The Role of Bacterial Growth Autoregulators (Alkyl Hydroxybenzenes) in the Response of Staphylococci to Stresses

The investigation of the response of a batch culture of Staphylococcus aureus to exogenous alkyl-substituted hydroxybenzenes (AHBs), chemical analogues of anabiosis autoinducers, showed that C₁-AHB at concentrations from 5 M to 1.5 mM did not influence the culture growth, whereas the more hydrophobic C₆-AHB inhibited it at concentrations of 0.5 mM and higher. Either of the AHBs drastically enhanced the phenotypic dissociation of staphylococcal cultures, which manifested itself in an increase in the fraction of cells producing small nonhemolyzing colonies of G type when plated on solid media with erythrocytes. In a submerged staphylococcal culture, the relative number of cells producing G-type colonies varied from 10 to 90%, depending on the concentration of the AHB added. The growth of S. aureus in the presence of AHBs also enhanced cell tolerance to heat shock (heating at 45 or 60°C for 10 min). The role of AHBs, which are structural modifiers of membranes and possess chaperone activity, in the mechanisms responsible for cell tolerance and phenotypic dissociation of microbial populations is discussed.     

The effect of anabiosis autoinducers on the bacterial genome

The mutagenic activity of chemical analogues of microbial anabiosis autoinducers (the autoregulatory d1 factors of cell differentiation), which act to inhibit cell proliferation, to enhance cell tolerance, and to induce the transition of cells to anabiotic state, was studied using the Ames test. In the range of concentrations studied (0.1 to 100 micrograms/ml), alkyl-substituted hydroxybenzenes (AHBs) differing in hydrophobicity, i.e., methylresorcinol (C1-AHB) and hexylresorcinol (C6-AHB), as well as unsubstituted resorcinol, showed different growth-inhibiting and mutagenic effects. C6-AHB was found to inhibit the growth of Salmonella typhimurium TA100 and to induce its mutagenesis at a rate of 1.8 revertants/nmol. C1-AHB taken at low concentrations not only failed to inhibit bacterial growth but even stimulated it and exerted an antimutagenic effect. Unsubstituted resorcinol virtually did not influence bacterial growth and showed weak mutagenic activity. The growth-inhibiting effect of elevated C6-AHB concentrations correlated with the degree of the transition of the original phenotype producing S-type colonies to a phenotype producing R-type colonies. The role of AHB homologues, as microbial autoregulators with mutagenic activity, in the regulation and correlation of two processes (the phenotypic dissociation of microbial populations and the formation of resting microbial forms) is discussed. The accumulation of AHBs in senescent microbial cultures may induce adaptive mutations, change the expression of genes, and promote the development of minor cell subpopulations (phenotypes), thus providing for the adaptation of these cultures to varying environmental conditions.     

The Effect of Anabiosis Autoinducers on the Bacterial Genome

The mutagenic activity of chemical analogues of microbial anabiosis autoinducers (the autoregulatory d₁ factors of cell differentiation), which act to inhibit cell proliferation, to enhance cell tolerance, and to induce the transition of cells to an anabiotic state, was studied using the Ames test. In the range of concentrations studied (0.1 to 100 g/ml), alkyl-substituted hydroxybenzenes (AHBs) differing in hydrophobicity, i.e., methylresorcinol (C₁-AHB) and hexylresorcinol (C₆-AHB), as well as unsubstituted resorcinol, showed different growth-inhibiting and mutagenic effects. C₆-AHB was found to inhibit the growth of Salmonella typhimurium TA100 and to induce its mutagenesis at a rate of 1.8 revertants/nmol. C₁-AHB taken at low concentrations not only failed to inhibit bacterial growth but even stimulated it and exerted an antimutagenic effect. Unsubstituted resorcinol virtually did not influence bacterial growth and showed weak mutagenic activity. The growth-inhibiting effect of elevated C₆-AHB concentrations correlated with the degree of the transition of the original phenotype producing S-type colonies to a phenotype producing R-type colonies. The role of AHB homologues, as microbial autoregulators with mutagenic activity, in the regulation and correlation of two processes: the phenotypic dissociation of microbial populations and the formation of resting microbial forms, is discussed. The accumulation of AHBs in senescent microbial cultures may induce adaptive mutations, change the expression of genes, and promote the development of minor cell subpopulations (phenotypes), thus providing for the adaptation of these cultures to varying environmental conditions.     

