The enhancement of humoral and cellular immune responses by dimethyldioctadecylammonium bromide

Dimethyldioctadecylammonium bromide (DDA) produced marked enhancement of both cellular and humoral immune responses to SRBC when administered to mice intraperitoneally, or of cellular immunity when given subcutaneously. Stimulated cellular responses were seen as increased footpad swelling as a measure of delayed hypersensitivity and increased antigen-induced blastogenesis. Elevation of humoral response was reflected in increased numbers of splenic plaque-forming cells (PFC) and in circulating anti-SRBC antibody. Adjuvancy did not depend on addition of the lipid of DDA to antigen, as both humoral and cellular responses were enhanced whether DDA and SRBC were admixed or injected separately 4 hr apart intraperitoneally. DDA also enhanced the PFC response to the T-cell independent antigen TNP-LPS. The DDA effects are accompanied by macrophage activation, which may mediate at least in part the observed responses. DDA-activated macrophages exhibit fast spreading, are highly phagocytic, and elaborate significantly greater amounts of thymocyte mitogenic factor(s) than do normal resident peritoneal macrophages. This activation may effect the stimulation of antigen-specific primary lymphocyte responses by adjuvant and expansion of memory-cell populations which lead to the observed enhancement of secondary responses.     

Protective antiviral immune responses to pseudorabies virus induced by DNA vaccination using dimethyldioctadecylammonium bromide as an adjuvant

To enhance the efficacy of a DNA vaccine against pseudorabies virus (PRV), we evaluated the adjuvant properties of plasmids coding for gamma interferon or interleukin-12, of CpG immunostimulatory motifs, and of the conventional adjuvants dimethyldioctadecylammonium bromide in water (DDA) and sulfolipo-cyclodextrin in squalene in water. We demonstrate that a DNA vaccine combined with DDA, but not with the other adjuvants, induced significantly stronger immune responses than plasmid vaccination alone. Moreover, pigs vaccinated in the presence of DDA were protected against clinical disease and shed significantly less PRV after challenge infection. This is the first study to demonstrate that DDA, a conventional adjuvant, enhances DNA vaccine-induced antiviral immunity.     

Effects of ethidium bromide on mitosis and chromosomes: a possible material basis for chromosome stickiness

When two types of mammalian cells were treated with ethidium bromide for several hours, the mitotic figures showed no chromatid breaks or exchanges but a high incidence of sticky chromosomes. Electron microscopic examinations revealed that many chromosomes are connected by submicroscopic chromatin strands of various widths. Chromosome stickiness, therefore, is interpreted as entanglement of chromatin fibers between unrelated chromosomes, probably caused by abnormal condensation behaviors prior to mitosis. Presumably, chromatin breaks would occur when sticky chromosomes separate during anaphase. Such microscopically undetectable breaks expressed as various kinds of chromosomal aberrations in the next mitosis when the damaged cells were permitted to recover in the absence of ethidium bromide.     

C-reactive protein functions as a negative regulator of macrophage activation induced by apoptotic DNA

C-reactive protein (CRP), an acute-phase protein with an ability to bind to nuclear antigen, has been reported to regulate cytokine secretion and modulate immune responses. We previously reported that activated syngeneic lymphocyte-derived apoptotic DNA (apopDNA) could induce macrophage activation and contribute to the initiation and progression of lupus nephritis. It is reasonable to hypothesize that CRP might regulate apopDNA-induced macrophage activation. Herein, CRP was shown to promote macrophage-mediated apopDNA uptake by binding to apopDNA (CRP/apopDNA complex). Notably, CRP/apopDNA treatment inhibited the production of inflammatory cytokines and chemokines by macrophages which could be induced by apopDNA alone. Further coculture and transwell studies revealed that CRP/apopDNA-induced macrophages prohibited apopDNA-induced macrophage activation in an IL-10 dependent manner. These results provide insight into the potential mechanism of CRP regulatory activity in macrophage activation induced by apopDNA in the context of lupus nephritis and other autoimmune diseases.     

