Rhodococcus rhodochrous IEGM 1360, an Effective Biocatalyst of C3 Oxidative Transformation of Oleanane Triterpenoids.

The optimal conditions for C3 oxidative biotransformation of 1.0 g/L pentacyclic triterpenoids oleanolic (OA) and glycyrrhetinic (GA) acids were determined using the resting cells of Rhodococcus rhodochrous IEGM 1360 from the Regional Specialised Collection of Alkanotrophic Microorganisms. Resting cell suspensions (OD600 2.6, pH 8.0, and OD600 2.2, pH 6.0) showed the highest catalytic activity against OA and GA, resulting in the formation of 61 and 100% of their 3-oxo derivatives, respectively. Using phase contrast, atomic force, and confocal laser scanning microscopy, an adaptive response of rhodococci to the effects of OA and GA was revealed. In silico, the apoptotic activity of 3-oxo-OA and antioxidant activity of 3-oxo-GA have been assumed. In vitro, a pronounced antibacterial activity of 3-oxo-OA against Micrococcus luteus, Escherichia coli, Staphylococcus aureus, and Bacillus subtilis was shown. The absence of toxic effects of the above triterpenoids and their 3-oxo derivatives on aquatic objects and plants was demonstrated in silico and in vitro, respectively. Supplementary Information: The online version contains supplementary material available at 10.1134/S0026261722603360.

[Synthesis and biological activity of 2,3-secotriterpene acid mono- and diamides].

Four types of amide (C3; C28; C3-C28) conjugates based on 2,3-seco-18alphaH-oleanane and 2,3-secolupane mono- and dicarboxylic acids were synthesized. The range of diamide derivatives was supplemented with C3-C3' and C28-C28' dicondensed amides with two A-secotriterpene backbones educed by reacting monocarboxylic A-secoacids with biogenic amino acid lysine. Compounds with inhibitory action against herpes virus reproduction (EC50 8.7 and 4.1 McM) were found among the synthesized mono- and diamide derivatives containing an ethyl-beta-alaninate fragment. It has been ascertained that diamide with ethyl-beta-alaninate fragment combines anti-herpes virus properties and anti-HIV activity (EC50 5.1 McM). For active compounds, the maximum non-toxic concentration (MNTC)/EC50 ratios ranges from 9.7 to 40.8. The synthesized amide conjugates do not exhibit any marked cytotoxic effects against human tumor cell lines rabdomiosarcoma RD TE32, A549 lung carcinoma and melanoma MS.

[Ionic conjugates of sulfate carboxymethyl cellulose with dialkylaminomethyl derivatives of 2-isobornyl-4-methylphenol: synthesis and study of anti-inflammatory and analgesic activity].

Water-soluble sulfate polysalts of carboxymethyl cellulose and tertiary aminomethyl derivatives of 2-isobornyl-4-methylphenol was obtained. For the synthesized conjugates investigated in vivo anti-inflammatory activity in the test of acute formalin inflammation and analgesic activity in tests the "hot plate" and "vinegar cramps".

[Biocatalytic synthesis of pharmacology perspective stigmast-4-en-3-one using Rhodococci cells].

The conditions for a directed biocatalytic oxidation of beta-sitosterol to a pharmacologically promising stigmast-4-en-3-one using Rhodococcus actinobacteria were selected. It was shown that palmitic acid induced the cholesterol oxidase reaction and allowed for the decrease in the bioconversion process duration from 7 to 5 days. The maximum level ofstigmast-4-ene-3-one formation was achieved using n-hexadecane as an additional growth substrate. With increased concentrations of beta-sitosterol (up to 2 g/L) an effective target product formation (80%) was achieved in the presence of Tween-80 and beta-cyclodextrine. R. erythropolis strains were 1.5-2 times more active than R. ruber strains in catalyzing the beta-sitosterol biotransformation process.

[Antiviral activity of 2,3-secotriterpenic hydrazones of lupane and 19beta,28-epoxy-18alpha-oleanane type].