Regulatory effect of microbial alkyloxybenzenes of different structure on the stress response of yeast

The effect of alkylhydroxybenzenes (AHBs) belonging to the class of alkylresorcinols differing in the degree of hydrophobicity—C7-AHB and more hydrophobic C12-AHB—on the resistance of Saccharomyces cerevisiae cells to heat shock and oxidative stress of lethal intensity was studied. Depending on structure and concentration, AHB added 2 h before exposure to stress had either an antistress or stress-potentiating effect on yeast cells in the mid-logarithmic growth phase. C7-AHB at concentrations 0.25–0.5 g/l caused a two-to fivefold increase in the resistance of yeast cells to hydrogen peroxide (30–150 mM), whereas C12-AHB reduced it at all concentrations. C7-AHB and C12-AHB had a similar effect on yeast subjected to heat shock (45°C, 30 min). It was found that the degree of the protective effect of C7-AHB and potentiating effect of C12-AHB depended on the nature of the stressor, being more pronounced in heat shock. The environmental significance of the antistress and stress-potentiating effects of microbial AHBs is discussed.     

Regulatory effect of microbial alkyloxybenzenes of different structure on the stress response of yeast

The effect of alkyloxybenzenes (AHBs) belonging to the class of alkylresorcinols differing in the degree of hydrophobicity--C7-AHB and more hydrophobic Cl12-AHB--on the resistance of Saccharomyces cerevisiae cells to heat shock and oxidative stress of lethal intensity was studied. Depending on structure and concentration, AHB added 2 h before exposure to stress had either an antistress or stress-potentiating effect on yeast cells in the mid-logarithmic growth phase. C7-AHB at concentrations 0.25-0.5 g/l caused a two- to fivefold increase in the resistance of yeast cells to hydrogen peroxide (30-150 mM), whereas Cl2-AHB reduced it at all concentrations. C7-AHB and Cl2-AHB had a similar effect on yeast subjected to heat shock (45 degrees C, 30 min). It was found that the degree of the protective effect of C7-AHB and potentiating effect of Cl2-AHB depended on the nature of the stressor, being more pronounced in heat shock. The environmental significance of the antistress and stress-potentiating effects of microbial AHBs is discussed.     

Role of alkylhydroxybenzenes in bacterial adaptation to unfavorable growth conditions

The adaptogenic effect of the chemical analogues of alkylhydroxybenzenes (AHBs), bacterial extracellular autoregulators (the individual compound C7-AHB and its technical preparation Sidovit), was demonstrated for two pseudomonad species, Pseudomonas aeruginosa and P. fluorescens. The protective effect of AHBs resulted in increased growth rate and biomass accumulation in bacteria grown under suboptimal conditions within the species tolerance range. The adaptogenic effect of AHBs (10–50 μmg/l) was more pronounced under more unfavorable growth conditions. In the case of P. fluorescens, the individual compound C7-AHB increased the biomass yield by 30% under alkaline conditions (pH 9.5), when the growth rate decreased by 80–90% compared to the optimum (pH 5.5–7.5). The Sidovit preparation, containing a mixture of natural AHBs with C7-AHB as the main component, increased the growth rate of P. aeruginosa by 40–60% at nonoptimal temperatures (45 and 10°C) or under enhanced salinity (1% NaCl). The action of AHBs as regulators of the rpoS and SOS response stress regulons was demonstrated to be among the mechanisms of their adaptogenic effect, as was demonstrated with the relevant reporter genes in the model strains E. coli C600 thi, thr, leuΔ(pro-lac) with the osmE-lacZ and umuD-lacZ hybrid operons, respectively. AHBs are technologically and economically acceptable as adaptogenic supplements for bacterial preparations used in soil bioremediation and oil spillage removal under conditions unfavorable for microbial growth, including increased salinity, extreme pH, and fluctuating sub- or supraoptimal temperatures.     

