A novel endonuclease that may be responsible for damaged DNA base repair in Pyrococcus furiosus

DNA is constantly damaged by endogenous and environmental influences. Deaminated adenine (hypoxanthine) tends to pair with cytosine and leads to the A:T→G:C transition mutation during DNA replication. Endonuclease V (EndoV) hydrolyzes the second phosphodiester bond 3′ from deoxyinosine in the DNA strand, and was considered to be responsible for hypoxanthine excision repair. However, the downstream pathway after EndoV cleavage remained unclear. The activity to cleave the phosphodiester bond 5′ from deoxyinosine was detected in a Pyrococcus furiosus cell extract. The protein encoded by PF1551, obtained from the mass spectrometry analysis of the purified fraction, exhibited the corresponding cleavage activity. A putative homolog from Thermococcus kodakarensis (TK0887) showed the same activity. Further biochemical analyses revealed that the purified PF1551 and TK0887 proteins recognize uracil, xanthine and the AP site, in addition to hypoxanthine. We named this endonuclease Endonuclease Q (EndoQ), as it may be involved in damaged base repair in the Thermococcals of Archaea.     

A common enzyme may be responsible for the conversion of organic nitrates to nitric oxide in vascular microsomes.

We compared the nitric oxide (NO)-generating behavior of nitroglycerin (NTG), pentaerythritol trinitrate (PEtriN) and isosorbide dinitrate (ISDN), in the microsomal preparation of bovine coronary artery smooth muscle cells. The comparative NO generating activities among these nitrates were consistent with their relative reported vasodilating activities. Consistent with our previous observations with NTG, 400 microM bromosulfophthalein did not affect NO generation from PEtriN and ISDN in vascular microsomes while 400 microM 1-chloro-2,4-dinitrobenzene completely inhibited NO generation from these nitrates. Gel filtration chromatography with solubilized microsomes of bovine aortic smooth muscle cells showed the primary activity of NO generation from all three nitrates to be eluted at about 200 kD, consistent with that found with solubilized microsomes from the bovine coronary artery microsomes. These results suggest that organic nitrates may be converted to NO by one common enzyme in vascular microsomes.     

Iron-catalyzed reactions may be responsible for the biochemical and biological effects of asbestos

The most carcinogenic forms of asbestos contain iron to levels as high as 36% by weight and catalyze many of the same biochemical reactions that freshly prepared solutions of iron do, i.e. oxygen consumption, generation of reactive oxygen species, lipid peroxidation and DNA damage. The participation of iron from asbestos in these reactions has been demonstrated using the iron chelator desferrioxamine B which inhibits iron-catalyzed reactions. Iron appears to be redox active on the asbestos fiber, but chelation and subsequent iron mobilization from asbestos by a variety of chelators, e.g. citrate, EDTA or nitrilotriacetate, makes the iron more redox active resulting in greater oxygen consumption and production of oxygen radicals in the presence of reducing agents. Iron also appears to be important for some of the asbestos-dependent biological effects on tissues or cells in culture, such as phagocytosis, cytotoxicity, lipid peroxidation and DNA damage. Therefore, redox cycling of iron to generate oxygen radicals at the surface of the fiber and/or in solution, as mobilized, low molecular weight chelates, may be very important in eliciting some of the biological effects of asbestos in vivo.     

Identification of boron transporter genes likely to be responsible for tolerance to boron toxicity in wheat and barley

Tolerance to boron (B) toxicity in cereals is known to be associated with reduced tissue accumulation of B. Genes from roots of B-tolerant cultivars of wheat and barley with high similarities to previously reported B efflux transporters from Arabidopsis and rice were cloned. Expression of these genes was strongly correlated with the ability of tolerant genotypes to lower the concentration of B in roots. The gene from barley located to chromosome 4. Backcross lines containing a B tolerance locus on chromosome 4 showed tolerance in proportion to the level of expression of the transporter gene, whereas those lacking the locus were sensitive to B and had very low levels of gene expression. The results are consistent with a widespread mechanism of tolerance to high B based on efflux of B from root cells.     

