Ghrelin receptor regulates HFCS-induced adipose inflammation and insulin resistance.

BACKGROUND AND OBJECTIVES: High fructose corn syrup (HFCS) is the most commonly used sweetener in the United States. Some studies show that HFCS consumption correlates with obesity and insulin resistance, while other studies are in disagreement. Owing to conflicting and insufficient scientific evidence, the safety of HFCS consumption remains controversial. SUBJECTS/METHODS: We investigated the metabolic consequences of mice fed a (a) regular diet, (b) 'Western' high-fat diet or (c) regular diet supplemented with 8% HFCS in drinking water (to mimic soft drinks) for 10 months. Adipose tissue macrophages (ATMs) have emerged as a major pathogenic factor for obesity and insulin resistance. ATMs consist of proinflammatory F4/80(+)CD11c(+) macrophages and anti-inflammatory F4/80(+)CD11c(-) macrophages. In this study, we assessed the effects of HFCS on ATMs in intra-abdominal fat. RESULTS: We found that HFCS feeding in mice induced more severe adipose inflammation and insulin resistance than even the higher-calorie-containing 'Western' high-fat diet, and these HFCS-induced deleterious effects were independent of calorie intake or body fat content. We showed that similar to 'Western' high-fat diet, HFCS triggered a robust increase of both proinflammatory ATMs and anti-inflammatory ATMs in intra-abdominal fat. Remarkably, however, the anti-inflammatory ATMs were much less abundant in HFCS-fed mice than in high-fat-fed mice. Furthermore, we showed that deletion of the ghrelin receptor (growth hormone secretagogue receptor, GHS-R) ameliorates HFCS-induced adipose inflammation and insulin resistance. HFCS-fed GHS-R-null mice exhibit decreased proinflammatory ATMs in intra-abdominal fat, reduced adipose inflammation and attenuated liver steatosis. CONCLUSION: Our studies demonstrate that HFCS has detrimental effects on metabolism, suggesting that dietary guidelines on HFCS consumption for Americans may need to be revisited. GHS-R deletion mitigates the effects of HFCS on adipose inflammation and insulin resistance, suggesting that GHS-R antagonists may represent a novel therapy for insulin resistance.

Renal cell apoptosis in chronic obstructive uropathy: the roles of caspases.

BACKGROUND: Apoptosis of tubular and interstitial cells is well documented in kidneys with chronic obstructive uropathy (COU) and probably plays an important role in the pathogenesis of this condition. The molecular control of apoptosis in COU remains poorly understood. Apoptosis in general is known to proceed initially along distinct pathways, which later converge into a common arm characterized by orderly activation of caspases. Caspases are cytosolic enzymes that belong to a 12-member family and serve as effector molecules for apoptosis. The role of individual caspases in mediating renal cell apoptosis in kidneys with COU is studied. METHODS: Kidneys were harvested from sham-operated mice and mice with COU created by left ureter ligation at days 4, 7, 15, 20, and 30. The following studies were performed: (1) determination of dried kidney weight; (2) in situ end labeling of fragmented DNA to detect apoptotic tubular and interstitial cells; (3) ribonuclease protection assay with specific anti-sense RNA probes for caspases 1, 2, 3, 6, 7, 8, 9, 11, and 12 to detect the expression of individual caspases; (4) immunostaining for caspases; and (5) assay for caspase 3. To assess the role of caspases in COU-associated renal cell apoptosis, the frequencies of apoptotic tubular and interstitial cells were separately quantitated for each experimental time point, and their patterns of variation were correlated with those of individual caspases. RESULTS: The obstructed kidneys showed progressive tissue loss (60% of control at day 15). Apoptosis of both tubular and interstitial cells was seen in obstructed kidneys. Tubular cell apoptosis peaked at four days after ureter ligation (13-fold of control), remained high between days 4 to 15, and thereafter decreased rapidly. Apoptotic interstitial cells were scanty initially, but gradually increased throughout the entire experiment. Apoptosis was minimal throughout the experiment in control and contralateral kidneys. In control and contralateral kidneys, caspases 2, 3, 6, 7, 8, and 9 mRNAs were expressed at low levels, whereas those for caspases 1, 11, and 12 were not detected. The obstructed kidneys displayed increased expression of all tested caspases. Caspases 1, 11, and 12 mRNAs were detected in obstructed kidneys in a common pattern characterized by a sharp increase at day 4, followed by a decrease until day 20, and a subsequent sharp increase until the end of the study at day 30. A similar pattern was noted for other caspases (2, 3, 6, 7, 8, and 9), which maximally reached twofold to fourfold that of controls. Immunostaining for caspases 1, 2, 3, 6, 7, 8, and 9 showed the same pattern characterized by focal and weak expression in proximal tubules of control or contralateral kidney, contrasting with increased staining in atrophic or dilated tubules of obstructed kidneys. Interstitial cells also displayed staining for several caspases, which paralleled the increasing density of interstitial cells toward the end of the experiment. Caspase-3 assay showed a marked increased activity in obstructed kidneys that reached fourfold and sevenfold of control at days 4 and 30, respectively. The rise and fall of caspase mRNAs between days 4 and 30 paralleled a similar fluctuation in tubular cell apoptosis. The subsequent increase of mRNAs was correlated with a continuous rise of interstitial cell apoptosis. CONCLUSIONS: Urinary obstruction in mice induces apoptosis of both tubular and interstitial cells in the affected kidney in a distinctive pattern that parallels an increased expression of caspases. This correlation suggests that these caspases mediate COU-associated renal cell apoptosis. Among the evaluated caspases, increased renal caspase 3 activity implies its central role in renal cell apoptosis associated with urinary obstruction.