Endogenous genotoxic agents and processes as a basis of spontaneous carcinogenesis

A list of endogenous DNA-damaging agents and processes is given. Endogenous electrophiles are found with the cosubstrates of physiological transfer reactions (S-adenosylmethionine for methylation, ATP for phosphorylation, NAD+ for ADP-ribosylation, acetyl CoA for acetylation). Aldehyde groups (glyceraldehyde-3-phosphate, formaldehyde, open forms of reducing sugars, degradation products of peroxidation) or alkylating degradation products derived from endogenous nitroso compounds represent additional possibilities. Radical-forming reactions include leakage of the superoxide anion radical from terminal cytochromes and redox cycles, hydroxyl radical formation by the Fenton reaction from endogenous hydrogen peroxide, and the formation of lipid peroxides. Genetic instability by spontaneous deaminations and depurinations as well as replicative instability by tautomer errors and in the presence of mutagenic metal ions represent a third important class of endogenous genotoxic processes. The postulated endogenous genotoxicity could form the mechanistic basis for what is called 'spontaneous' tumor incidence and explain the possibility of an increased tumor incidence after treatment of animals with non-genotoxic compounds exhibiting tumor-promoting activity only. Individual differences are expected to be seen also with endogenous DNA damage. The presence of endogenous DNA damage implies that exogenous DNA-carcinogen adducts give rise to an incremental damage which is expected to be proportional to the carcinogen dose at lowest levels. An increased tumor risk due to exposure to exogenous genotoxic carcinogens could therefore be assessed in terms of the background DNA damage, for instance in multiples of the mean level or of the interindividual variability in a population.     

High-temperature deep-subsurface microbial communities as a possible equivalent of ancient ecosystems

Microbiological, molecular biological, and radioisotopic studies suggest that active and complex microbial communities exist in the deep layers of the subsurface biosphere. This review discusses only one group of such communities, i.e., those developing at high (above 60°C temperatures). Oil wells, subsurface water reservoirs (e.g., the Great Artesian Basin in Australia), deep mines (in South Africa), and high-temperature horizons below the seafloor in the areas of underwater volcanic activity contain the best-studied high-temperature subsurface ecosystems. These microbial communities differ considerably from one another in biodiversity, initial energy substrate, and major microbiological processes. However, before they can be considered as equivalents of the Earth’s primordial ecosystems, it is necessary to demonstrate that they are energetically independent of the modern biosphere.     

Induction by immunomodulatory agents of a macrophage antigen recognized by monoclonal antibody 158.2 and correlation with macrophage function

MA158.2, a rat monoclonal antibody with binding specificity for cells of the monocyte-macrophage lineage, reacts with an antigen (158.2) whose expression is enhanced on mononuclear cells activated to the tumoricidal phenotype by treatment with lymphokine supernatant containing macrophage activating factor (MAF). The functional relevance of enhanced expression of this antigen has been examined in mouse peritoneal macrophages treated with a variety of immunomodulatory agents and assayed for augmented macrophage-mediated defense reactions, including O-2 production, microbicidal, and tumoricidal activity. An interferon-gamma (IFN-gamma) preparation produced by recombinant DNA technology induced a dose-dependent increase in expression of the 158.2 antigen in inflammatory macrophages which was accompanied by acquisition of microbicidal activity against Listeria monocytogenes. However, these cells did not express tumoricidal activity and induction of this property required concomitant exposure to lipopolysaccharide (LPS). Similar results were obtained using macrophages elicited with pyran copolymer. Exposure to LPS alone induced enhanced expression of antigen 158.2 but did not elicit microbicidal activity. Macrophages challenged with IFN-alpha, IFN-beta, MDP, and bestatin did not exhibit increased 158.2 and also failed to acquire tumoricidal activity when treated concomitantly with LPS. Collectively, these data indicate that the MA 158.2 antibody recognizes an antigen expressed by macrophage populations displaying the so-called primed phenotype in which microbicidal activity is expressed but in which induction of tumoricidal activity requires the addition of a second signal such as LPS.     