Stimulation of insulin release by glyceraldehyde may not be similar to glucose

Glyceraldehyde (GA) has been used to study insulin secretion for decades and it is widely assumed that beta-cell metabolism of GA after its phosphorylation by triokinase is similar to metabolism of glucose; that is metabolism through distal glycolysis and oxidation in mitochondria. New data supported by existing information indicate that this is true for only a small amount of GA's metabolism and also suggest why GA is toxic. GA is metabolized at 10-20% the rate of glucose in pancreatic islets, even though GA is a more potent insulin secretagogue. GA also inhibits glucose metabolism to CO2 out of proportion to its ability to replace glucose as a fuel. This study is the first to measure methylglyoxal (MG) in beta-cells and shows that GA causes large increases in MG in INS-1 cells and d-lactate in islets but MG does not mediate GA-induced insulin release. GA severely lowers NAD(P) and increases NAD(P)H in islets. High NADH combined with GA's metabolism to CO2 may initially hyperstimulate insulin release, but a low cytosolic NAD/NADH ratio will block glycolysis at glyceraldehyde phosphate (GAP) dehydrogenase and divert GAP toward MG and D-lactate formation. Accumulation of D-lactate and 1-phosphoglycerate may explain why GA makes the beta-cell acidic. Reduction of both GA and MG by abundant beta-cell aldehyde reductases will lower the cytosolic NADPH/NADP ratio, which is normally high.     

Local leptin production in osteoarthritis subchondral osteoblasts may be responsible for their abnormal phenotypic expression

Introduction  

Leptin is a peptide hormone with a role in bone metabolism and rheumatic diseases. The subchondral bone tissue plays a prominent role in the pathophysiology of osteoarthritis (OA), related to abnormal osteoblast (Ob) differentiation. Although leptin promotes the differentiation of Ob under normal conditions, a role for leptin in OA Ob has not been demonstrated. Here we determined if endogenous leptin produced by OA Ob could be responsible for the expression of the abnormal phenotypic biomarkers observed in OA Ob.     

One or two low affinity penicillin-binding proteins may be responsible for the range of susceptibility of Enterococcus faecium to benzylpenicillin

Three benzylpenicillin-resistant, clinical isolates of Enterococcus faecium (MIC values 16-64 micrograms ml-1) contained six penicillin-binding proteins (PBPs), of which PBP5 was the most abundant and had the lowest affinity for the antibiotic. Four benzylpenicillin-susceptible strains (MIC values 0.031-0.5 microgram ml-1) were obtained as spontaneous derivatives from these above organisms. There were significant decreases in the amounts of PBP5 in each of the derivatives, with the concomitant appearance of a new, higher affinity PBP (5*) in three strains. Increased amounts of PBP5, with no changes in PBP5*, were found in several mutants with intermediate-level benzylpenicillin-resistance (MIC values 1-8 micrograms ml-1) selected from two of the susceptible strains. Examination of 18 other clinical isolates, with a wide range of susceptibilities to benzylpenicillin (MIC values 0.062-128 micrograms ml-1), showed that PBP5* was present in 13 strains, and PBP5 in all of them, but in differing amounts. The results concerning the relative amounts and relative affinities of PBPs 5* and 5 allowed the categorization of the various strains into six groups, within which organisms had somewhat similar susceptibilities to benzylpenicillin.     

Further evidence that oxidative stress may be a risk factor responsible for the development of atherosclerosis

There are numerous data suggesting that oxidative stress may be involved in the development of atherosclerosis. Therefore, in the present study we measured the amount of 8-hydroxy-2'-deoxyguanosine (8-OH-dG), one of the typical biomarkers of oxidative stress, in DNA isolated from lymphocytes of the patients and in the control group. Levels of antioxidant vitamins (A, C, and E) and intracellular labile iron pool (LIP), which can influence oxidative stress, were also determined. Blood samples were obtained from a control group of 55 healthy persons and from 43 atherosclerotic patients. 8-OH-dG and the vitamin levels were measured by high-performance liquid chromatography. Labile iron pool in lymphocytes was analyzed by fluorescent assay. The levels of 8-OH-dG and LIP were significantly higher and vitamin C concentration was significantly lower in the patient group than in the control group. The rest of the analyzed parameters do not significantly differ between the groups. A lower concentration of vitamin C and higher levels of labile iron pool in a group of atherosclerotic patients when compared with the control group may lead to oxidative stress, which is manifested by a higher level of 8-OH-dG in blood lymphocytes. All these factors may create an environment that promotes the development of atherosclerosis.     