Mechanism of chronic obstructive uropathy: increased expression of apoptosis-promoting molecules.

BACKGROUND: We have demonstrated that renal tubular and interstitial cells undergo pronounced apoptosis during the course of chronic obstructive uropathy (COU). Apoptosis is a complex cellular process consisting of multiple steps, each of which is mediated by families of related molecules. These families may include receptor/ligand molecules such as Fas, Fas ligand, tumor necrosis factor receptor-1 (TNFR-1), and TNF-related apoptosis inducing ligand (TRAIL); signal transduction adapter molecules such as Fas-associated death domain (FADD), TNFR-1 associated death domain (TRADD), receptor-interacting protein (RIP), Fas-associated factor (FAF), and Fas-associated phosphatase (FAP); or effector molecules such as caspases. However, the mechanism of tubular cell apoptosis, as well as the pathogenetic relevance of these apoptosis-related molecules in COU, remains poorly understood. METHODS: Kidneys were harvested from sham-operated control mice and mice with COU created by left ureter ligation sacrificed in groups of three at days 4, 15, 30, and 45. To detect apoptotic tubular and interstitial cells, in situ end labeling of fragmented DNA was performed. To detect the expression of apoptosis-related molecules, ribonuclease protection assay was used with specific antisense RNA probes for Fas, Fas ligand, TNFR-1, TRAIL, FADD, TRADD, RIP, FAF, FAP, and caspase-8. Immunostaining for Fas, Fas ligand, TRAIL, TRADD, RIP, and caspase-8 was also performed. To assess the role of these molecules in COU-associated renal cell apoptosis, the frequencies of apoptotic tubular and interstitial cells were separately quantitated for each experimental time point, and their patterns of variation were correlated with those of apoptosis-related molecules. RESULTS: The obstructed kidneys displayed increased apoptosis of both tubular and interstitial cells. Tubular cell apoptosis appeared at day 4 after ureter ligation, peaked (fivefold of control) at day 15, and decreased gradually until the end of the experiment. In contrast, interstitial cell apoptosis sustained a progressive increase throughout the experiment. Apoptosis was minimal at all experimental time points for control and contralateral kidneys. Compared with control and contralateral kidneys, the ligated kidneys displayed a dynamic expression of mRNAs for many apoptosis-related molecules, which included an up to threefold increase for Fas, Fas ligand, TNF-R1, TRAIL, TRADD, RIP, and caspase-8, and an up to twofold increase for FADD and FAP, but there was little change for FAF. These mRNAs increased between days 4 and 15, decreased until day 30, but then increased again until day 45. The rise and fall of mRNAs between days 4 and 30 paralleled a similar fluctuation in tubular cell apoptosis in that period. The subsequent increase of mRNAs was correlated with a continuous rise of interstitial cell apoptosis. We demonstrated a positive immunostaining for Fas and Fas ligand in the tubular cells at early time points as well as in interstitial inflammatory cells at later time points. Although increased expression of TRAIL, TRADD, RIP, and caspase-8 was noted in tubular cells, there was no staining for these molecules in interstitial cells. CONCLUSION: The current study documents a dynamic expression of several molecules that are known to mediate the most crucial steps of apoptosis. It implicates these molecules in COU-associated renal cell apoptosis and in the pathogenesis of this condition. It also lays the foundation for interventional studies, including genetic engineering, to evaluate the molecular control of apoptosis associated with COU.

