Inflammatory response to cold injury in remote organs is reduced by corticotropin-releasing factor

Current experimental evidence concerning the potential activity of corticotropin releasing factor (CRF) in inflammatory processes still remains controversial. To determine whether CRF has protective effects on three remote organs (liver, lung and stomach) affected by cold injury and to characterize the role of neutrophils in cold-induced inflammation, dorsums of anesthetized rats were exposed for 5 min to a 22% NaCl solution maintained at -20+/-0.5 degrees C and the rats were sacrificed at 24 h after the cold injury. The results indicate that cold-exposure-induced edema in the liver, lung and stomach was blocked by subcutaneous (s.c.; 1.2 and 12 nmol/kg; 30 min before cold trauma) CRF pretreatment, while the central administration of CRF (intracisternally (i.c.); 0.30 and 1.5 nmol/rat; 15 min before cold) had the similar effect at the higher dose. Histological assessment and the tissue myeloperoxidase activities also revealed that CRF given peripherally has a protective role in damage generation. Moreover, CRF had a facilitatory effect in the recovery of the body temperature following cold exposure. In conclusion, CRF is likely to act on its peripheral receptors in the inflamed remote organs, suppressing the edematogenic effects of inflammatory mediators, some of which are neutrophil-derived.     

Effect of exogenous melatonin on ethanol-induced changes in Na(+),K(+)- and Ca(2+)-ATPase activities in rat synaptosomes

In the present study, the effects of acute ethanol (EtOH) toxicity and of exogenous melatonin (MLT) on this toxicity were examined by measuring membrane-bound ATPases and acetylcholinesterase activities in rat synaptosomal membranes. The concentrations of plasma -tocopherol and adrenal ascorbic acid (AA) were also measured. Synaptosomal Na⁺,K⁺-ATPase and Ca²⁺-ATPase activities were significantly depressed in acute EtOH-intoxicated rats compared with controls, while acetylcholinesterase activity remained unaltered. Pretreatment with MLT (10 mg/kg) prior to acute EtOH administration prevented EtOH-induced inhibition of ATPases. Adrenal AA and plasma -tocopherol levels were also depressed regardless of MLT pretreatment. MLT treatment alone affected neither membrane-bound enzyme activities nor tissue and blood levels of vitamins C and E. It is concluded that acute EtOH intoxication disturbs neural transport functions through the membrane-bound ATPase activity depression. Reduced AA and -tocopherol levels may contribute to the neurodegenerative effects of EtOH. However, pretreatment with a high dose of MLT before EtOH administration may be beneficial to prevent EtOH-induced toxicity on ATPase-mediated neural transport functions.     

Effects of neutral,cationic, and anionic chromium ascorbate complexes on isolated human mitochondrial and genomic DNA

The relative activities of neutral, cationic, and anionic chromium ascorbate complexes toward isolated human mitochondrial and genomic DNA were investigated at physiologically relevant conditions by agarose gel electrophoresis. A direct relationship between the charge of the Cr(III) species and their DNA-damaging properties was found. The cationic species were found to be fully capable of DNA-cleavage, even in short incubation periods. Incubations were also performed in the presence of amino acids. No apparent effect was observed under the applied experimental conditions to facilitate or prevent damage through the ternary amino acid-Cr-DNA adduct formation or binary chromium-amino acid complex formation.     

Isolation and identification of alkaline protease producer halotolerantBacillus licheniformis strain BA17

An alkaline protease producerBacillus licheniformis strain was isolated from Van Lake in Turkey. The strain is Gram positive, aerobic, motile, sporulating rod-shaped bacterium. Spores were ellipsoidal and positioned central in nonswollen sporangium. The cells were able to grow well at a pH range of 5.7–10. The optimal growth temperature was found to be 37 °C. Growth at a wide range of NaCl concentration (from 0 to 20%) showed that BA17 is halotolerant. Main fatty acid composition of BA17 was anteiso-C15:0 and iso-C15∶0. The strain was presumptively identified asB. licheniformis according to 16S rDNA gene sequence analysis. The most appropriate medium for the growth and protease production is composed of 0.5% yeast extract, 0.5% NaNO₃, 0.02% MgSO₄\7H₂O, 0.1% K₂HPO₄ and 0.5% maltose. The optimum temperature and pH of the alkaline protease of strain BA17 were found to be 60 °C and pH 11, respectively. The activity was completely lost in the presence of PMSF, suggesting that the preparation contains serine-alkaline protease(s).     