Use of diazido ethidium bromide as a specific probe for mitochondrial functions.

The diazido derivative of ethidium bromide has been synthesized as a potential photoaffinity label and shown to be at least as effective as a mitochondrial mutagen as the parent compound, with a similar mode of action. Exposure of mitochondria of Saccharomyces cerevisiae to the compound, followed by ultraviolet-irradiation, which converts it to the highly reactive dinitrene, results in its specific binding to a single component which has been tentatively identified as the smallest polypeptide (subunit 9) of the membrane-bound ATPase. An analogus reaction is also obtained with the soluble, oligomycin-sensitive ATPase complex but not with the F1-ATPase itself. The reaction with the ATPase complex can also be monitored by fluorescence enhancement and by this attribute, as well as by other criteria, diazido-ethidium bromide, ethidium bromide itself, euflavine, N,N'-dicyclohexylcarbodiimide, 2,4-dinitrophenol, and 2-azido-4-nitrophenol all appear to compete for the same, lipophilic, binding site. A mitochondrial mutation (73/1) (see Flury, U., Feldman, F., and Mahler, H.R. (1974) J. Biol. Chem. 249, 6630-6637) produces a photoaffinity product with an altered electrophoretic mobility and molecular weight.     

Stabilization of enzymes by dormancy autoinducers as a possible mechanism of resistance of resting microbial forms

Alkyl-substituted hydroxybenzenes (AHBs), autoinducers of microbial dormancy (ord ₁ factors), were found to stabilize the structure of protein macromolecules, making them metabolically less active and more resistant to stresses. In vitro experiments with theBacillus intermedius ribonuclease and chymotrypsin showed that the degree of the physical and chemical stability of these enzymes treated with AHBs depends on their concentration and incubation time. Experiments with RNase, which is capable of refolding, i.e., renaturation after heat denaturation, revealed that AHBs efficiently interact with both intact and denatured proteins. The data obtained allow the inference to be made thatd ₁ factors may play the role of natural chemical chaperons, blocking metabolism in dormant cells through the formation of catalytically inactive thermostable complexes with enzymes.     

Stabilization of enzymes by anabiosis autoinducers as a possible mechanism of resistance of resting microbial forms

Alkyl-substituted hydroxybenzenes (AHBs), auto-inducers of microbial dormancy (or d1 factors), were found to stabilize the structure of protein macromolecules, making them metabolically less active and more resistant to stresses. In vitro experiments with the Bacillus intermedius ribonuclease and chymotrypsin showed that the degree of the physical and chemical stability of these enzymes treated with AHBs depends on their concentration and incubation time. Experiments with RNase, which is capable of refolding, i.e., renaturation after heat denaturation, revealed that AHBs efficiently interact with both intact and denatured proteins. The data obtained allow the inference to be made that d1 factors may play the role of natural chemical chaperons, blocking metabolism in dormant cells through the formation of catalytically inactive thermostable complexes with enzymes.     

Binase and other microbial RNases as potential anticancer agents

Some RNases possess preferential cytotoxicity against malignant cells. The best known of these RNases, onconase, was isolated from frog oocytes and is in clinical trials as anticancer therapy. Here we propose an alternative platform for anticancer therapy based on T1 RNases of microbial origin, in particular binase from Bacillus intermedius and RNase Sa from Streptomyces aureofaciens. We discuss their advantages and the most promising directions of research for their potential clinical applications.     

Impaired nucleotide excision repair pathway as a possible factor in pathogenesis of head and neck cancer