Novel hydrazones of lupane and 19beta,28-epoxy-18alpha-oleanane type have been synthesized via interaction of 2,3-secotriterpenic aldehydonitriles with substituted hydrazines. As a result of investigation of 2,3-secotriterpenic hydrazones antiviral activity to the strain "Indiana" of vesicular stomatitis virus on two models of mammal's line cell infection, acetylhydrazone 1-cyano-2,3-seco-19beta,28-epoxy-18alpha-olean-3-al has been found to have a high prophylactic activity 0.00016 microg/ml to vesicular stomatitis virus and to inhibit a virus reproduction in primarily infected cells in 0.21 microg/ml concentration.

[The synthesis of triterpenic amides based on 2,3-seco-1-cyano-19beta,28-epoxy-18alpha-olean-3-oic acid].

Novel 2,3-seco-triterpenic amides were prepared by the interaction of the chloride of 2,3-seco-l-cyano-19beta,28-epoxy-18alpha-oleane-3-oic acid with primary amines and synthetic and biogenic amino acids. A cytotoxic triterpenic conjugate with a residue of the ethyl ester of beta-alanine was found among the synthesized nitrogen-containing derivatives. Treatment with this conjugate in a concentration of 100 muM resulted in the 45.5% survival of melanoma cells in the medium.

[The immunotropic activity of lupane and oleanane 2,3-seco-triterpenoids].

The immunotropic effect of the 2,3-seco derivatives of allobetulon, betulonic acid, and the methyl ester of betulonic acid were studied. It was found that the highest activity is shown by compounds with an oleanane fragment. The presence of a free C28-carboxyl group enhances the activity of lupeolic 2,3-seco derivatives. A significant contribution to the development of the immune response is introduced by a functional group at the C3 atom in the A ring - the C3-carboxy derivatives intensify the processes of antibody production and alter the number and ratio of leukocyte forms. It is shown that 2,3-seco-1-cyano-19beta,28-epoxy-18alpha-olean-3-oic acid stimulates humoral immunity with a positive influence on hematopoiesis.

[Oxidative biotransformation of thioanisole by Rhodococcus rhodochrous IEGM 66 cells].

Comparative study of sulfoxidation activity of free and immobilized Rhodococcus rhodochrous IEGM 66 cells was performed. Free Rhodococcus cells (in the presence of 0.1 vol % n-hexadecane) displayed maximal oxidative activity towards thioanisole (0.5 g/l), a prochiral organic sulfide, added after 48-h cultivation of bacterial cells. Higher sulfide concentrations inhibited sulfoxidation activity of Rhodococcus. Use of immobilized cells allowed the 2-day preparatory stage to be omitted and a complete thioanisole bioconversion to be achieved in 24 h in the case that biocatalyst and 0.5 g/l thioanisole were added simultaneously. The biocatalyst immobilized on gel provides for complete thioanisole transformation into (S)-thioanisole sulfoxide (optical purity of 82.1%) at high (1.0-1.5 g/l) concentrations of sulfide substrate.

Mitochondrial DNA damage is involved in apoptosis caused by pro-inflammatory cytokines in human OA chondrocytes.

