UMLS:C0004135 - FACTA Search

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Query: UMLS:C0004135 (ATM)
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Neocarzinostatin (NCS) belongs to a family of antitumour protein antibiotics that selectively inhibit DNA synthesis. Replicon initiation in mammalian cells is selectively inhibited by NCS, and cells defective in DNA repair, such as ataxia telangiectasia fibroblasts, are especially sensitive to NCS as they are to X-ray. The holoantibiotic consists of a nonprotein chromophore (Mr = 659), tightly and specifically bound to an apoprotein (Mr = 10,700). The apoprotein protects the highly labile chromophore from degradation in aqueous solution; all the activity resides in the nonprotein chromophore. The latter binds specifically to DNA, especially to regions rich in T and A residues, with a tight binding site consisting of four base pairs. NCS chromophore consists of three main structural subunits: a naphthoic acid derivative, an amino-sugar and a connecting highly unsaturated middle component (C12H5) with a strained ether (probably epoxide) and cyclic carbonate. The authors have proposed that the naphthoic acid subunit intercalates DNA and the positively charged amino sugar binds electrostatically to the negatively charged sugar phosphate backbone of DNA; these two anchors serve to juxtapose the middle piece with the deoxyribose of mainly thymidylate residues in DNA. Upon activation of the drug by a thiol (which forms an adduct with the middle piece) and in the presence of O2, there is a selective oxidation of the 5'-C of deoxyribose to produce a DNA strand break with a phosphate at the 3'-end and a nucleoside 5'-aldehyde at the other. Kinetic analysis shows that one molecule of thiol adds to DNA-bound NCS chromophore even in the absence of oxygen; this is rapidly followed by the consumption of 1 mol of O2 and then another mol of thiol. The oxygen of the 5'-aldehyde is derived from O2, not H2O. Even in the absence of O2 the NCS chromophore abstracts a hydrogen from C-5' of deoxyribose in DNA, presumably generating a carbon-centred radical intermediate in the DNA (other mechanisms have not been eliminated) which can add O2 to form a peroxy derivative. The second molecule of thiol may be involved in the cleavage of this complex to form the 5'-aldehyde at the strand break. There is no evidence for the involvement of metals or a diffusible form of reduced oxygen.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Molecular mechanism of novel DNA sugar damage by an antitumour protein antibiotic. 294 68

The effect of angiotensin 1-7 (Ang 1-7) on the proximal tubule has not been well studied. It was hypothesized that Ang 1-7 has a biphasic effect on fluid absorption in the isolated rat proximal straight tubule. Proximal straight tubules were perfused at a rate of 5.81 +/- 0.44 nL/mm per minute and absorbed fluid at 0.98 +/- 0.10 nL/mm per minute. Bicarbonate absorption was 80.1 +/- 11.6 pmol/mm per minute. When 10(-12) M Ang 1-7 was added to the bath, fluid absorption increased to 1.47 +/- 0.10 nL/mm per minute (P < 0.013) and bicarbonate increased to 115.0 +/- 12.8 pmol/mm per minute (P < 0.004). Ang 1-7 had no effect on either the maximum rate of bicarbonate absorption (P > 0.90) or bicarbonate permeability (P > 0.60). Next, 10(-8) M Ang 1-7 was used. During the control period, fluid absorption was 0.90 +/- 0.09 nL/mm per minute. When 10(-8) M Ang 1-7 was added, fluid absorption decreased to 0.62 +/- 0.04 nL/mm per minute (P < 0.05). DuP 753, an AT1 receptor antagonist, blocked both effects induced by Ang 1-7, whereas PD 123319, an AT2 receptor antagonist, did not block the stimulatory effect. From these data, it was concluded that Ang 1-7 binds AT1 receptors and has a biphasic effect on fluid absorption, and at physiologic levels, the heptapeptide induces the stimulation of bicarbonate absorption.
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PMID:Angiotensin 1-7 has a biphasic effect on fluid absorption in the proximal straight tubule. 784 54