Effect of alkylhydroxybenzenes, microbial anabiosis inducers, on the structural organization of Pseudomonas aurantiaca DNA and on phenotypic dissociation induction

We revealed a relationship between alkylhydroxybenzene (AHB)-induced changes in the structural organization of supramolecular complexes (SC) of the DNA of Pseudomonas auraniaca and the phenotypic dissociation of this bacterium. The addition of 0.1-0.3 mM hexylresorcinol (C6-AHB), a chemical analogue of microbial anabiosis autoinducers, caused the formation of cystlike refractile cells (CRC) in these gram-negative, nonsporulating bacteria. Inoculating pseudomonad CRC on solid nutrient media resulted in phenotypic dissociation of the microbial population that yielded several variants with different colony structure and morphology. This manifested itself in the conversion of the original S-colony-forming phenotype into the R form and in the formation of less pigmented colonies. These transitions were possibly linked to AHB-induced structural changes in the DNA. In vitro studies revealed that AHB could interact with DNA SC, resulting in their structural modification that manifested itself in changes in their elastoviscosity. DNA supramolecular complexes isolated from proliferating, stationary-phase, and anabiotic P. aurantiaca cells differed in their elastoviscosity and capacity to interact with AHB homologues with different hydrophobicity, such as hexylresorcinol and methylresorcinol (C1-AHB). The DNA SC from actively proliferating cells were characterized by smaller elastoviscosity compared with those from stationary-phase and anabiotic cells, due to the difference in the DNA superspiralization degree and the physiological age of the bacteria involved. C6-AHB produced a pronounced relaxing effect on the DNA SC from exponential-phase P. aurantiaca cells. The less hydrophobic C1-AHB produced a similar effect on the DNA SC from stationary-phase cells. The curve of the dose-effect dependence of C6-AHB had a breaking point within the submillimolar (10(-4) M) concentration range. These concentrations induce the formation of cystlike anabiotic pseudomonad cells that are characterized by an unstable genotype and dissociate into distinct variants upon inoculation on solid media.     

Impact of bacterial autoregulatory molecules (homoserine lactones and alkylhydroxybenzenes) on the oxidative metabolism of the cell effectors of natural immunity

We investigated the impact of bacterial regulators homoserine lactones (HSLs) and alkylhydroxybenzenes (AHBs) (which are present in human fluids at pico- and nanomolar concentrations) on neutrophile oxidative metabolism. The HSL and AHB effects were determined using a test based on induced luminol-dependent chemoluminescence of neutrophiles in human peripheral blood. In this test, neutrophiles were preincubated with chemical analogs of bacterial autoregulators with different lengths of the hydrocarbon radical, such as HSL · HCl, C6- and C12-HSL, and C1-, C6-, and C12-AHB. We revealed that they suppressed the chemoluminescence and, accordingly, the oxidative metabolism of neutrophiles. This effect was more significant with HSLs than with AHBs. Within each of the two groups, the effect increased with an increase in the length of the hydrocarbon chain of the homologues. High concentrations of long-chain autoregulators of both types produce a cytotoxic effect that is associated with apoptosis in the case of C12-HSL and with cell membrane damage in the case of C12-AHB. The effects of low HSL and AHB concentrations involve their protein-modifying properties and result in changes in the activities of neutrophile oxidative enzymes. To a lesser extent, these effects are due to the pro- and antioxidant activities of HSLs and AHBs, respectively. In light of the results obtained, the HSL and AHB effects are to be considered as a novel mechanism of regulating the activities of cell effectors of natural innate immunity. In symbiotic and parasitic systems, the mechanism involves the bimodal pattern of the effects of HSLs and AHBs that vary depending on their structure and concentrations.     

The function of anabiosis autoinductors in microorganisms under blockade of metabolism

Alkyl-substituted hydroxybenzenes (AHBs), which are auto-inducers of microbial dormancy (d1 factors), were found to stabilize the structure of protein macromolecules and modify the catalytic activity of enzymes. In vitro experiments showed that C6-AHB at concentrations from 10(-4) to 10(-2) M, at which it occurs in the medium as a true solution and a micellar colloid, respectively, nonspecifically inhibited the activity of chymotrypsin, RNase, invertase, and glucose oxidase. C6-AHB-induced conformational alterations in protein macromolecules were due to the formation of complexes, as evidenced by differences in the fluorescence spectra of individual RNase and C6-AHB and their mixtures and in the surface tension isotherms of C6-AHB and trypsin solutions. Data on the involvement of dormancy auto-inducers in the post-translational modification of enzymes and their inhibition will provide further insight into the mechanisms of development and maintenance of dormant microbial forms.     