High bioreactor production and emulsifying activity of an unusual exopolymer by Chromohalobacter canadensis 28

Unusual composition of an exopolymer (EP) from an obligate halophilic bacterium Chromohalobacter canadensis 28 has triggered an interest in development of an effective bioreactor process for its production. Its synthesis was investigated in 2‐L bioreactor at agitation speeds at interval 600‐1000 rpm, at a constant air flow rate of 0.5 vvm; aeration rates of 0.5, 1.0, and 1.5 vvm were tested at constant agitation rate of 900 rpm. EP production was affected by both, agitation and aeration. As a result twofold increase of EP yield was observed and additionally increased up to 3.08 mg/mL in a presence of surfactants. For effective scale‐up of bioreactors mass transfer parameters were estimated and lowest values of K_La obtained for the highest productivity fermentation was established. Emulsification activity of EP exceeded that of trade hydrocolloids xanthan, guar gum, and cellulose. A good synergism between EP and commercial cellulose proved its potential exploration as an enhancer of emulsifying properties of trade emulsions. A pronounced lipophilic effect of EP was established toward olive oil and liquid paraffin. Cultivation of human keratinocyte cells (HaCaT) with crude EP and purified γ‐polyglutamic acid (PGA) showed higher viability than control group.     

Utilization of Recycled Asphalt Concrete with Warm Mix Asphalt and Cost-Benefit Analysis

The asphalt paving industries are faced with two major problems. These two important challenges are generated with an increase in demand for environmentally friendly paving mixtures and the problem of rapidly rising raw materials. Recycling of reclaimed asphalt pavement (RAP) is a critical necessity to save precious aggregates and reduce the use of costly bitumen. Warm Mix Asphalt (WMA) technology provides not only the option of recycling asphalt pavement at a lower temperature than the temperature maintained in hot mixtures but also encourages the utilization of RAP and therefore saves energy and money. This paper describes the feasibility of utilizing three different WMA additives (organic, chemical and water containing) at recommended contents with different percentages of RAP. The mechanical properties and cost-benefit analysis of WMA containing RAP have been performed and compared with WMA without RAP. The results indicated that, 30%, 10% and 20% can be accepted as an optimum RAP addition related to organic, chemical and water containing additives respectively and organic additive with 30% RAP content has an appreciable increase in tensile strength over the control mix. It was also concluded that the RAP with WMA technology is the ability to reduce final cost compared to HMA and WMA mixtures.     

Distribution of Activator of G-Protein Signaling 3 within the Aggresomal Pathway: Role of Specific Residues in the Tetratricopeptide Repeat Domain and Differential Regulation by the AGS3 Binding Partners Giα and Mammalian Inscuteable

AGS3, a receptor-independent activator of G-protein signaling, is involved in unexpected functional diversity for G-protein signaling systems. AGS3 has seven tetratricopeptide (TPR) motifs upstream of four G-protein regulatory (GPR) motifs that serve as docking sites for Giα-GDP. The positioning of AGS3 within the cell and the intramolecular dynamics between different domains of the proteins are likely key determinants of their ability to influence G-protein signaling. We report that AGS3 enters into the aggresome pathway and that distribution of the protein is regulated by the AGS3 binding partners Giα and mammalian Inscuteable (mInsc). Giα rescues AGS3 from the aggresome, whereas mInsc augments the aggresome-like distribution of AGS3. The distribution of AGS3 to the aggresome is dependent upon the TPR domain, and it is accelerated by disruption of the TPR organizational structure or introduction of a nonsynonymous single-nucleotide polymorphism. These data present AGS3, G-proteins, and mInsc as candidate proteins involved in regulating cellular stress associated with protein-processing pathologies.The discovery of AGS3 (GPSM1) and related accessory proteins revealed unexpected functional diversity for G-protein signaling systems (8, 36). AGS3 is involved in a number of different cellular activities, including asymmetric cell division during neuronal development (30), neuronal plasticity and addiction (9, 10, 12, 38, 39), autophagy (27), membrane protein trafficking (17), cardiovascular function (7), and metabolism (7). AGS3 is a multidomain protein consisting of seven tetratricopeptide repeats (TPR) in the amino-terminal portion of the protein and four G-protein regulatory (GPR) motifs in the carboxyl region of the protein. Each of the GPR motifs binds and stabilizes the GDP-bound conformation of Gα (Giα, Gtα, and Gi/oα), essentially behaving as a guanine nucleotide dissociation inhibitor. As such, AGS3 may be complexed with up to four Gα and function as an alternative binding partner for Gα independently of the classical heterotrimeric Gαβγ. Despite the clearly demonstrated function of AGS3 and the related protein LGN (GPSM2 or AGS5) in various model organisms and a fairly solid, basic biochemical understanding of the interaction of a GPR motif with Gα, the signals that operate “upstream” and/or “downstream” of AGS3 or an AGS3-Gi/oα complex are not well defined.AGS3 and other GPR proteins may regulate G-protein signaling directly by influencing the interaction of Gα with Gβγ or another Gα binding partner. In addition, a portion of Gα in the cell is complexed with GPR proteins to various degrees, and this interaction is regulated. Ric-8A interacts with an AGS3-Giα complex in a manner somewhat analogous to the interaction of a G-protein-coupled receptor with heterotrimeric Gαβγ, promoting nucleotide exchange and the apparent dissociation of AGS3 and Giα-GDP (37). The specific impact of AGS3 and other GPR proteins on signaling events is likely dependent upon where the individual protein is positioned within the cell and the nature of intra- and intermolecular interactions that influence the interaction of the GPR motif with Gi/oα.The TPR domain of AGS3 is an important determinant of its positioning within the cell through its interaction with specific binding partners (1, 8, 28, 36). As part of a broader effort to address the fundamental questions of AGS3 “positioning” and control of G-protein interaction, we focused upon the roles of individual TPR domains. Endogenous and ectopically expressed wild-type AGS3 is nonhomogeneously distributed in the cytoplasm, with obvious punctate structures, and it may be present at the cell periphery. Disruption of the TPR organizational structure by targeted amino acid substitutions or introduction of a nonsynonymous single-nucleotide polymorphism redistributes AGS3 to punctate structures throughout the cytoplasm that are similar in appearance to the preaggresomal assemblies or aggregates observed in neurodegenerative diseases. Upon cellular stress, both wild-type and TPR-modified AGS3 migrate, in a microtubule-dependent manner, to a perinuclear aggresome. The distribution of AGS3 to the aggresome is dependent upon the TPR domain, and it is differentially regulated by Giα and mammalian Inscuteable (mInsc), which bind to the GPR and TPR domains, respectively, of AGS3. These data present AGS3 and G-proteins as candidate proteins involved in regulating cellular stress associated with protein-processing pathologies and suggest that this involvement can be manipulated to therapeutic advantage.     