The loop of Henle contributes to renal acidification by reabsorbing about 15% of filtered bicarbonate. To study the effects on loop of Henle bicarbonate transport (JHCO3) of acid-base disturbances and of several factors known to modulate sodium transport, these in vivo microperfusion studies were carried out in rats during: (a) acute and chronic metabolic acidosis, (b) acute and chronic (hypokalemic) metabolic alkalosis, (c) a control sodium diet, (d) a high-sodium diet, (e) angiotensin II (AII) intravenous infusion, (f) simultaneously intravenous infusion of both AII and the AT1 receptor antagonist DuP 753, (g) acute ipsilateral mechanicochemical renal denervation. Acute and chronic metabolic acidosis increased JHCO3; acute metabolic alkalosis significantly reduced JHCO3, whereas chronic hypokalemic alkalosis did not alter JHCO3. Bicarbonate transport increased in animals on a high-sodium intake and following AII administration, and the latter was inhibited by the AII (AT1) receptor antagonist DuP 753; acute renal denervation lowered bicarbonate transport. These data indicate that bicarbonate reabsorption along the loop of Henle in vivo is closely linked to systemic acid-base status and to several factors known to modulate sodium transport.
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PMID:Bicarbonate transport along the loop of Henle. II. Effects of acid-base, dietary, and neurohumoral determinants. 804 Mar 39

The Na+/H+ antiport and Na(+)-HCO3- coinflux carrier contribute to recovery from intracellular acidosis in cardiac tissue. The effects of angiotensin II (10(-12)-10(-6) M) on H+ fluxes after intracellular acid loading and during reperfusion after myocardial ischemia have been investigated in the isovolumic, Langendorff-perfused ferret heart. Intracellular pH (pHi) was estimated using 31P nuclear magnetic resonance (NMR) spectroscopy from the chemical shift of intracellular deoxyglucose-6-phosphate or inorganic phosphate. Angiotensin II produced concentration-dependent stimulation (maximum at 10(-6) M: 67%) of 5-(N-ethyl-N-isopropyl)amiloride (EIPA)-sensitive Na(+)-dependent of H+ efflux consistent with stimulation of the Na+/H+ antiport. Half-maximal stimulation of H+ efflux occurred at approximately 10(-9) M, which is close to the dissociation constant of the cardiac angiotensin AT1 receptor. Stimulation via this receptor was confirmed with the nonpeptide AT1 receptor blocker, GR-117289. Angiotensin II had less pronounced effects on HCO3(-)-dependent pHi recovery after acid loading with no effect on pHi recovery after intracellular alkalosis. During reperfusion, angiotensin II significantly increased H+ extrusion but impaired contractile recovery. The results support the hypothesis that angiotensin II facilitates H+ extrusion in the heart. This may help maintain physiological homeostasis, but the hypothesized obligated Na+ influx could exacerbate cellular dysfunction during reperfusion.
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PMID:Angiotensin II stimulates sodium-dependent proton extrusion in perfused ferret heart. 876 51

Bicarbonate reabsorption was evaluated by stationary microperfusion "in vivo" early distal (ED) and late distal (LD) segments of at kidney. Intratubular pH was recorded by double-barreled of H+ exchange resin/reference (1 M KCl) microelectrodes for the determination of HCO3- reabsorption. In the presence of angiotensin II (ANG II) (10(-12) M), a significant increase in HCO3- reabsorption was observed both in ED (from 0.930 +/- 0.060 to 2.64 +/- 0.210 nmol.cm-2.s-1 in luminally perfused tubules and from 0.850 +/- 0.040 to 2.03 +/- 0.210 nmol.cm-2.s-1 during capillary perfusion) and LD segments from 0.310 +/- 0.130 to 2.16 +/- 0.151 nmol.cm-2.s-1 during luminal perfusion and from 0.530 +/- 0.031 to 2.16 +/- 0.211 nmol.cm-2.s-1 with capillary perfusion). The addition of the AT1-receptor antagonist losartan (10(-6) M) to luminal perfusion blocked luminal ANG II-mediated stimulation in ED and LD segments. 5-(N,N-hexamethylene)amiloride (10(-4) M) added to luminal perfusion inhibited luminal ANG II-mediated stimulation in ED (by 81%) and LD (by 54%) segments. The addition of bafilomycin A1 (2 x 10(-7) M) to luminal perfusion does not affect luminal ANG II-mediated stimulation in ED segments but reduces it in LD segments (by 33%). During the addition of atrial natriuretic peptide (ANP) (10(-6) M) or ANG II plus ANP in both segments, no significant differences in HCO3- reabsorption were observed. Our results indicate that luminal ANG II acts to stimulate Na+/H+ exchange in ED and LD segments via activation of AT1 receptors, as well as the vacuolar H(+)-adenosinetriphosphatase in LD segments. ANP does not affect HCO3- reabsorption in either ED or LD segments and does not impair the stimulation caused by ANG II.
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PMID:Effect of luminal angiotensin II and ANP on early and late cortical distal tubule HCO3- reabsorption. 894 91