The effects of alkylhydroxybenzenes on homoserine lactone-induced manifestations of quorum sensing in bacteria

The effects of four alkylhydroxybenzene (AHB) homologs with different hydrocarbon chain lengths on the synthesis of violacein pigment induced by C₆-homoserine lactone (HSL) and biofilm formation by Chromobacterium violaceum NCTC 13274 and on Escherichia coli pAL103 bioluminescence in the presence of C₆-oxo-HSL were studied. Alkylhydroxybenzenes inhibit the growth of C. violaceum increased in the C₅-AHB → C₁₂-AHB series in the absence of this activity in C₁-AHB. Subinhibitory AHB concentrations reduced violacein production and suppressed biofilm formation. These effects were presented as individual and group regression dependencies between the analysed parameters. Using the bioluminescent model, the regulatory effects of AHBs were not associated with their direct competition with HSL and that they develop as a result of changes in the sensitivity of bacterial cells to the respective quorum sensing inducer.     

Effect of alkylhydroxybenzenes,microbial anabiosis inducers,on the structural organization of <Emphasis Type="Italic">Pseudomonas aurantiaca</Emphasis> DNA and on the induction of phenotypic dissociation

We revealed a relationship between alkylhydroxybenzene (AHB)-induced changes in the structural organization of supramolecular complexes (SC) of the DNA of Pseudomonas aurantiaca and the phenotypic dissociation of this bacterium. The addition of 0.1–0.3 mM hexylresorcinol (C₆-AHB), a chemical analogue of microbial anabiosis autoinducers, caused the formation of cystlike refractile cells (CRC) in these gram-negative, nonsporulating bacteria. Inoculating pseudomonad CRC on solid nutrient media resulted in phenotypic dissociation of the microbial population that yielded several variants with different colony structure and morphology. This manifested itself in the conversion of the original S-colony-forming phenotype into the R form and in the formation of less pigmented colonies. These transitions were possibly linked to AHB-induced structural changes in the DNA. In vitro studies revealed that AHB could interact with DNA SC, resulting in their structural modification that manifested itself in changes in their viscoelasticity. DNA supramolecular complexes isolated from proliferating, stationary-phase, and anabiotic P. aurantiaca cells differed in their viscoelasticity and capacity to interact with AHB homologues with different hydrophobicity, such as hexylresorcinol and methylresorcinol (C₁-AHB). The DNA SC from actively proliferating cells were characterized by smaller viscoelasticity compared with those from stationary-phase and anabiotic cells, due to the difference in the DNA superspiralization degree and the physiological age of the bacteria involved. C₆-AHB produced a pronounced relaxing effect on the DNA SC from exponential-phase P. aurantiaca cells. The less hydrophobic C₁-AHB produced a similar relaxing effect on the DNA SC from stationary-phase cells. The curve of the dose-effect dependence of C₆-AHB had a breaking point within the submillimolar (10^–4 M) concentration range. These concentrations induce the formation of cystlike anabiotic pseudomonad cells that are characterized by an unstable phenotype and dissociate into distinct variants upon inoculation on solid media.__________Translated from Mikrobiologiya, Vol. 74, No. 2, 2005, pp. 157–165.Original Russian Text Copyright © 2005 by Mulyukin, Vakhrushev, Strazhevskaya, Shmyrina, Zhdanov, Suzina, Duda, Kozlova, El-Registan.     