Osmotically relevant membrane signaling complex: association between HB-EGF, beta(1)-integrin, and CD9 in mTAL.

The integral membrane proteins cluster of differentiation-9 (CD9), beta(1)-integrin, and heparin-binding epidermal growth factor-like (HB-EGF) exist in association in many cell lines and are linked to intracellular signaling mechanisms. Two of the proteins (CD9 and beta(1)-integrin) are induced by hypertonicity, suggesting that their related signaling processes may be relevant to osmotic stress. The validity of this hypothesis rests upon coexpression and physical association between these molecules in nephron segments that are normally exposed to high and variable ambient osmolality. In this work, we show that CD9 and beta(1)-integrin are induced in rat kidney medulla after dehydration. Immunohistochemistry and immunoprecipitation studies show that CD9, HB-EGF, and beta(1)-integrin are coexpressed and physically associated in medullary thick ascending limbs (mTAL), nephron segments that are normally exposed to high and variable extracellular osmolality. Our findings are consistent with the existence of a cluster of integral membrane proteins in mTAL that may initiate or modulate osmotically relevant signaling pathways.

Regulation of stanniocalcin in MDCK cells by hypertonicity and extracellular calcium.

Differential display RT-PCR cloning method was applied to poly(A)(+) RNA isolated from Madin-Darby canine kidney (MDCK) cells in isotonic or hypertonic medium. A differentially expressed 360-bp PCR fragment was isolated, subcloned, sequenced, and used to screen an MDCK cDNA library constructed in lambdaZapII. A composite sequence of two overlapping cDNA clones provided 1,053 bp of sequence that was 93% identical to human stanniocalcin and corresponded to the 3'-end of the mRNA. Although the fish homolog of this hormone inhibits calcium uptake by the gill and intestine, the function of mammalian stanniocalcin remains unknown. Stanniocalcin cDNA probe hybridizes to a 4.4-kb mRNA that is induced eightfold by hypertonicity, in a manner that is dependent on medium organic osmolytes. The mRNA induction correlates with increased total cellular content of the protein and its concomitant release to the medium, consistent with secretion for autocrine or paracrine activity. Furthermore, induction of the mRNA by hypertonicity is dependent on extracellular calcium and displays a threshold phenomenon. The data suggest that kidney stanniocalcin may have a role in the adaptation of kidney cells to osmotic stress, in a manner that is extracellular calcium dependent.

Osmotic response element enhancer activity. Regulation through p38 kinase and mitogen-activated extracellular signal-regulated kinase kinase.

Hypertonicity induces a group of genes that are responsible for the intracellular accumulation of protective organic osmolytes such as sorbitol and betaine. Two representative genes are the aldose reductase enzyme (AR, EC 1.1.1.21), which is responsible for the conversion of glucose to sorbitol, and the betaine transporter (BGT1), which mediates Na+-coupled betaine uptake in response to osmotic stress. We recently reported that the induction of BGT1 mRNA in the renal epithelial Madin-Darby canine kidney cell line is inhibited by SB203580, a specific p38 kinase inhibitor. In these studies we report that the hypertonic induction of aldose reductase mRNA in HepG2 cells as well as the osmotic response element (ORE)-driven reporter gene expression in transfected HepG2 cells are both inhibited by SB203580, suggesting that p38 kinase mediates the activation and/or binding of the transcription factor(s) to the ORE. Electrophoretic gel mobility shift assays with cell extracts prepared from SB203580-treated, hypertonically stressed HepG2 cells further show that the binding of trans-acting factors to the ORE is prevented and is thus also dependent on the activity of p38 kinase. Similarly, treatment of hypertonically stressed cells with PD098059, a mitogen-activated extracellular regulated kinase kinase (MEK1) inhibitor, results in inhibition of the hypertonic induction of aldose reductase mRNA, ORE-driven reporter gene expression, and the binding of trans-acting factors to the ORE. ORE-driven reporter gene expression was not affected by p38 kinase inhibition or MEK1 inhibition in cells incubated in iso-osmotic media. These data indicate that p38 kinase and MEK1 are involved in the regulation of the hyperosmotic stress response.

Cell apoptosis and proliferation in obstructive uropathy.