1. The effects of angiotensin II (AngII) on water and electrolyte transport are biphasic and dose-dependent, such that low concentrations (10(-12) to 10(-9) mol/L) stimulate reabsorption and high concentrations (10(-7) to 10(-6) mol/L) inhibit reabsorption. Similar dose-response relationships have been obtained for luminal and peritubular addition of AngII. 2. The cellular responses to AngII are mediated via AT1 receptors coupled via G-regulatory proteins to several possible signal transduction pathways. These include the inhibition of adenylyl cyclase, activation of phospholipases A2, C or D and Ca2+ release in response to inositol-1,4,5,-triphosphate or following Ca2+ channel opening induced by the arachidonic acid metabolite 5,6,-epoxy-eicosatrienoic acid. In the brush border membrane, transduction of the AngII signal involves phospholipase A2, but does not require second messengers. 3. Angiotensin II affects transepithelial sodium transport by modulation of Na+/H+ exchange at the luminal membrane and Na+/HCO3 cotransport, Na+/K(+)-ATPase activity and K+ conductance at the basolateral membrane. 4. Atrial natriuretic factor (ANF) does not appear to affect proximal tubular sodium transport directly, but acts via specific receptors on the basolateral and brush border membranes to raise intracellular cGMP levels and inhibit AngII-stimulated transport. 5. It is concluded that there is a receptor-mediated action of ANF on proximal tubule reabsorption acting via elevation of cGMP to inhibit AngII-stimulated sodium transport. This effect is exerted by peptides delivered at both luminal and peritubular sides of the epithelium and provides a basis for the modulation by ANF of proximal glomerulotubular balance. The evidence reviewed supports the concept that in the proximal tubule, AngII and ANF act antagonistically in their roles as regulators of extracellular fluid volume.
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PMID:Regulation of renal tubular sodium transport by angiotensin II and atrial natriuretic factor. 899 49

In order to examine the effects and the interaction of angiotensin II (ANG II, 1 pM) and atrial natriuretic peptide (ANP, 1 microM) on the kinetics of bicarbonate reabsorption in the rat middle proximal tubule, we performed in vivo experiments using a stopped-flow microperfusion technique with the determination of lumen pH by Sb microelectrodes. These studies confirmed that ANG II added to the luminal or peritubular capillary perfusion fluid stimulates proximal bicarbonate reabsorption and showed that ANP alone does not affect this process, but impairs the stimulation caused by ANG II. We also studied the effects and the interaction of these hormones in cortical distal nephron acidification. Bicarbonate reabsorption was evaluated by the acidification kinetic technique in early (ED) and late (LD) distal tubules in rats during in vivo stopped-flow microperfusion experiments. The intratubular pH was measured with a double-barreled microelectrode with H(+)-sensitive resin. The results indicate that ANG II acted by stimulating Na+/H+ exchange in ED (81%) and LD (54%) segments via activation of AT1 receptors, as well as vacuolar H(+)-ATPase in LD segments (33%). ANP did not affect bicarbonate reabsorption in either segment and, as opposed to what was seen in the proximal tubule, did not impair the stimulation caused by ANG II. To investigate the mechanism of action of these hormones in more detail, we studied cell pH dependence on ANG II and ANP in MDCK cells using the fluorescent probe BCECF. We showed that the velocity of cell pH recovery was almost abolished in the absence of Na+, indicating that it is dependent on Na+/H+ exchange. ANP (1 microM) alone had no effect on this recovery but reversed both the acceleration of H+ extrusion at low ANG II levels (1 pM and 1 nM), and inhibition of H+ extrusion at higher ANG II levels (100 nM). To obtain more information on the mechanism of interaction of these hormones, we also studied their effects on the regulation of intracellular free calcium concentration, [Ca2+]i, monitored with the fluorescent probe Fura-2 in MDCK cells in suspension. The data indicate that the addition of increasing concentrations of ANG II (1 pM to 1 microM) to the cell suspension led to a progressive increase in [Ca2+]i to 2-3 times the basal level. In contrast, the addition of ANP (1 microM) to the cell suspension led to a very rapid 60% decrease in [Ca2+]i and reduced the increase elicited by ANG II, thus modulating the effect of ANG II on [Ca2+]i. These results may indicate a role of [Ca2+]i in the regulation of the H+ extrusion process mediated by Na+/H+ exchange and stimulated/impaired by ANG II. The data are compatible with stimulation of Na+/H+ exchange by increases of [Ca2+]i in the lower range, and inhibition at high [Ca2+]i levels.
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PMID:Interactions of ANP and ANG II in tubular nephron acidification. 925 67

