Mechanisms of triple stress-mediated damage in stationary phase cells of Salmonella typhimurium exposed to succinate-acidified hypochlorite system at 5° C

Exposure for 20 min of stationary phase cells of Salmonella typhimurium to a combined triple stress system (TSS) treatment comprising hypochlorite derived 5 ppm free available chlorine in solution acidified with 1% succinate (pH 2·5) and at a chill shock temperature of 5°C resulted in symptoms of injury. Cells became sensitive to 40 μg/ml lysozyme, 50 μg/ml actinomycin D and 100 μg/ml ribonuclease B, to which control cells were resistant. Metabolic injury was indicated by reduction in colony forming ability of stressed cells on minimal salts glucose agar M9 medium. There was no detectable leakage loss of 260–280 nm-absorbing materials. This was also confirmed by assay of the cellular RNA material components. Loss of alkaline phosphatase activity was observed in the stressed cells.
The intensity of induced cellular damage as measured by lysozyme sensitivity was greatest in the cells exposed to the complete TSS, followed by those stressed in 1% succinate at 5°C, then 5 ppm chlorine at 5°C and the singular chill shock stress at 5°C, respectively. The magnitudes of cellular damage, however, were suggestive of synergistic interactions among the component stress factors of the TSS.
The findings obtained indicate impairment of the structural integrity and functional capabilities of the permeability barriers and the inactivation of certain periplasmic enzymes. The resultant cumulative cellular damage from the TSS exposure may therefore enhance greater sensitivity of treated cells to subsequent stress factors.     

Enhanced intensity of polycentric chromosome formation in cells with micronuclei exposed to 5-bromodeoxyuridine under prolonged hyperthermia at 40 degrees C

The formation of polycentric chromosomes in metaphases of the first mitotic division of polykaryocytes containing micronuclei, under 5-BrdU treatment in the condition of a prolonged hyperthermia was studied. It was shown that the enhance of the frequency of polycentric chromosomes at 40 degrees C was statistically reliable. These data propose the existence of an enzymatic mechanism of disrupting the chromosomal ends at mitosis at the optimal condition (37 degrees C). In cells with micronuclei, under 5-BrdU treatment at 40 degrees C, this mechanism undergoes, presumably, a partial inhibition leading to the enhanced frequency of chromosomes with fused telomeres.     

Immune response of Tilapia aurea exposed to Salmonella typhimurium

Tilapia aurea showed a specific immune response to Salmonella typhimurium. S. typhimurium was introduced into the gut of T. aurea by force-feeding. S. typhimurium was isolated from the fish viscera after 15 days, but at 30 days viable cells were not detected. T. aurea had an antibody titer to S. typhimurium after 30 days which was fivefold greater than the natural background antibody titer. An elevated antibody titer was not indicative of active bacterial infection.     

Low-temperature damage and subsequent recovery of fab1 mutant Arabidopsis exposed to 2 degrees C.

The fab1 mutant of Arabidopsis thaliana, which contains increased levels of saturated fatty acids, was indistinguishable from the wild type when it was grown at 22 or 12 degrees C. During the first 7 to 10 d after transfer to 2 degrees C, the growth and photosynthetic characteristics of the fab1 plants remained indistinguishable from the wild type, with values for the potential quantum efficiency of photosystem II decreasing from 0.8 to 0.7 in plants of both lines. Whereas wild-type plants maintained quantum efficiency of photosystem II at approximately 0.7 for at least 35 d at 2 degrees C, this parameter declined rapidly in the mutant after 7 d and reached a value of less than 0.1 after 28 d at 2 degrees C. This decline in photosynthetic capacity was accompanied by reductions in chlorophyll content and the amount of chloroplast glycerolipids per gram of leaf. Electron microscopic examination of leaf samples revealed a rapid and extensive disruption of the thylakoid and chloroplast structure in the mutant, which is interpreted here as a form of selective autophagy. Despite the almost complete loss of photosynthetic function and the destruction of photosynthetic machinery, fab1 plants retained a substantial capacity for recovery following transfer to 22 degrees C. These results provide a further demonstration of the importance of chloroplast membrane unsaturation to the proper growth and development of plants at low temperature.     