Regulation of phase variation in type I pili formation in <Emphasis Type="Italic">Escherichia coli</Emphasis>: Role of alkylresorcinols,microbial autoregulators

Formation of virulence-associated type I pili in Escherichia coli should be considered as one of the most efficient models for investigating the mechanisms of regulating the heterogeneity of populations of genetically identical microbial cells. The present work focused on the role of alkylhydroxybenzenes (AHBs), density-dependent intercellular regulators, in controlling phase variations in type I pili formation (fimbriogenesis). The tested AHB homologue was C12-AHB; a genetically constructed strain E. сoli dsp250 containing the fimA-lacZ hybrid operon was used. In this operon, the fimA gene encodes the main subunit of the pili protein, and its expression results in β-galactosidase synthesis; pili-forming cells, therefore, become blue on the medium with the Х-gal substrate. Expression of fimA depends on the inversion of the fimS region that is located upstream of it. If the inversion is on, pili formation takes place, if it is off, no pili are formed. An increase in C12-AHB concentration (within the 5 × 10^–5–2 × 10^–4 M range) in the exponential-phase culture of strain dsp250 causes a dose-dependent change in the dominant phenotype that is displayed by up to 98–99% of the cells. Cells with this phenotype form colonies with a blue center and white edges. Up to 60% of the cells with this phenotype assume a metastable state and up to 11% and 44% of them transition to the alternative phenotypes of pili-forming and pili-less cells, respectively. The influence of C12-AHB on off-switching, i.e. the formation of the avirulent phenotype, was observed irrespective of the growth conditions of strain dsp250. Addition of glucose to the LB medium (5 or 10 mg/mL) resulted in catabolic repression via regulation by the cAMP-CNR complex and predictably induced pili formation in 49 and 75% of the cells, respectively. Against this background, C12-AHB caused a dose-dependent decrease in the share of pili-forming cells to 33–61% and an increase in the share of pili-less cells to 32–61%. If glucose was added in excess (2.5, 5 or 10 mg/mL) to the diluted LB/2 medium, pili formation was completely repressed, while C12-AHB still induced the off inversion to the pili-less phenotype in up to 30% of the cells. The conclusion can be drawn that C12-AHB is not involved in the pathway of fimbriogenesis regulation via cAMP. Since C12-AHB functions as an extracellular alarmon (activating the rpoS regulon and the SOS response as shown earlier, see Golod et al., 2009), its mechanism of action apparently involves stress signal transduction. It induces the synthesis of global regulators RpoS and H-NS and of intracellular alarmon (p) ppGpp; these factors are responsible for the on → off inversion and the proliferation of pili-less cells.     

Protection of Saccharomyces cerevisiae against oxidative and radiation-caused damage by alkyl hydroxybenzenes

The effects of C7-alkylhydroxybenzene (C7-AHB) and p-hydroxyethylphenol (tyrosol), chemical analogs of microbial anabiosis autoregulators, on the viability of yeast cells under oxidative stress were investigated. The stress was caused by reactive oxygen species (ROS) produced under gamma irradiation of cell suspensions using doses of 10-150 krad at an intensity of 194 rad/s or by singlet oxygen generated in cells photosensibilized with chlorin e6 (10 micrograms/l). C7-AHB was found to exert a protective effect. The addition of 0.05-0.16 vol% of C7-AHB to cell suspensions 30 min before irradiation protected yeast cells from gamma radiation (50 krad). The protective effect of C7-AHB manifested itself both in the preservation of cell viability during irradiation and in the recovery of their capacity to proliferate after irradiation. In our studies on photodynamic cell inactivation, the fact that the phenolic antioxidant C7-AHB protects cells from intracellular singlet oxygen was revealed for the first time. The analysis of difference absorption spectra of oxidized derivatives of C7-AHB demonstrated that the protective mechanism of C7-AHB involves the scavenging of ROS resulting from oxidative stress. The fact that tyrosol failed to perform a photoprotective function suggests that the antioxidant properties of microbial C7-AHB are not related to their chaperon functions. The results obtained make an important addition to the spectrum of known antioxidant and antistress effects of phenolic compounds.     