Donor heart preservation with iloprost supplemented St. Thomas Hospital cardioplegic solution in isolated rat hearts

This study was designed to assess the influence of St. Thomas Hospital cardioplegic solution (St. Th.) on heart preservation in rat hearts subjected to 6h ischemia when supplemented with iloprost. In the control group (n=8), nothing was added to St. Th., whereas 10 or 1000 nmol L(-1) iloprost was added in the second (n=7) and third (n=8) groups, respectively. Mechanical contraction parameters, cardiac tissue damage and oxidative stress markers were evaluated. The 10 nmol/L iloprost group peak systolic pressure (71.0+/-30.9 versus 41.0+/-9.4 mm Hg) and -dp/dtmax (1103.8+/-94.3 versus 678.6+/-156.8 mm Hg s(-1)) were significantly higher than control group at 30 min of reperfusion (p<0.05). Iloprost supplemented groups had higher GSH and catalase levels of coronary perfusate at reperfusion, in comparison with initial values (p<0.05). AST, CK, CK-MB values increased at 0 min of reperfusion and cTnI values at 45 min of reperfusion (p<0.05) in all groups with no difference between groups. According to our results, iloprost supplementation had mild but significant improvement in postischemic values in mechanical and oxidative stress parameters, resulting in better heart preservation.     

The effects of mesenchymal stem cell mitochondrial transplantation on doxorubicin‐mediated nephrotoxicity in rats

The effect of dysfunctional mitochondria in several cell pathologies has been reported in renal diseases, including diabetic nephropathy and acute kidney injury. Previous studies have reported that mitochondrial transplantation provided surprising results in myocardial and liver ischemia, as well as in Parkinson's disease. We aimed to investigate the beneficial effects of isolated mitochondria transplantation from mesenchymal stem cells (MSCs) in vivo, to mitigate renal damage that arises from doxorubicin‐mediated nephrotoxicity and its action mechanism. In this study, a kidney model of doxorubicin‐mediated nephrotoxicity was used and isolated mitochondria from MSCs were transferred to the renal cortex of rats. The findings showed that the rate of isolated mitochondria from MSCs maintains sufficient membrane integrity, and was associated with a beneficial renal therapeutic effect. Following doxorubicin‐mediated renal injury, isolated mitochondria or vehicle infused into the renal cortex and rats were monitored for five days. This study found that mitochondrial transplantation decreased cellular oxidative stress and promoted regeneration of tubular cells after renal injury (P < .001, P = .009). Moreover, mitochondrial transplantation reduced protein accumulation of tubular cells and reversed renal deficits (P = .01, P < .001). Mitochondrial transplantation increased Bcl‐2 levels, and caspase‐3 levels decreased in injured renal cells (P < .015, P < .001). Our results provide a direct link between mitochondria dysfunction and doxorubicin‐mediated nephrotoxicity and suggest a therapeutic effect of transferring isolated mitochondria obtained from MSCs against renal injury. To our knowledge, this study is the first study in the literature that showed good therapeutic effects of mitochondrial transplantation in a nephrotoxicity model, which is under‐researched.