Mechanisms that may be involved in calcium tolerance of the diabetic heart

In diabetes the hearts exhibit impaired membrane functions, but also increased tolerance to Ca²⁺ (iCaT) However, neither the true meaning nor the molecular mechanisms of these changes are fully understood. The present study is devoted to elucidation of molecular alterations, particularly those induced by non-enzymatic glycation of proteins, that may be responsible for iCaT of the rat hearts in the stage of fully developed, but still compensated diabetic cardiomyopathy (DH). Insulin-dependent diabetes (DIA) was induced by a single i.v. dose of streptozotocin (45 mg.kg^-1). Beginning with the subsequent day, animals obtained 6 U insulin daily. Glucose, triglycerides, cholesterol and glycohemoglobin were investigated in blood. ATPase activities, the kinetics of activation of (Na,K)-ATPase by Na⁺ and K⁺, further the fluorescence anisotropy of diphenyl-hexatriene as well as the order parameters of membranes in isolated heart sarcolemma (SL) were also investigated. In addition, the degree of glycation and glycation-related potency for radical generation in SL proteins were determined by investigating their fructosamine content. In order to study calcium tolerance of DH in a 'transparent' model, hearts were subjected to calcium paradox (Ca-Pa, 3 min of Ca²⁺ depletion; 10 min of Ca²⁺ repletion). In this model of Ca²⁺-overload, Ca²⁺ ions enter the cardiac cells in a way that is not mediated by receptors. Results revealed that more than 83% of the isolated perfused DH recovered, while the non-DIA control hearts all failed after Ca-Pa. DH exhibited well preserved SL ATPase activities and kinetics of (Na,K)-ATPase activation by Na⁺, even after the Ca-Pa. This was considered as a reason for their iCaT. Pretreatment and administration of resorcylidene aminoguanidine (RAG 4 or 8 mg.kg^-1) during the disease prevented partially the pathobiochemical effects of DIA-induced glycation of SL proteins. DIAinduced perturbations in anisotropy and order parameters of SL were completely prevented by administration of RAG (4 mg.kg^-1). Although, the latter treatment exerted little influence on the (Na,K)-ATPase activity, it decreased the calcium tolerance of the DH. Results are supporting our hypothesis that the glycation-induced enhancement in free radical formation and protein crosslinking in SL may participate in adaptive mechanisms that may be also considered as 'positive' and are responsible for iCaT of the DH.     

The acute EPS of haloperidol may be unrelated to its metabolic transformation to BCPP+

We have previously proposed that haloperidol's debilitating extrapyramidal symptoms (EPS) may be associated with its quaternary BCPP+ (an MPP+ like species) metabolite formed in vivo. However, recent work on D2 knock out mice suggests that haloperidol's EPS may be related to its potent D2 binding (K(i)=0.9 nM). In this study, we explore this question by synthesizing and testing an analogue (DS-27) that binds to D2 receptors with higher affinity than haloperidol, but cannot form quaternary metabolites. This study suggests that D2 affinity may be the primary underlying mechanism for acute catalepsy induction by haloperidol.     

The enzymes responsible for the metabolism of prostaglandins in bovine placenta

The following review presents some data on the enzymes of synthesis and catabolism of prostaglandins in bovine placenta. The available literature confirms the anabolic and catabolic ability of bovine placenta to metabolise prostaglandins, but there is little direct information about the pathways involved. The aim of the review is to describe what is known about the physico-chemical properties and activity of enzymes involved in prostaglandin metabolism in bovine placenta.     

