TGF-beta receptor expression and binding in rat mesangial cells: modulation by glucose and cyclic mechanical strain.

BACKGROUND: Transforming growth factor-beta (TGF-beta) is a causal factor in experimental glomerulosclerosis, and it mediates the increased extracellular matrix (ECM) accumulation that occurs in cultured mesangial cells (MCs) exposed to high glucose concentrations and cyclic mechanical strain. This change is associated with increased levels of TGF-beta, but may also involve alterations in receptor expression and binding. METHODS: Rat MCs cultured in media containing either 8 or 35 mM glucose were seeded into culture plates with elastin-coated flexible bottoms. Thereafter, they were subjected to cyclic stretch or static conditions and then examined for 125I-TGF-beta1 binding and expression of TGF-beta receptors at the gene and protein levels. RESULTS: Kinetic studies showed that MCs bound TGF-beta1 in a time- and concentration-dependent manner, expressing 6800 high-affinity receptors per cell, with an apparent dissociation constant (Kd) of 15.4 pM, while cross-linking analysis identified three TGF-beta receptors (betaR) corresponding to betaRI, betaRII, and betaRIII of 54, 73, and 200 kDa, respectively. Immunocytochemical studies of betaRI and betaRII protein revealed MC expression in a homogeneous, punctate distribution, whereas Northern analysis demonstrated the presence of the corresponding mRNAs. Exposure to cyclic stretching significantly increased (10%) the overall number of TGF-beta receptors, whereas ligands associated with betaRs I, II, and III also increased (25 to 50%). The finding of increased (30 to 40%) betaRI and betaRII transcript levels and immunoreactive protein (163 and 59%, respectively) in the absence of significant changes in the apparent Kd indicated that stretch-induced binding was the result of increased receptor synthesis and expression and not due to a change in binding affinity. In a similar, but more dramatic fashion, exposure to high glucose also elevated (50%) the receptor number, as well as the amount of ligands associated with betaRs I, II, and III (100 to 250%). This same treatment also increased the levels of betaRI and betaRII mRNA (30 to 40%) and the immunoreactive protein (82 and 82%, respectively), without significantly altering the binding affinity of the receptor. A concerted or synergistic effect of both stimuli was not evidenced. CONCLUSION: These results suggest that the modulation of TGF-beta receptors may be an additional control point in mediating the glucose- and mechanical force-induced increase in ECM deposition by MCs.

Mechanical strain of glomerular mesangial cells in the pathogenesis of glomerulosclerosis: clinical implications.

Due to their elasticity, glomeruli will undergo excessive expansion and repetitive cycles of distension contraction under conditions of impaired glomerular pressure autoregulation and systemic arterial hypertension. These alterations in glomerular volume are associated with mesangial cell stretch which in turn stimulates the synthesis and deposition of ECM with eventual mesangial expansion and glomerulosclerosis. Hyperactivity of growth factors with prosclerotic activity is an important component in the translation of cellular mechanical strain into the abnormal metabolism of ECM components. Although mesangial cell mechanical strain is expected to occur in both remnant glomeruli and in glomeruli of diabetic kidneys, quantitatively different factors will determine the resultant metabolic consequences. In remnant glomeruli, the mechanical stretch is intense, being accounted for largely by the marked glomerular hypertrophy and increased glomerular compliance. In diabetic glomeruli, however, the mechanical stretch is less prominent but its effect on ECM synthesis is markedly aggravated by the presence of hyperglycaemia. There are presently no methods clinically available to diminish the prosclerotic action of growth factors at the glomerular level. In addition, there are no effective means to specifically improve glomerular pressure autoregulation. Therefore, current therapies must be aimed at decreasing systemic arterial pressure, blocking angiotensin II action and reducing glomerular hypertrophy. While there are effective drugs for the treatment of hypertension and for angiotensin II inhibition, protein restriction is the only measure available to diminish glomerular hypertrophy. Finally, in diabetes correction of systemic and glomerular hypertension should be coupled with strict glycaemic control to correct both glomerular autoregulation and increased ECM deposition.

Selective review of key perioperative renal-electrolyte disturbances in chronic renal failure patients.

The medical care of chronic renal failure patients is often complicated by the comorbid conditions of hypertension and coronary artery disease in the perioperative period. The limitations on solute and water excretion imposed by renal dysfunction increase the susceptibility of this population to both salt deficit and surfeit, as well as hyponatremia and hypernatremia perioperatively. Accurate assessment and successful treatment of these complications in renal failure patients require understanding of the concept of electrolyte-free water, proper utilization of diuretics, and calculated prescription of fluid therapy. The presence of hyperkalemia in the adapted renal failure patient generally indicates a severe reduction in glomerular filtration, such that nonrenal hypokalemic treatments are imperative. IV calcium-based therapy and infusion of insulin with glucose represent the mainstays of immediate therapy, and sodium bicarbonate therapy should be given only when severe acidemia is present. Perioperative aggravation of preexistent hypertension is common. Rebound hypertension attributable to injudicious adjustment of the medical regimen should be diligently searched for first, before any new therapies are recommended. Relief of pain or anxiety may be all that is necessary. Briefly acting calcium channel blocker therapy should not be employed in these cases, and smooth IV control by a variety of agents is preferable, the choice of the agent contingent on the clinical scenario.

Effects of oral antihyperglycemic agents on extracellular matrix synthesis by mesangial cells.