The effect of angiotensin II (Ang II) on the activity of the cardiac Na+-independent Cl--HCO3- exchanger (anionic exchanger [AE]) was explored in cat papillary muscles. pHi was measured by epifluorescence with BCECF-AM. Ang II (500 nmol/L) induced a 5-(N-ethyl-N-isopropyl)amiloride-sensitive increase in pHi in the absence of external HCO3- (HEPES buffer), consistent with its stimulatory action on Na+-H+ exchange (NHE). This alkalinizing effect was not detected in the presence of a CO2-HCO3- buffer (pHi 7.07+/-0.02 and 7.08+/-0.02 before and after Ang II, respectively; n=17). Moreover, in Na+-free HCO3--buffered medium, in which neither NHE nor Na+-HCO3- cotransport are acting, Ang II decreased pHi, and this effect was canceled by previous treatment with SITS. These findings suggested that the Ang II-induced activation of NHE was masked, in the presence of the physiological buffer, by a HCO3--dependent acidifying mechanism, probably the AE. This hypothesis was confirmed on papillary muscles bathed with HCO3- buffer that were first exposed to 1 micromol/L S20787, a specific inhibitor of AE activity in cardiac tissue, and then to 500 nmol/L Ang II (n=4). Under this condition, Ang II increased pHi from 7.05+/-0.05 to 7.22+/-0.05 (P<.05). The effect of Ang II on AE activity was further explored by measuring the velocity of myocardial pHi recovery after the imposition of an intracellular alkali load in a HCO3--containing solution either with or without Ang II. The rate of myocardial pHi recovery was doubled in the presence of Ang II, suggesting a stimulatory effect on AE. The enhancement of the activity of this exchanger by Ang II was also detected when the AE activity was reversed by the removal of extracellular Cl- in a Na+-free solution. Under this condition, the rate of intracellular alkalinization increased from 0.053+/-0.016 to 0.108+/-0.026 pH unit/min (n=6, P<.05) in the presence of Ang II. This effect was canceled either by the presence of the AT1 receptor antagonist, losartan, or by the previous inhibition of protein kinase C with chelerythrine or calphostin C. The above results allow us to conclude that Ang II, in addition to its stimulatory effect on alkaline loading mechanisms, activates the AE in ventricular myocardium and that the latter effect is mediated by a protein kinase C-dependent regulatory pathway linked to the AT1 receptors.
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PMID:Angiotensin II activates Na+-independent Cl--HCO3- exchange in ventricular myocardium. 950 8