Distinct patterns of cell proliferation and apoptosis have been recognized for tubular, interstitial, and glomerular cells in chronic obstructive uropathy (OU). In many experimental models of OU, tubular cell apoptosis develops quickly after ureter ligation, peaks between 7 and 24 days postobtruction (about 30-fold of control), and tapers thereafter. Apoptosis initially involves the dilated collecting ducts, but subsequently spreads to other tubules. Tubular cell apoptosis probably accounts for renal tissue loss in OU because a direct correlation between its degree and the decline in dry kidney weight is well-documented. Pronounced tubular cell proliferation occurs shortly after ureter ligation, peaks at about day 6 (60-fold above control), and quickly subsides to baseline. Because the peak of tubular cell proliferation immediately precedes the onset of tubular cell apoptosis, a pathogenetic link may exist between these two processes. Interstitial cell apoptosis occurs with an increasing frequency throughout the course of OU (up to 35-fold above control). Interstitial cell proliferation appears in a bimodal pattern with the early peak coinciding with that of tubular cell proliferation and consisting mostly of fibroblasts, whereas the later peak consists mostly of inflammatory cells. Glomerular cell apoptosis and proliferation are not different from control, which explains, in part, the structural integrity of the glomeruli throughout the disease course. Although the general pathways of cell apoptosis and proliferation are well known, the molecular control of these processes in OU is poorly understood. In addition, whether apoptosis or proliferation of tubular and interstitial cells is differentially regulated remains to be studied. However, several molecules known to be activated or overexpressed in kidney with OU may modulate cell apoptosis and proliferation. The relevant functions of these molecules include induction of apoptosis (angiotensin II, reactive oxygen species, jun-N-terminal kinase, p53), inhibition of the cell cycle (transforming growth factor-beta, p21), inhibition of apoptosis (clusterin, epidermal growth factor, insulin-like growth factor, bcl-2, osteopontin), or promotion of interstitial fibroblast proliferation (platelet-derived growth factor).

The patient with a clotted PTFE graft developing fever.

Haemodialysis access graft infection is easily recognizable when local symptoms (warmth, swelling, pain, or drainage) predominate, and endocarditis is a well established complication of infected grafts. We report a case of bacterial endocarditis complicating silent infection in clotted haemodialysis access graft. It is suggested that, clotted non-functioning grafts may be the harbingers of silent infection, and should be suspected as the source of infection in every haemodialysis patient that presents with fever, even in the absence of clinical signs of graft site infection.

Acute effects of vasopressin V2-receptor antagonist on kidney AQP2 expression and subcellular distribution.

The acute effect of treatment with the vasopressin V2-receptor antagonist OPC-31260 (OPC) on aquaporin-2 (AQP2) distribution and expression in rat kidney was examined. Immunofluorescence and semi-quantitative immunoelectron microscopy revealed that 15 and 30 min of OPC treatment resulted in significant reduction in apical plasma membrane labeling of AQP2, with a concomitant increase in labeling of vesicles and multivesicular bodies. In parallel, OPC treatment induced a large increase in urine output [0.6 +/- 0.2 vs. 8.3 +/- 1.0 ml/h (n = 4)]. Northern blotting using a 32P-labeled AQP2 cDNA probe and a digoxigenin-labeled AQP2 RNA probe revealed a band of approximately 1.6 kb corresponding to the predicted size of AQP2 mRNA. In control experiments, thirsting increased, whereas water loading decreased AQP2 mRNA levels. Treatment of rats with OPC caused a significant reduction in AQP2 mRNA within 30 min (52 +/- 21%, n = 8, P < 0.025) and 60 min (56 +/- 7%, n = 4, P < 0.001) of treatment compared with intravenous saline-injected controls. Thus a very rapid reduction in AQP2 mRNA was observed in response to vasopressin-receptor antagonist treatment. The reduction in AQP2 mRNA persisted after 24 h (40 +/- 17%, n = 5, P < 0.05) of OPC treatment. There was a parallel increase in diuresis and reduction in urine osmolality. In conclusion, V2-receptor blockade produced a rapid internalization of AQP2 parallel with a rapid increase in urine output. Furthermore, OPC treatment caused a rapid and significant reduction in AQP2 mRNA expression, demonstrating that for rapid regulation of AQP2 expression, modulation of AQP2 mRNA levels is regulated via vasopressin-receptor signaling pathways.

Silent infection in clotted hemodialysis access grafts.