Tobacco smoking is one of the major risk factors in pathogenesis of head and neck squamous cell carcinomas (HNSCC). Many of the chemical compounds present in tobacco are well-known carcinogens which form adducts with DNA. Cells remove these adducts mainly by the nucleotide excision repair pathway (NER). NER also eliminates a broad spectrum of pyrimidine dimers (CPD) and photo-products (6-4PP) induced by UV-radiation or DNA cross-links after cisplatin anti-cancer treatment. In this study DNA damage and repair was examined in peripheral blood lymphocytes obtained from 20 HNSCC patients and 20 healthy controls as well as HTB-43 larynx and SSC-25 tongue cancer cell lines. DNA repair kinetics in the examined cells after cisplatin or UV-radiation treatment were investigated using alkaline comet assay during 240min of post-treatment incubation. MTT assay was used to analyse cell viability and the Annexin V-FITC kit specific for kinase-3 was employed to determine apoptosis after treating the cells with UV-radiation at dose range from 0.5 to 60J/m(2). NER capability was assessed in vitro with cell extracts by the use of a bacterial plasmid irradiated with UV-light as a substrate for the repair. The results show that lymphocytes from HNSCC patients and HTB-43 or SSC-25 cancer cells were more sensitive to genotoxic treatment with UV-radiation and displayed impaired DNA repair. Also evidenced was a higher rate of apoptosis induction after UV-radiation treatment of lymphocytes from the HNSCC patients and the HTB-43 cancer cells than after treatment of those from healthy donors. Finally, our results showed that there was a significant decrease in NER capacity in HTB-43 or SSC-25 cancer cells as well as in peripheral blood lymphocytes of HNSCC patients compared to controls. In conclusion, we suggest that the impaired NER pathway might be a critical factor in pathogenesis of head and neck cancer.     

A new approach for the immobilization of permeabilized brewer's yeast cells in a modified composite polyvinyl alcohol lens-shaped capsule containing montmorillonite and dimethyldioctadecylammonium bromide for use as a biocatalyst

Permeabilized brewer's yeast cells were immobilized in modified composite polyvinyl alcohol lens-shaped capsules containing montmorillonite (MONT) and dimethyldioctadecylammonium bromide (DDAB). The special properties of the capsules were then investigated. The results showed that the diffusion capability of hydrophobic molecules from bulk solution into the capsules was obviously improved by the introduction of 0.5% MONT and 0.05% DDAB into the 15% PVA matrix. More importantly, when ethyl 4-chloro-3-oxobutanoate (COBE) was reduced with the capsules as the biocatalyst, the yield and enantiomeric excess (ee) of the product reached 88% and 99.1%, respectively, within 8 h, which are significantly higher totals than those mediated by the unmodified PVA capsules under the same conditions. The intracellular alcohol dehydrogenase (ADH) in the capsules retained over 81% of its original activity after 1 month of storage and 88% of its initial activity after 20 cycles of reaction.     

Reductive microbial dissolution of manganese nodules as a possible hazard of deep-sea mining

The microbial lysis of deep-sea nodules as a possible result of large-scale, deep-sea mining is considered. It is assumed that the Mn (IV) and Fe (III) compounds of the manganese nodules are reduced by the numerous aerobic bacteria at the sediment/water interface as soon as the adjacent nodule area is buried by sedimentation of the disturbed deposits and the organic-rich debris from the blooming surface plankton. Intensive mineralization processes in the resettled sediments cause oxygen depletion. Subsequently, the aerobic (and anaerobic) microorganisms will switch to Mn (IV) and Fe (III) oxides as alternative electron acceptors in order to continue their energy-conserving (ATP synthesis) reactions (anaerobic respiration). The higher the amount of decomposable organic matter, the more intensive are these processes. Consequently, buried manganese nodules may be dissolved, thereby liberating mobile Mn (II), Fe (II) and several trace elements (Ni, Cu, Co and others). This possible hazard and its ecological consequences should be evaluated carefully before deep-sea mining is started on a large scale.     

Negative co-operativity in clustered receptors as a possible basis for membrane action

A model for the interaction of a membrane receptor with a stimulating ligand is presented. It is assumed that (a) the receptor macromolecules are embedded in the membrane as a close packed two-dimensional cluster and (b) strong negative co-operative interaction occurs among the receptor molecules. The model explains the existence of (a) strong membrane stimulation by fractional ligand occupancy of the receptor; (b) the absence of positively co-operative binding curves for ligand to membrane receptors and (c) it provides a molecular explanation for the existence of “spare receptor”.