Glutathione s-transferase omega 1-1 is a target of cytokine release inhibitory drugs and may be responsible for their effect on interleukin-1beta posttranslational processing

Stimulus-induced posttranslational processing of human monocyte interleukin-1beta (IL-1beta) is accompanied by major changes to the intracellular ionic environment, activation of caspase-1, and cell death. Certain diarylsulfonylureas inhibit this response, and are designated cytokine release inhibitory drugs (CRIDs). CRIDs arrest activated monocytes so that caspase-1 remains inactive and plasma membrane latency is preserved. Affinity labeling with [(14)C]CRIDs and affinity chromatography on immobilized CRID were used in seeking potential protein targets of their action. Following treatment of intact human monocytes with an epoxide-bearing [(14)C]CRID, glutathione S-transferase (GST) Omega 1-1 was identified as a preferred target. Moreover, labeling of this polypeptide correlated with irreversible inhibition of ATP-induced IL-1beta posttranslational processing. When extracts of human monocytic cells were chromatographed on a CRID affinity column, GST Omega 1-1 bound selectively to the affinity matrix and was eluted by soluble CRID. Recombinant GST Omega 1-1 readily incorporated [(14)C]CRID epoxides, but labeling was negated by co-incubation with S-substituted glutathiones or by mutagenesis of the catalytic center Cys(32) to alanine. Peptide mapping by high performance liquid chromatography-mass spectrometry also demonstrated that Cys(32) was the site of modification. Although S-alkylglutathiones did not arrest ATP-induced IL-1beta posttranslational processing or inhibit [(14)C]CRID incorporation into cell-associated GST Omega 1-1, a glutathione-CRID adduct effectively demonstrated these attributes. Therefore, the ability of CRIDs to arrest stimulus-induced IL-1beta posttranslational processing may be attributable to their interaction with GST Omega 1-1.     

The v-src oncogene may not be responsible for the increased radioresistance of hematopoietic progenitor cells expressing v-src.

Infection of the IL-3-dependent, myeloid progenitor cell line 32D cl 3 with murine retroviruses that contain either the wild-type or a temperature-sensitive mutant v-src can render these cells growth-factor independent. These cells also became resistant to gamma irradiation administered at the low-dose rate of 0.05 Gy/min, which is used clinically. The v-src-dependent nature of resistance to gamma irradiation was examined by studying four clones of 32D cl 3 cells that had been infected with a retrovirus carrying the tsLA31A mutant of v-src. The tyrosine-specific kinase activity of this mutant is dramatically reduced at the nonpermissive temperature of 39 degrees C. Cells transformed by v-src and grown at either 34 or 39 degrees C, in the presence or absence of IL-3, demonstrated a significantly higher D0 compared to parental cells examined under identical conditions. In addition, expression of v-src abrogated the synergistic killing effect of heat and gamma irradiation. The D0 of parental 32D cl 3 cells kept at 39 degrees C after gamma irradiation was reduced significantly compared to the D0 of these cells kept at 34 degrees C. This contrasts with data from 32D cl 3 cells infected with either the wild-type v-src or the temperature-sensitive mutant, neither exhibited a synergistic effect in the D0 at either 34 or 39 degrees C. Therefore, while continuous expression of a v-src gene product is required for maintenance of the growth-factor-independent state, v-src does not appear to be responsible for the increased gamma-radiation resistance of these cells at low dose rate.     

Chromogranin A correlates with norepinephrine release rate.

Chromogranin A (CgA) is an acidic protein co-released with catecholamines during exocytosis from sympathetic nerve terminals and chromaffin cells. Previous work has demonstrated that large scale perturbations in sympathetic nervous system (SNS) functioning result in corresponding changes in CgA levels in plasma. Little is known about the physiologic significance of CgA. We hypothesized that, since CgA and catecholamines are co-released from the same storage vesicles, and since CgA is not subject to reuptake or enzymatic metabolism, plasma CgA should reflect norepinephrine release from sympathetic terminals. We therefore measured venous CgA, norepinephrine levels, and norepinephrine release rate in 30 unmedicated subjects. Although the correlation of CgA with plasma norepinephrine was only modest (r = 0.37, p less than 0.05), its correlation with norepinephrine release rate was highly significant (r = 0.58, p less than 0.001). Thus, CgA may offer a novel perspective on peripheral sympathetic activity.