OBJECTIVE: Pro-inflammatory cytokines play a pivotal role in cartilage destruction during the progression of osteoarthritis (OA). Additionally, these cytokines are capable to generate reactive oxygen and nitrogen species within chondrocytes. Mitochondrion is a prime target of oxidative damage and an important player in aging and degenerative processes. The purpose of the present study was to investigate whether these cytokines will alter the mitochondrial DNA (mtDNA) integrity and mitochondrial function in both normal and osteoarthritic human chondrocytes. DESIGN: Primary normal and osteoarthritic human chondrocyte cultures were exposed to various concentrations of interleukin-1beta (IL-1beta) and tumor necrosis factor-alpha (TNF-alpha) for different time. Following exposure, chondrocytes were evaluated for mitochondrial DNA damage, ATP production, changes in mitochondrial transcription, and apoptosis. Adenoviral vectors were used to deliver DNA repair enzyme hOGG1 to mitochondria. RESULTS: Pro-inflammatory cytokines IL-1beta and TNF-alpha disturb mitochondrial function in human chondrocytes by inducing mitochondrial DNA damage, decreasing energy production and mitochondrial transcription, which correlated with the induction of apoptosis. Increased NO production was the key factor responsible for accumulation of mtDNA damage after cytokine exposure. Mitochondrial superoxide production was also enhanced following pro-inflammatory cytokine exposure. OA chondrocyte mitochondria were more susceptible to damage induced by pro-inflammatory cytokines then mitochondria from normal chondrocytes. Protection of human chondrocytes from mtDNA damage by the mitochondria-targeted DNA repair enzyme hOGG1 rescued mtDNA integrity, preserved ATP levels, reestablished mitochondrial transcription, and significantly diminished apoptosis following IL-1beta and TNF-alpha exposure. CONCLUSION: Mitochondrion is an important target in pro-inflammatory cytokine toxicity, maintaining of mitochondrial DNA integrity is necessary to prevent chondrocytes from apoptosis induced by IL-1beta and TNF-alpha.

Diminished mitochondrial DNA integrity and repair capacity in OA chondrocytes.

OBJECTIVES: Osteoarthritis (OA) is characterized by the failure of chondrocytes to respond to injury and perform the cartilage remodeling process. Human articular chondrocytes actively produce reactive oxygen and nitrogen species (ROS and RNS) capable of causing cellular dysfunction and death. A growing body of evidence indicates that mitochondrial dysfunction and mitochondrial DNA (mtDNA) damage play a causal role in disorders linked to excessive generation of oxygen free radicals. The aim of this study was to determine whether mtDNA damage was present in OA chondrocytes, and whether mtDNA repair capacity is compromised in OA chondrocytes following oxidative stress, leading to chondrocyte death. METHODS: Human articular cartilage was isolated from knee joints of cadavers available through the Anatomical Gifts Program at the University of South Alabama (normal donors) or OA patients undergoing total knee replacement surgeries (OA patients). Total DNA was isolated from either chondrocytes released following collagenase digestion, or from first passage chondrocytes grown in culture and exposed to ROS or RNS. mtDNA integrity and repair capacity were analyzed by quantitative Southern blot analysis, using a mtDNA-specific radioactive probe. Cell viability was determined by the trypan blue exclusion method. RESULTS: mtDNA damage was found in chondrocytes from OA patients compared to normal donors. It was accompanied with reduced mtDNA repair capacity, cell viability, and increased apoptosis in OA chondrocytes following exposure to ROS and RNS. CONCLUSIONS: These results indicate that mtDNA damage and poor mtDNA repair capacity for removing damage caused by oxidative stress may contribute to the pathogenesis of OA.

[Synthesis and immunotropic activity of methyl esters of 2-alkylaminomethylene-3-oxolup-20(29)-en-28-ic acids].

New lupane beta-enaminoketones were synthesized by interaction of methyl 2-hydroxymethylene-3-oxolup-20(29)-en-28-oate with aliphatic amines. Immunotropic activity was found for some of these compounds.

[Synthesis and immunotropic activity of 2-alkylaminomethylene-19beta,28-epoxyolean-3-ones].

2-Alkylaminomethylene-19beta,28-epoxyolean-3-ones were obtained by interaction of 2-hydroxymethylene-19beta,28-epoxyolean-3-one with aliphatic amines. Some of the resulting substances exhibit immunotropic activity.

[Bioconversion of beta-sitosterol and its complex esters by Rhodococcus actinobacteria].

The ability of pure cultures of Rhodococcus actinobacteria from the Ural specialized collection of alkanotrophic microorganisms (World Federation for Culture Collections accession number 768; http://www.ecology.psu.ru/iegmcol) to convert beta-sitosterol (BSS) and its 3beta-acylated derivatives was studied. Rhodococcus strains with pronounced cholesterol oxidase activity, capable of converting BSS to stigmat-4-ene-3-one in the reaction of cooxidation with n-hexadecane, were selected. The dependence of the activity of cholesterol oxidase of rhodococci on the length of the acyl group in BSS esters was studied. Conditions under which Rhodococcus cells convert BSS to 17beta-hydroxyandrost-4-ene-3-one (testosterone), commonly used in pharmacology, were determined.