Survival of dehydrated cells of Salmonella typhimurium LT2 at high temperatures

Cells of Salmonella typhimurium LT2 were dehydrated on hydrophobic membranes (Millipore FGLP2500) placed in a controlled atmosphere chamber held at 57% equilibrium relative humidity (ERH) and 37 degrees C. Dehydration for 48 h under the above conditions increased the heat resistance of Salm. typhimurium LT2 when measured as the surviving fraction after a heat challenge of 135 degrees C for 30 min. Results also showed that little or no death occurred during heat challenges of 1 h at temperatures of up to 100 degrees C. The survival of Salm. typhimurium LT2 was measured as the ability to form colonies on solid media tryptone soy broth plus 1.2% agar (TSBA) after 24 h at 37 degrees C. Incorporation of sodium pyruvate, at a concentration of (TSBA) after 24 h at 37 degrees C. Incorporation of sodium pyruvate, at a concentration of 0.2% into the recovery medium, did not enhance the recovery of heated Salm. typhimurium LT2. Dehydrated cells of S. typhimurium LT2 showed a triphasic death curve. Increasing the period of dehydration from 48 h to 34 d, reduced initial numbers due to die off but did not alter the shape of the subsequent survival curve.     

The N4-hydroxycytidine reduction system in toluenized cells of Salmonella typhimurium.

1. Enzymatic reduction of N4-hydroxycytidine to cytidine in Salmonella typhimurium is highly specific. The reaction occurs only at the nucleoside level. Free base or its 1-methyl analogue is not reduced. 2. The pH optimum shows a broad plateau with a maximum at pH 7.0. The apparent Km value, estimated in the toluene-treated cells, is 4.8 mM and Vmax 1.4 nmoles/min/mg of wet bacterial weight. The reaction is NADH-dependent, although in toluenized bacterial cells it can occure without addition of any exogenous factor.     

DNA damage in cells exposed to ionizing radiation

Ionizing radiation induces variety of structural lesions in DNA of irradiated organisms. Their formation depends largely on the degree of cell oxygenation, the level of endogenous antioxidants, on DNA-protein complexes and compactization of DNA in the chromatin and activity of DNA repair systems. All ionizing radiation-induced DNA lesions can arbitrarily be divided into two groups. Group 1 includes singly damaged sites (single-sites): base modification, single-strand breaks, alkaline-labile sites (including a basic sites). Group 2 contains: locally multiply damaged sites (clustered lesions), double-strand breaks, intermolecular cross-links. The yields of lesions of group 2 increases with high linear energy transfer of radiation and these lesions play a dominant role in the radiation death, formation of chromosome and gene mutations, cell transformation.     

Short-term preservation of mouse oocytes at 5 degrees C.

The temporary preservation of oocytes without freezing would be useful for some experiments. ICR mouse oocytes were kept in a preservation medium under mineral oil for 1, 2, 3, 4 or 7 days at 5 degrees C, and 1 or 2 days at 37 degrees C. In vitro fertilization was attempted on oocytes rinsed with TYH medium after preservation. More than 70% of morphologically normal oocytes were recovered from each preservation group. Fertilization rates of oocytes preserved for 1, 2, 3, 4 or 7 days at 5 degrees C were 69.9, 66.5, 45.3, 26.7 and 8.8% respectively. Fertilization rates of oocytes preserved for 1 or 2 days at 37 degrees C were 9.6 and 1.6%, respectively. Preservation of oocytes at 5 degrees C has some capability as a method of short-term storage without freezing.     

Multimeric C9 within C5b-9 deposits in unique locations in the cell wall of Salmonella typhimurium

We have shown previously that multimeric C9 within C5b-9 (C9:C5b-8 greater than 3:1) is needed for killing of a rough strain of Escherichia coli. We now extend these studies using serum sensitive, rough (R) and serum resistant, wild type (WT) strains of Salmonella typhimurium as well as a mutant S. typhimurium strain (TS) with a temperature sensitive mutation in synthesis of keto-deoxy-octulosonate, a constituent within the deep core structure of Salmonella LPS. Both R and TS required multimeric C9 within C5b-9 to be killed. Addition at 37 degrees C of increasing inputs of C9 to TS or R bearing C5b-9 led to a dose-related increase in C9 binding and killing. In contrast, addition of high inputs of C9 to the same strains at 4 degrees C, a procedure that limits the C9:C5b-8 ratio to 1:1, resulted in low C9 binding and minimal killing. Bactericidal C5b-9 formed at 37 degrees C on R and TS with high inputs of C9 co-sedimented with the bacterial outer membrane on sucrose density gradient analysis. Non-bactericidal C5b-9 on R, WT, and TS co-sedimented near the inner membrane, despite the presumed lack of association between these constituents. Whereas 125I C9 within the non-bactericidal pools immunoprecipitate with anti-C5, 125I C9 within bactericidal pools did not immunoprecipitate with anti-C5, anti-C7, or anti-C9. These findings suggest that bactericidal C5b-9 may be deposited in a unique location or configuration within the bacterial cell wall.     