The role of alkylhydroxybenzenes in the adaptation of <Emphasis Type="Italic">Micrococcus luteus</Emphasis> to heat shock

The response of the gram-positive bacterium micrococcus luteus to heat shock (4°C, 15 min) and the adaptogenic activity of alkylhydroxybenzenes (AHBs), which are extracellular growth-regulating substances of these bacteria, were studied. The perception of stress and the postshock behavior of M. luteus cells proved to depend on the growth phase and medium. The magnitude of the stress response was more pronounced in cultures grown on synthetic medium than in cultures grown on rich medium (nutrient broth). During exponential or linear growth, the cells were more sensitive to the temperature effect than during decelerated growth. In linearly growing m. luteus cultures, the amount of total intra- and extracellular alkylhydroxybenzenes, the anabiosis inducers, increased in response to heat shock. AHB redistribution between cells and culture liquid occurred in the course of stress and after stress. In micrococci exposed to heat shock, an increase in the AHB concentration both in cells and in culture liquid is likely a defense reaction of stress resistance. This conclusion was confirmed in experiments with the addition 30 min before the heat shock of a chemical analogue of the anabiosis inducer, C₇-AHB (12 mM), which protected M. luteus cells so that their intense growth was observed after shock without any lag. The protective effect of AHBs is a result of their ability to form complexes with enzyme macromolecules and stabilize them. The data obtained extend the knowledge of the stress-protective functions of low-molecular-weight autoregulators and of the role of intercellular communications in the stress response of bacterial cultures.Translated from Mikrobiologiya, Vol. 74, No. 1, 2005, pp. 26–33.Original Russian Text Copyright © 2005 by Stepanenko, Mulyukin, Kozlova, Nikolaev, El-Registan.     

Growth and morphological changes induced by lithium chloride treatment of HL-60 cells

HL-60 cells were grown in culture and their proliferative behaviour and response to lithium were studied. Treatment of cells with lithium concentrations of up to 5 mM enhanced cell proliferation, however above 5 mM lithium, cell growth was inhibited. Cell viability remained above 90% with concentrations of lithium below 10 mM. With increasing concentrations of lithium cell death increased rapidly to about 70% after 3 days at 50 mM. DNA synthesis was also strongly inhibited by concentrations of lithium above 5 mM. At 50 mM lithium, [3H]-thymidine incorporation was 1%. Electron microscopy seems to indicate that the plasma membrane is the main target for lithium cytotoxicity, whilst lithium uptake studies suggest that cytotoxicity might be related to the accumulation of lithium within the cells.     

The role of microbial dormancy autoinducers in metabolism blockade

Alkyl-substituted hydroxybenzenes (AHBs), which are autoinducers of microbial dormancy (d ₁ factors), were found to stabilize the structure of protein macromolecules and modify the catalytic activity of enzymes. In vitro experiments showed that C₆-AHB at concentrations from 10⁻⁴ to 10⁻² M, at which it occurs in the medium as a true solution and a micellar colloid, respectively, nonspecifically inhibited the activity of chymotrypsin, RNase, invertase, and glucose oxidase. C⁶-AHB-induced conformational alterations in protein macromolecules were due to the formation of complexes, as evidenced by differences in the fluorescence spectra of individual RNase and C₆-AHB and their mixtures and in the surface tension isotherms of C₆-AHB and trypsin solutions. Data on the involvement of dormancy autoinducers in the posttranslational modification of enzymes and their inhibition will provide further insight into the mechanisms of development and maintenance of dormant microbial forms.     

Kinetic studies and unstructured models of lymphocyte metabolism in fed-batch culture

The growth of two lymphocyte cell lines, a hybridoma cell line and a human cutaneous T cell lymphoma (HuT78), was studied in fed-batch culture, and unstructured models of growth developed. A criteria was established to insure that the growth rate varied by less than a specified tolerance throughout the culture period. Glutamine and serum were growth-limiting nutrients for both cell lines with half-maximal growth rates at 0. 53 mM glutamine and 0. 55%(v/v) serum for the hybridoma cells and 0. 21 mM glutamine and 1. 5% serum for the HuT-78 cells. Over the range of glucose concentrations from 5. 5 mM to 28 mM, the specific growth rate of hybridoma cells was independent of glucose concentration, whereas glucose concentrations above 5. 5 mM inhibited HuT-78 growth. For both cell lines, the growth rate was significantly inhibited by the addition of ammonium, although the hybridoma cell line was more affected by ammonia than was the HuT-78 cell line. Growth of HuT-78 cells increased in the presence of interleukin-2. Unstructured models for the hybridoma cells were similar to other models presented in the literature. Applications of these models to adoptive immunotherapy are discussed.     