Thrombotic and infectious complications are frequent causes of hemodialysis vascular access failure and contribute considerably to the cost of care for chronic hemodialysis patients. Although there is clear indication for removal of patent grafts in unresolved bacteremia, there are no guidelines for the management of clotted nonfunctioning grafts. To evaluate for the existence and clinical relevance of silent infection in clotted nonfunctioning hemodialysis grafts, a study was conducted with a series of 20 hemodialysis patients who presented with fever (15 patients), or fever and clinical signs of sepsis (five patients), in whom the source of infection was not immediately localized to any organ system. Comparison was made with 21 asymptomatic patients with clotted grafts who served as control subjects. All patients and control subjects came from a pool of 115 chronic hemodialysis patients in an outpatient hemodialysis unit in the Houston metropolitan area, who were on hemodialysis for a period of time ranging from 3 to 15 yr. Indium scans were performed, followed by removal of the clotted grafts in all patients and control subjects. Bacterial cultures of the recovered surgical material and blood were done concomitantly in all study participants. Indium scans showed positive uptake in or around the clotted grafts in all of the patients and in 15 of the control subjects. Purulent material was found in the grafts in all patients and in 13 of 15 indium scan-positive control subjects. When positive, blood culture pathogens were identical to those cultured from the graft material in all instances. The predominant pathogens were Staphylococcus aureus, followed by Staphylococcus epidermidis. There was no evidence of graft infection in the control subjects if indium scan was negative. Chart review dating back to the start of dialysis revealed five past infectious episodes in the patient group, compared with four in the control group. These findings suggest that clotted nonfunctioning grafts are frequent harbingers of infection. They should be suspected as the source of infection in every hemodialysis patient that presents with fever, even in the absence of clinical signs of graft site infection.

p38 kinase activity is essential for osmotic induction of mRNAs for HSP70 and transporter for organic solute betaine in Madin-Darby canine kidney cells.

In renal cells, hypertonicity induces genes for heat shock proteins (HSP70, alpha B-crystallin), as well as enzymes and transporters directly involved in the metabolism and transport of protective organic osmolytes. While heat shock proteins are induced by many stresses including osmotic stress, the induction of the osmolytes genes appears to be specific to osmotic stress. These two adaptive mechanisms allow kidney cells to survive and function in the hypertonic environment that exists on routine basis in kidney medulla. In mammalian cells, hypertonicity induces three mitogen-activated protein kinase pathways: ERK (extracellular regulated kinase), JNK (Jun N-terminal kinase), and p38. ERK activation by osmotic stress is a consistent finding in many cells, but it is not essential for transcriptional regulation of mRNA for transporter of organic osmolyte betaine. While the growth of yeast cells on NaCl-supplemented medium is dependent on HOG1 pathway, it is still unclear which pathway mediates the adaptation to osmotic stress in mammalian cells. Here, we show that inhibition of p38 kinase activity, using the specific inhibitor SB203580 (4-(fluorophenyl)-2-(4-methylsulfonyl-phenyl)-5-(4-pyridyl) imidazole), abolishes the hypertonicity-mediated induction of mRNAs for HSP70 and betaine transporter in Madin-Darby canine kidney cells. The inhibition is dose-dependent and correlates with the in situ activity of native p38 kinase, determined as MAPKAPK-2 activity in cell extracts. As reported previously, the activities of ERK-1 and -2 were not affected by SB203580, but surprisingly, inhibition of native p38 kinase activity correlates with up-regulation of native JNK-1 activity in osmotically stressed cells. p38 mRNA is induced by hypertonic stress and is attenuated with p38 kinase inhibition. We also find that thermal induction of HSP70 mRNA is not affected by p38 kinase inhibition. Such findings suggest that p38 kinase activity is essential for the induction of genes involved in the adaptation of mammalian cells to osmotic stress and that the increased activity of JNK-1 during p38 kinase inhibition is consistent with regulation of JNK-1 by p38 kinase in osmotically stressed cells. In addition, the transduction pathways mediating HSP70 mRNA induction by different stresses appear to be divergent; osmotic induction of HSP70 is p38 kinase-dependent, while thermal induction is not.

Glomerulomegaly and proteinuria in a patient with idiopathic pulmonary hypertension.