Oxygen radical-induced mitochondrial DNA damage and repair in pulmonary vascular endothelial cell phenotypes.

Mitochondrial (mt) DNA is damaged by free radicals. Recent data also show that there are cell type-dependent differences in mtDNA repair capacity. In this study, we explored the effects of xanthine oxidase (XO), which generates superoxide anion directly, and menadione, which enhances superoxide production within mitochondria, on mtDNA in pulmonary arterial (PA), microvascular (MV), and pulmonary venous (PV) endothelial cells (ECs). Both XO and menadione damaged mtDNA in the EC phenotypes, with a rank order of sensitivity of (from most to least) PV > PA > MV for XO and MV = PV > PA for menadione. Dimethylthiourea and deferoxamine blunted menadione- and XO-induced mtDNA damage, thus supporting a role for the iron-catalyzed formation of hydroxyl radical. Damage to the nuclear vascular endothelial growth factor gene was not detected with either XO or menadione. PAECs and MVECs, but not PVECs, repaired XO-induced mtDNA damage quickly. Menadione-induced mtDNA damage was avidly repaired in MVECs and PVECs, whereas repair in PAECs was slower. Analysis of mtDNA lesions at nucleotide resolution showed that damage patterns were similar between EC phenotypes, but there were disparities between XO and menadione in terms of the specific nucleotides damaged. These findings indicate that mtDNA in lung vascular ECs is damaged by XO- and menadione-derived free radicals and suggest that mtDNA damage and repair capacities differ between EC phenotypes.

[Lipid peroxidation and function of some antioxidant enzyme systems in corn and oats in acute injury by hydrogen fluoride]. / Peroksidnoe okislenie lipidov i funktsionirovanie nekotorykh antiokislitel'nykh fermentnykh sistem u kukuruzy i ovsa pri ostrom porazhenii ftoristym vodorodom.

Experimental research showed the HF main harmful effect at the maximal exposure time (12 h). Intensity of chemiluminescence processes was enhanced almost in 1.5-fold. In the maize leaves the reduced chemiluminescence intensity was observed under the maximal toxicant concentration (1 mg/m3) effect, whereas the further growth of chemiluminescence intensity was observed in the oat plants. The total amount of the lipid peroxidation products was increased dependently on the toxicant concentration in all experimental variants. Changes in the studied enzymatic system activities were multidirected. Analysis of all activities dynamics for the SOD, GGTP, GST, GR and GP showed that GGTP and sometimes GP were involved more rapidly then SOD into the processes of detoxication of lipid peroxidation products and metabolites formed under the HF effect. However, the correlation between changes both in the SOD and GP activities failed to be found. The obtained data give a basis to conclude that during period between 8 and 12 h of HF exposure the essential changes in the activities of SOD and glutathione enzymatic systems took place as an adaptive response of plant cell to the investigated stress-factor impact.

Nitric oxide-induced damage to mtDNA and its subsequent repair.

Mutations in mitochondrial DNA (mtDNA) have recently been associated with a variety of human diseases. One potential DNA-damaging agent to which cells are continually exposed that could be responsible for some of these mutations is nitric oxide (NO). To date, little information has been forthcoming concerning the damage caused by this gas to mtDNA. Therefore, this study was designed to investigate damage to mtDNA induced by NO and to evaluate its subsequent repair. Normal human fibroblasts were exposed to NO produced by the rapid decomposition of 1-propanamine, 3-(2-hydroxy-2-nitroso-1-propylhydrazino) (PAPA NONOate) and the resultant damage to mtDNA was determined by quantitative Southern blot analysis. This gas was found to cause damage to mtDNA that was alkali-sensitive. Treatment of the DNA with uracil-DNA glycosylase or 3-methyladenine DNA glycosylase failed to reveal additional damage, indicating that most of the lesions produced were caused by the deamination of guanine to xanthine. Studies using ligation-mediated PCR supported this finding. When a 200 bp sequence of mtDNA from cells exposed to NO was analyzed, guanine was found to be the predominantly damaged base. However, there also was damage to specific adenines. No lesions were observed at pyrimidine sites. The nucleotide pattern of damage induced by NO was different from that produced by either a reactive oxygen species generator or the methylating chemical, methylnitrosourea. Most of the lesions produced by NO were repaired rapidly. However, there appeared to be a subset of lesions which were repaired either slowly or not at all by the mitochondria.

