81.8%), and the maximum production occurred about 35 hours after the end of the log phase of growth, in MRS sucrose broth. Polysaccharide formation did not occur above 40 degrees C, a temperature at which no growth was observed. The two variants were forming minicells by abnormal divisions.

The spectrum of mutations generated by passage of a hydrogen peroxide damaged shuttle vector plasmid through a mammalian host.

Treatment of a plasmid shuttle vector (pZ189) with a combination of hydrogen peroxide and a ferric iron/EDTA complex prior to transfection and passage in simian (CV-1) cells increases the frequency of mutations at the supF locus by up to 60-fold over the spontaneous background. This increase in mutation frequency is abolished when the inhibitors desferrioxamine, superoxide dismutase, catalase or dimethyl sulfoxide are included in the initial reaction or when the iron/EDTA complex is omitted, a strong indication that the premutagenic damage arises as a result of direct attack by hydroxyl radical generated in a superoxide driven Fenton reaction. DNA sequence analysis of the mutated plasmids shows that 1) Deletions occuring in combination with base-substitutions arise in 22.5 percent of the induced mutants compared with only 3 percent of spontaneous mutants 2) Sixty percent of all induced deletion mutations involve the loss of a single base and 77 percent of these (20 out of 26) occur at two adenine-containing sites 3) The base-change spectrum of mutants arising in the treated plasmid population is marked by the predominance of mutants containing a single base-change and by an increase in changes at AT base pairs. These results provide direct information concerning the nature of mutations arising in mammalian cells as a result of hydroxyl radical mediated DNA damage.

Singlet oxygen involvement in the inactivation of cultured human fibroblasts by UVA (334 nm, 365 nm) and near-visible (405 nm) radiations.

The UVA (320-380 nm) radiation inactivation of mammalian cells is dependent upon the presence of oxygen. In order to examine the intermediates involved, we have irradiated cells in the presence of chemical probes which are able to modify the activity of various oxygen species. We have also examined the possibility that UVA inactivates cultured human fibroblasts via generation of intracellular hydrogen peroxide. An iron scavenger (desferrioxamine) and a hydroxyl radical scavenger (dimethylsulfoxide) protect the cells against hydrogen peroxide. Diethyldithiocarbamate (a superoxide dismutase inhibitor) and aminotriazole (a catalase inhibitor) sensitize the cells to this oxidizing agent. These data support previous reports that hydrogen peroxide inactivates as a result of the iron-catalyzed generation of hydroxyl radical. None of these agents significantly alter the fluence-dependent inactivation of cell populations by radiation at 365 nm. In contrast, the cells are sensitized to radiation at 334, 365 and 405 nm in the presence of deuterium (an enhancer of singlet oxygen lifetime) and are protected against radiation at 365 nm by sodium azide (a quencher of singlet oxygen). These results are consistent with the conclusion that the generation of singlet oxygen, but not hydrogen peroxide or hydroxyl radical, plays an important role in the inactivation of cultured human cells by UVA and near-visible radiations.

Action spectra for human skin cells: estimates of the relative cytotoxicity of the middle ultraviolet, near ultraviolet, and violet regions of sunlight on epidermal keratinocytes.

Action spectra for the cytotoxic action of electromagnetic radiation in the solar range 280-434 nm have been determined for human fibroblasts and epidermal keratinocytes derived from the same foreskin biopsy. The spectra for the two cell types are close to identical and coincide with our previously published data for a human lymphoblastoid line indicating that the mechanism of inactivation of the three human cell types is similar at any given wavelength. Using published data for ultraviolet transmission of human skin and sample spectral irradiance data, we have estimated the relative biological effectiveness of the middle ultraviolet (UVB) (290-320 nm), near ultraviolet (UVA) (320-380 nm), and violet (380-434 nm) regions of sunlight for cytotoxicity at the basal layer of the epidermis. We conclude that the UVB component in noon summer sunlight (the most UVB rich spectral conditions tested) may contribute only about 40% of the total cytotoxic effectiveness of sunlight at 290-434 nm. At lower zenith angles, UVA can account for up to 80% of the cytotoxic effectiveness of the combined UVA and UVB regions. Finally, a comparison of published action spectra data for human erythema with cytotoxicity data corrected for ultraviolet transmission to different depths of the human epidermis suggests that UVA erythema could be causally related to cytotoxicity occurring at an average depth of 40-50 micron into the human epidermis.

Quantitative differences in host cell reactivation of ultraviolet-damaged virus in human skin fibroblasts and epidermal keratinocytes cultured from the same foreskin biopsy.

Repair efficiency of cultured cells may be estimated by measuring the ability of a particular cell type to support virus damaged by an appropriate agent. In this study we have compared the inactivation of ultraviolet (254 nm)-damaged herpes simplex virus in human fibroblast and epidermal keratinocyte cell lines derived from the same foreskin biopsy and found the epithelial cells to be a factor of 3 times less efficient in supporting the damaged virus. The two different cell types show comparable ultraviolet inactivation of clone-forming ability, indicating that the difference is specific to viral host cell reactivation. This study required the development of a quantitative infectious centers assay for the measurement of viral titer in human epithelial cells, a system which may be of more general application in studies of potential human carcinogens.

Excision repair in u.v. (254 nm) damaged non-dividing human skin fibroblasts: a major biological role for DNA polymerase alpha.

We have used the eukaryotic DNA polymerase alpha inhibitor, aphidicolin, and the polymerase beta inhibitor, dideoxythymidine, to examine the role of these enzymes in excision repair of ultraviolet (u.v., 254 nm) damage induced in non-dividing (arrested) human skin fibroblasts. The effects of these drugs on u.v.-treated cells have been monitored using a simple and reproducible repair synthesis assay in parallel with viability measurements to determine the degree of inhibition of repair of potentially lethal damage. In agreement with previous studies using density gradients, repair synthesis induced by low fluences of u.v. (less than 3 J m-2) is relatively insensitive to inhibition by aphidicolin compared to high fluences where approximately 85 per cent inhibition is observed at the highest (20 micrograms/ml) aphidicolin concentration employed. However, repair of potentially lethal damage is inhibited by at least 90 per cent over the entire fluence range. Although dideoxythymidine led to considerable inhibition of repair synthesis, the result is probably an artifact under these in vivo conditions. The polymerase beta inhibitor was not toxic to u.v.-treated cells nor did it add to the toxicity of aphidicolin when the drugs were used in combination. We conclude that if the beta polymerase is involved in excision repair then its temporary (4 h) inhibition by dideoxythymidine is entirely reversible. In contrast, polymerase alpha appears to be an enzyme essential to the majority of biologically effective excision repair over the entire u.v. fluence range tested.