Adaptation of Chinese hamster ovary cells to high potassium ion-containing medium for enhancement of follicle-stimulating hormone production

In this study, a suspension culture of recombinant Chinese hamster ovary (CHO) cells producing follicle-stimulating hormone (FSH) was used to investigate the effects of potassium ion (K⁺) on cell growth and FSH production. Cell growth was significantly suppressed at a K⁺ concentration higher than 60 mM, but specific FSH productivity (q _FSH) was enhanced more than 2-fold compared to the value obtained at 4 mM K⁺. In an attempt to alleviate the cell growth suppression at a high K⁺ concentration, the cells were adapted at 60 mM K⁺ in a repeated batch mode. During adaptation, the growth rate increased from 0.010 to 0.020 h⁻¹, andq _FSH also gradually increased and reached 11.1 ng/(10⁶ cells h), which was even higher than that of the unadapted cells at 60 mM K⁺. The adapted cells showed a 2.6-fold increase in maximum FSH titer at 80 mM K⁺ compared to the unadapted cells at 4 mM K⁺. Taken together, these results demonstrate the potential of using culture media containing cells adapted to high K⁺ concentrations, for the enhancement of recombinant protein production.     

Regulation of the functional activity of lysozyme by alkylhydroxybenzenes

In our study, we investigated the capacity of alkylhydroxybenzenes (AHB), which are microbial anabiosis autoinducers, for alteration of the enzymatic activity of the hen egg-white lysozyme, as well as the efficiency of hydrolysis of specific (peptidoglycan) and nonspecific (chitin) substrates catalyzed by lysozyme. AHB homologues (C7-AHB and C12-AHB), which differ in their hydrophobicity and effects in their interaction with lysozyme, were used as modifying agents. C7-AHB stimulated enzymatic activity within the whole range of concentrations used (10^?7?10^?3 M). More hydrophobic C12-AHB exhibited this ability only at low concentrations and inhibited fermentative activity at high concentrations, acting as a mixed-type inhibitor. Both AHB homologues caused changes in the hydrophobicity of lysozyme molecules. An increase in the affinity level between the C7-AHB-modified enzyme and the nonspecific substrate (colloidal chitin or cell wall polymers of Saccharomyces sp.) was observed, which manifested itself in the enhancement of the hydrolysis rate by 200–500% (as compared to the native enzyme). A significant effect on the efficiency of the lysozyme-catalyzed modifications of the substrate (peptidoglycan, colloidal chitin) structure as a result of its complexation with AHB was demonstrated. A stabilizing effect of C7-AHB and C12-AHB was revealed, which ensured a high level of activity of the AHB-modified enzyme (as compared to the control) after heat treatment (functional stability), as well as at nonoptimal temperatures of catalysis (operational stability). The biological significance of lysozyme modification with AHB and the practical aspects of its application are discussed.     

The adhesion of protein A-bearing Staphylococcus aureus organisms to soluble-staphylococcal-antigens-coated HeLa cells mediated by specific antibodies

The adhesion of staphylococcal protein A (SpA)-bearing Staphylococcus aureus Cowan I organisms to HeLa cells was enhanced by pretreatment of HeLa cells with staphylococcal extracellular antigens and antibodies to them. The adhesion of HLj, an SpA-poor mutant derived from Cowan I, to HeLa cells was not enhanced by the same pretreatment of HeLa cells. Furthermore, the enhanced staphylococcal adhesion was inhibited by soluble SpA. The antigen(s) responsible for the enhanced staphylococcal adhesion was(were) heat stable. Pretreatment of HeLa cells with the mixture of staphylococcal extracellular antigens and antibodies to them also enhanced the adhesion of Cowan I. Similarly the adhesion of Cowan I was enhanced by pretreatment of HeLa cells with extracellular antigens of Pseudomonas aeruginosa and antibodies to them. These results indicated that cell-bound SpA mediated the binding of S. aureus to immune complexes composed of extracellular bacterial products and antibodies to them bound to the surface of HeLa cells, and suggested another role of cell-bound SpA as a co-adhesin with other factors in infections due to S. aureus.