Molecular laser biotechnology.

Laser technology has developed to the point where it is possible to utilize lasers as a sophisticated but accessible tool in understanding and manipulating gene functioning. This review emphasizes some of the systems that employ lasers in the new and growing field of molecular laser biotechnology. Here the main emphasis is on the manipulation and understanding of bacterial and plant systems.

Glial cell-specific differences in response to alkylation damage.

Oligodendrocytes are preferentially sensitive to the toxic, carcinogenic, and teratogenic effects of methylnitrosourea (MNU). The mechanisms responsible for this enhanced sensitivity have not been fully elucidated. One of the most vulnerable cellular targets for this chemical is mitochondrial DNA (mtDNA). To determine if differences in mtDNA damage and repair capacity exist among the different CNS glial cell types, the effects of MNU exposure on oligodendroglia, astroglia, and microglia cultured separately from neonatal rat brain were compared. Quantitative determinations of mtDNA initial break frequencies and repair efficiencies showed that whereas no cell type-specific differences in initial mtDNA damage were detected, mtDNA repair in oligodendrocytes, oligodendrocyte progenitors, and microglia was significantly reduced compared to that of astrocytes. In astrocytes, and all other cell types previously evaluated in our laboratory, >60% of N-methylpurines were removed from the mtDNA by 24 hr. In contrast, only 35% of lesions were removed from mtDNA of oligodendrocytes, oligodendrocyte progenitors, and microglia during the same time period. Mitochondrial perturbations by a variety of xenobiotics have been linked to apoptosis. In the present study, apoptosis, as determined by DNA laddering and ultrastructural analysis, was clearly induced by MNU treatment of cultured oligodendrocyte progenitors and microglia, but not in astroglia. These data demonstrate a correlation between diminished mtDNA repair capacity and the induction of apoptosis. However, further experimentation is necessary to determine if a causal relationship exists and contributes to the vulnerability of oligodendroglia following exposure to N-nitroso compounds in the environment or in chemotherapeutic regimen.

The amyloid beta protein induces oxidative damage of mitochondrial DNA.

Multiple lines of evidence suggest involvement of oxidative stress in the pathogenesis of Alzheimer disease (AD). The finding that amyloid beta peptide (A beta) has neurotoxic properties and that such effects are mediated in part by free-radicals has provided an avenue to explore new therapeutic strategies. In this study, we showed that exposure of PC 12 cells to an A beta fragment induces oxidative damage of mitochondrial DNA. Cells were exposed for 24 h to 50 microM A beta (25-35) or to 50 microM of a control peptide with a scrambled sequence. Oxidative damage of mitochondrial DNA (mtDNA) was assessed using a Southern blot technique and an mtDNA-specific probe recognizing a 13.5-kilobase restriction fragment. Treatment of DNA with NaOH was used to reveal abasic sites and single strand breaks. Treatment with endonuclease III or FAPy glycosylase was used to detect pyrimidine or purine lesions, respectively. Cells exposed to A beta exhibited marked oxidative damage of mtDNA as evidenced by characteristic changes on Southern blots. Cells exposed to the scrambled peptide did not show such modifications. Simultaneous addition of the pineal hormone melatonin consistently prevented the A beta-induced oxidative damage to mtDNA. Mitochondrial dysfunction in AD has been demonstrated by several laboratories. This study provides experimental evidence supporting a causative role of A beta in mitochondrial lesions of AD.