Glomerulomegaly is a histologic finding present in idiopathic pulmonary hypertension, congenital cyanotic heart disease, morbid obesity associated with sleep apnea syndrome, sickle cell disease, and polycythemic states. This study examines the case of a 34-yr-old woman with idiopathic pulmonary artery hypertension who presented with nephrotic-range proteinuria. Kidney biopsy revealed enlarged glomeruli with mesangial-proliferative glomerulonephritis. A review of the pertinent literature and a discussion of the proposed pathophysiologic mechanisms leading to glomerulomegaly are presented.

Hypertonic induction of the cell adhesion molecule beta 1-integrin in MDCK cells.

Cells of many organisms adapt to osmotic stress by accumulating compatible organic osmolytes. In Madin-Darby canine kidney (MDCK) cells, a renal epithelial cell line widely used as a culture model for the study of osmotic regulation in mammals, extracellular hypertonicity induces genes responsible for the accumulation of organic osmolytes. We have recently cloned from these cells a partial cDNA corresponding to a member of the transmembrane 4 superfamily (tetraspan) family, CD9 antigen, and demonstrated its induction by hypertonicity [D. Sheikh-Hamad, J. D. Ferraris, J. Dragolovich, H. G. Preuss, M. B. Burg, and A. García-Pérez. Am. J. Physiol. 270 (Cell Physiol. 39): C253-C258, 1996]. An association between CD9 and potential regulatory proteins, such as the heparin-binding epidermal growth factor-like protein and the cell adhesion molecule beta 1-integrin, has been reported. Here, using beta 1-integrin-specific monoclonal antibodies and an antisense oligonucleotide probe, we demonstrate expression and hypertonic induction of beta 1-integrin in MDCK cells. Induction of the mRNA and protein occurs in 2 h and is maximal at 6 h, consistent with a regulatory role in the adaptation to osmotic stress. In addition, we show that accumulation of organic osmolytes markedly attenuates the hypertonic induction of the mRNA, a feature shared with genes involved in hyperosmotic stress response. Finally, we demonstrate that CD9 and beta 1-integrin are expressed in association at the cell membrane. Our findings suggest the existence of a cluster of integral membrane proteins that includes but may not be limited to CD9 and the adhesion molecule beta 1-integrin, which may play a role in the adaptation of kidney cells to osmotic stress, possibly at the regulatory level.

Cisplatin-induced renal toxicity: possible reversal by N-acetylcysteine treatment.

Cisplatin administration is frequently associated with renal insufficiency and tubular dysfunction. In this article, a case of massive cisplatin overdose as a result of an accidental substitution for carboplatin is reported. The patient developed oliguric renal failure, hepatotoxicity, ototoxicity, peripheral neuropathy, blindness, and severe myelosuppression. A therapeutic trial with N-acetylcysteine to reverse renal toxicity was attempted. This article reviews the literature on cisplatin nephrotoxicity, with an emphasis on possible mechanisms involved, and suggests therapy for its modification.

CD9 antigen mRNA is induced by hypertonicity in two renal epithelial cell lines.

In diverse organisms, cells adapt to hyperosmotic stress by accumulating organic osmolytes. Mammalian renal medullary cells are routinely under osmotic stress. Two renal cell lines, Madin-Darby canine kidney (MDCK) and PAP-HT25, have been widely used to study mammalian osmotic regulation. In these epithelial cells, extracellular hypertonicity induces gene transcription of proteins directly involved in the metabolism and transport of organic osmolytes. This induction is relatively specific and not part of a generalized stress response. Little is known about the signal transduction pathway between cellular detection of extracellular osmolality and increased specific gene transcription. Here, using differential mRNA display polymerase chain reaction on MDCK cells in isotonic vs. hypertonic medium, we identify a cDNA product corresponding to CD9 antigen mRNA. CD9 antigen is a cell surface glycoprotein originally found in cells of the immune system. Although CD9 antigen has been structurally characterized, its function is unclear. We further demonstrate that CD9 antigen mRNA is present in MDCK and PAP-HT25 cells and that its mRNA abundance is induced by extracellular hypertonicity, but not by heat stress. Also, we show that accumulation of organic osmolytes markedly attenuates the CD9 mRNA induction, as only recently demonstrated with genes involved in the hyperosmotic stress response. This suggests a role for CD9 antigen in this response.

Induction of gene expression by heat shock versus osmotic stress.