HeLa cells synthesize a specific heat shock protein upon exposure to heat shock at 42 degrees C but not at 45 degrees C

Upon exposure to heat shock, HeLa cells synthesize a small set of proteins having the molecular weights of 70,000, 73,000, 78,000, 85,000, 92,000, and 105,000. In addition to these proteins, we found an unusual heat shock protein induced by heat shock at 42 degrees C, but not at 45 degrees C. The 42 degrees C-specific protein, the molecular weight of which was 90,000, was not produced in control cells and the induction of the protein was completely inhibited by actinomycin D. The protein was not induced by other treatments that induced most heat shock proteins. Thus, this 42 degrees C-specific protein seems to have a peculiar induction mechanism and a specific function in the cells.     

Equilibrium binding of insulin to rat white fat cells at 15 degrees C

Equilibrium binding of insulin to isolated rat epididymal fat cells was investigated. A temperature of 15 degrees C was chosen for the study to minimize lysosomal degradation of insulin. Indeed, medium insulin lost only 1% of its precipitability in trichloroacetic acid during the 4-h incubation required to approach equilibrium. Binding was measured by a method that did not perturb the equilibrium of the system. A new formalism for analyzing binding data in general was introduced. A correction for trapping of insulin in the interstitial space of cell pellets was both necessary and sufficient to derive specific binding data from raw observations. Thus, so-called "nonspecific binding" was unmasked as a misnomer, and the expression "correction for trapping" was proposed as a substitute. Equations for one and two independent classes of binding sites were fit to the data by the method of maximum likelihood, and the best fit was selected based on Akaike's information criterion, as adapted for a constant fractional error. More than 99.7% of the binding sites were found to be describable by a simple binding isotherm with Kd,app = 8.8 multiplied by over divided by 1.3 nM. Less than 0.3% sites had a higher affinity (Kd approximately equal to 8 multiplied by over divided by 3 pM). There were 99,000 x/divided by 1.6 binding sites/cell. These equilibrium parameters are in agreement with values derived from a kinetic analysis, presented in the subsequent paper (Lipkin, E. W., Teller, D. C., and de Ha?n, C. (1986) J. Biol. Chem. 260, 1702-1711).     

Kinetics of insulin binding to rat white fat cells at 15 degrees C

The kinetics of insulin binding to isolated rat epididymal fat cells was investigated at 15 degrees C, at which temperature the system was simplified by the absence of lysosomal insulin degradation. The data were fit by maximum likelihood criteria with differential equations describing a number of models for the interaction of insulin and cells. Among those models that yielded a fit, the selection criteria were minimization of the Akaike information criterion and compatibility of the overall equilibrium constant for the system calculated from rate constants with the previously obtained experimental value. The results of the analysis indicated that insulin, I, first reversibly bound to cell surface receptors, R, whereupon this initial insulin-receptor complex, RI, reversibly altered its state or cellular location to R'I, according to the following equation. (Formula: see text) No evidence was found that insulin could either associate or dissociate from R'I directly. The association rate constant was kappa 12 = 1.6 x/divided by 1.4 X 10(5) liter mol-1 s-1, a value shown to be incompatible with diffusion control. The other rate constants were: kappa 21 = 3.4 x/divided by 1.6 X 10(-3) s-1, kappa 23 = 3.2 x/divided by 1.5 X 10(-4) s-1, and kappa 32 = 2.0 x/divided by 1.5 X 10(-4) s-1. From these rate constants, an equilibrium constant of 8.4 x/divided by 1.5 nM was calculated, in excellent agreement with the previously measured value of 8.8 x/divided by 1.3 nM (Lipkin, E. W., Teller, D. C., and de Ha?n, C. (1986) J. Biol. Chem. 260, 1694-1701). The kinetic analysis also yielded receptor numbers similar to those obtained by equilibrium binding studies. The nature of the R'I state is discussed in terms of an internalized state, in terms of insulin receptor complex in caveolae, in terms of receptor aggregates, and in terms of being a Michaelis complex between insulin bound to the receptor and cell surface-bound insulin protease.