The luminal membrane of collecting duct cells, specially the intercalated cells, is normally exposed to active kallikrein. This is due to the specific localization of renal kallikrein in the connecting tubule cells. We have previously reported inhibition of distal bicarbonate secretion by renal kallikrein. The present study was performed to evaluate the participation of basolateral Cl-/HCO3- exchanger and luminal H(+)-ATPase activity of cortical collecting duct segments (CCD) in the mechanism involved in the inhibition of bicarbonate secretion induced by the enzyme. The effect of orthograde injections of 1 microgram/ml (250 U/6.3 mg) pig pancreatic kallikrein, in the absence and presence of 1 mM DIDS (stilbene-disulfonic acid) in the renal tubule system, was evaluated. Urine fractions were collected after two-minutes stop-flow. Changes in the urine fraction (Fr) related to those in free-flow urine samples (Ff) were related to the respective polyfructosan (Inutest) ratio. Renal kallikrein activity (Fr:Ff kallikrein/Fr:Ff polyfructosan) increased significantly in the first 120 microliters urine fraction collected after glandular 1 microgram/ml kallikrein, P < 0.05, (first stop-flow) and after glandular 1 microgram/ml kallikrein plus 1 mM. DIDS P < 0.05 (second stop flow). Bicarbonate secretion rate (Fr:Ff HCO3-/Fr:Ff polyfructosan) of collecting ducts was significantly reduced in the first 120 microliters urine fraction collected, related to control, during the first and second stop-flow periods. No difference was shown in bicarbonate excretion between the first 120 microliters urine fractions collected after administration of glandular kallikrein and glandular kallikrein plus DIDS. To measure H(+)-ATPase activity, rat microdissected cortical collector tubules (CCD) were incubated in the presence of increasing glandular kallikrein doses (A: 93, B: 187 and C: 375 mU/200 microL) in the presence of ouabain (4 microM) and omeprazole (100 microM) to inhibit Na(+)-K(+)-ATPase and H(+)-K(+)-ATPase, respectively. In CCD, bafilomycin-sensitive H(+)-ATPase activity (pmol/mm/min) after increasing kallikrein doses did not differ significantly from control. No difference related to control H(+)-ATPase activity was observed when microdissected CCD segments were incubated in the presence of an AT1 receptor antagonist (Losartan 10(-6) M) and glandular kallikrein (93 mU). On the contrary, angiotensin II (10(-8) M) significantly decreased H(+)-ATPase activity. The present study shows that neither basolateral Cl-/HCO3- exchanger nor H(+)-ATPase activity are involved in bicarbonate inhibition by glandular kallikrein at CCD. Involvement of luminal Cl-/HCO3- exchanger at beta intercalated cells in CCD may be suggested for the bicarbonate secretion inhibition induced by renal kallikrein.
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PMID:Effect of glandular kallikrein on distal bicarbonate transport. Role of basolateral Cl-/HCO3- exchanger and vacuolar H(+)-ATPase. 1090 41

Angiotensin II (AII) plays an important role in renal proximal tubular acidification via the costimulation of basolateral Na/HCO3 cotransporter (NBC) and apical Na/H exchanger (NHE) activities. These effects are mediated by specific G protein-coupled AII receptors, but their corresponding downstream effectors are incompletely defined. Src family tyrosine kinases (SFKs) contribute to the regulation of both transport activities by a variety of stimuli and are coupled to classic mitogen-activated protein kinase (MAPK) pathway activation in this cell type. We therefore examined these signaling intermediates for involvement in AII-stimulated NBC activity in cultured proximal tubule cells. Subpressor concentrations of AII (0.1 nM) increased NBC activity within minutes, and this effect was abrogated by selective antagonism of AT1 angiotensin receptors, SFKs, or the classic MAPK pathway. AII directly activated Src, as well as the proximal (Raf) and distal (ERK) elements of the classic MAPK module, and the activation of Src was prevented by AT1 receptor antagonism. An associated increase in basolateral membrane NBC1 content is compatible with the involvement of this proximal tubule isoform in these changes. We conclude that AII stimulation of the AT1 receptor increases NBC activity via sequential activation of SFKs and the classic MAPK pathway. Similar requirements for SFK/MAPK coupling in both cholinergic and acidotic costimulation of NBC and NHE activities suggest a central role for these effectors in the coordinated regulation of epithelial transport by diverse stimuli.
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PMID:Angiotensin II stimulation of renal epithelial cell Na/HCO3 cotransport activity: a central role for Src family kinase/classic MAPK pathway coupling. 1202 70

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