Elevated temperature rapidly increases expression of genes for heat shock proteins (HSP), including HSP-70. The response is presumably triggered by denaturation of cell proteins and helps in their renaturation. Hypertonicity may also denature proteins, but the protective response, which is accumulation of compatible organic osmolytes [including betaine and inositol in Madin-Darby canine kidney (MDCK) cells], apparently differs and is slow. Recently, hypertonicity was found also to increase expression of HSP-70 in MDCK cells, a response proposed to provide protection until organic osmolytes can accumulate. Our purpose was to examine whether 1) a gene involved in accumulation of organic osmolytes also responds to heat stress and 2) whether accumulation of organic osmolytes affects expression of HSP-70. We find that 1) the betaine transporter mRNA, which is greatly increased by hypertonicity (515 vs. 315 mosmol), is unaffected by high temperature (42 degrees C vs. 37 degrees C); 2) hypertonicity-induced increases in HSP-70 and betaine transporter mRNA are much greater when the medium (and cell) contain no betaine and no inositol than when high concentrations of these are present; and 3) high betaine greatly inhibits the increase in HSP-70 mRNA at high temperature. We conclude the following. 1) Although heat shock and betaine transporter genes both respond to hypertonicity, the betaine transporter is not a HSP. 2) Accumulation of organic osmolytes attenuates the HSP-70 response to hypertonicity, as it might if the HSP-70 expression were a temporizing response. 3) Betaine inhibits HSP-70 response to elevated temperature, presumably by its known effect of stabilizing proteins.

Dopamine antagonizes the actions of angiotensin II in renal brush-border membrane.

In the present study, we examined the effects of dopamine and angiotensin II (ANG II) in renal brush-border membrane (BBM). With isolated BBM vesicles, dopamine (> 10(-4) M) directly inhibited BBM 22Na+ uptake and activated phospholipase C (PLC). These effects were mimicked by DA1 agonist but not DA2 agonist and were prevented by DA1 antagonist but not DA2 antagonist, indicating the involvement of DA1 receptors. In contrast to dopamine, ANG II directly stimulated BBM 22Na+ uptake and activated BBM phospholipase A2 (PLA2). Neither dopamine nor ANG II altered BBM adenosine 3',5'-cyclic monophosphate content. In the presence of dopamine, ANG II failed to stimulate BBM Na+ uptake and PLA2. However, both DA1 and DA2 agonists similarly abrogated the actions of ANG II, and both DA1 and DA2 antagonists were required to restore ANG II actions in the presence of dopamine, indicating the involvement of both DA1 and DA2 receptors in the antagonistic effect of dopamine. Dopamine, as well as DA1 or DA2 agonists, also lowered 125I-ANG II BBM binding. In summary, these results show that, in renal BBM, dopamine impedes ANG II receptor binding and antagonizes the stimulatory effects of ANG II on Na+ uptake and PLA2. This occurred through both DA1 and DA2 receptors and independent of DA1 effects on BBM Na+ uptake or PLC.

Angiotensin II directly increases rabbit renal brush-border membrane sodium transport: presence of local signal transduction system.

In the present study, we have examined the direct actions of angiotensin II (AII) in rabbit renal brush border membrane (BBM) where binding sites for AII exist. Addition of AII (10(-11)-10(-7) M) was found to stimulate 22Na+ uptake by the isolated BBM vesicles directly. All did not affect the Na(+)-dependent BBM glucose uptake, and the effect of AII on BBM 22Na+ uptake was inhibited by amiloride, suggesting the involvement of Na+/H+ exchange mechanism. BBM proton permeability as assessed by acridine orange quenching was not affected by AII, indicating the direct effect of AII on Na+/H+ antiport system. In search of the signal transduction mechanism, it was found that AII activated BBM phospholipase A2 (PLA) and that BBM contains a 42-kDa guanine nucleotide-binding regulatory protein (G-protein) that underwent pertussis toxin (PTX)-catalyzed ADP-ribosylation. Addition of GTP potentiated, while GDP-beta S or PTX abolished, the effects of AII on BBM PLA and 22Na+ uptake, suggesting the involvement of G-protein in AII's actions. On the other hand, inhibition of PLA by mepacrine prevented AII's effect on BBM 22Na+ uptake, and activation of PLA by mellitin or addition of arachidonic acid similarly enhanced BBM 22Na+ uptake, suggesting the role of PLA activation in mediating AII's effect on BBM 22Na+ uptake. In summary, results of the present study show a direct stimulatory effect of AII on BBM Na+/H+ antiport system, and suggest the presence of a local signal transduction system involving G-protein mediated PLA activation.