BACKGROUND: Increased expression of the glucose transporter GLUT1 in mesangial cells (MCs) markedly stimulates glucose transport and the formation of extracellular matrix (ECM), even when ambient glucose concentrations are low. Certain antihyperglycemic agents cause GLUT1 overexpression and increase glucose transport in various tissues. However, their effects on the kidney are unknown. Because diabetic glomerulosclerosis is characterized by the accumulation of mesangial matrix, was studied the effects of antihyperglycemic agents on matrix metabolism in MCs cultured either in 8 or 20 mM glucose. METHODS: Membrane-associated GLUT1 was measured by immunoblotting. The initial rate of glucose transport was determined according to the 2-deoxy-D[14C(U)]glucose uptake. Collagen metabolism was studied by metabolic radiolabeling with [14C]-proline. Fibronectin in the medium was measured by ELISA. GLUT1 mRNA was estimated by Northern analysis. RESULTS: The sulfonylurea tolazamide increased GLUT1 protein expression by 107 and 69% in 8 and 20 mM glucose-grown cells, respectively. However, GLUT1 mRNA levels remained unchanged. Transporter-dependent deoxyglucose uptake was increased by tolazamide up to 184% in a dose-dependent fashion and was evident at both glucose concentrations after three or five days of exposure to the drug. Tolazamide significantly stimulated transforming growth factor-beta 1 (TGF-beta 1) secretion and the total synthesis of collagen and collagen and fibronectin accumulation in the medium of MCs maintained in high or low glucose concentrations. The biguanide metformin did not alter GLUT1 expression, glucose transport, fibronectin formation, or collagen metabolism, except at high concentrations. CONCLUSION: Tolazamide markedly enhances ECM synthesis and accumulation in MCs probably by stimulating GLUT1 expression, glucose transport and TGF-beta 1 secretion, irrespective of the ambient glucose concentration. This effect was dose-dependent and minimally inducible by metformin.

Mechanical strain- and high glucose-induced alterations in mesangial cell collagen metabolism: role of TGF-beta.

Cultured mesangial cells (MC) exposed to cyclic mechanical strain or high glucose levels increase their secretion of transforming growth factor-beta1 (TGF-beta1) and collagen, suggesting possible mechanisms for the development of diabetic renal sclerosis resulting from intraglomerular hypertension and/or hyperglycemia. This study examines whether glucose interacts with mechanical strain to influence collagen metabolism and whether this change is mediated by TGF-beta. Accordingly, rat MC were grown on flexible-bottom plates in 8 or 35 mM glucose media, subjected to 2 to 5 d of cyclic stretching, and assayed for TGF-beta1 mRNA, TGF-beta1 secretion, and the incorporation of 14C-proline into free or protein-associated hydroxyproline to assess the dynamics of collagen metabolism. Stretching or high glucose exposure increased TGF-beta1 secretion twofold and TGF-beta1 mRNA levels by 30 and 45%, respectively. However, the combination of these stimuli increased secretion greater than fivefold without further elevating mRNA. In 8 mM glucose medium, stretching significantly increased MC collagen synthesis and breakdown, but did not alter accumulation, whereas those stretched in 35 mM glucose markedly increased collagen accumulation. TGF-beta neutralization significantly reduced baseline collagen synthesis, breakdown, and accumulation in low glucose, but had no significant effect on the changes induced by stretch. In contrast, the same treatment of MC in high glucose medium greatly reduced stretch-induced synthesis and breakdown of collagen and totally abolished the increase in collagen accumulation. These results indicate that TGF-beta plays a positive regulatory role in MC collagen synthesis, breakdown, and accumulation. However, in low glucose there is no stretch-induced collagen accumulation, and the effect of TGF-beta is limited to basal collagen turnover. In high glucose media, TGF-beta is a critical mediator of stretch-induced collagen synthesis and catabolism, and, most importantly, its net accumulation. These data have important implications for the pathogenesis and treatment of diabetic glomerulosclerosis.

Role of glomerular mechanical strain in the pathogenesis of diabetic nephropathy.

Glomerular rigidity limits the glomerular expansion and mesangial cell (MC) stretch induced by variations in intracapillary pressure. In tissue culture, MC stretch stimulates synthesis of extracellular matrix components (ECM). Therefore, altered glomerular rigidity in diabetes may influence ECM accumulation by modulating the glomerular distention and MC stretch associated with glomerular hypertension. An ambient of high glucose concentration per se also enhances MC formation of ECM, possibly altering the cellular response to mechanical stretch. In this study, compliance was measured in isolated perfused glomeruli from streptozotocin-injected rats at four days (4d-D), five weeks (5w-D) and six months (6m-D) after induction of diabetes. In addition, collagen metabolism induced by stretch was investigated in MC cultured in 8 and 35 mM glucose concentrations. Glomerular compliance was normal in 5w-D rats and moderately increased in 4d-D (16%) and 6m-D animals (14%). As compared to static cultures. MC stretch increased total collagen synthesis (8 mM, 50%; 35 mM, 27%) and catabolism. However, while the fraction of newly formed collagen being catabolized increased in 8 mM-stretched cultures, in 35 mM-stretched it was unchanged. This resulted in marked increase in the net collagen accumulated in the incubation medium (4 vs. 24%) and cell layer 5 vs. 15%) only in the latter. In diabetes, the largely unaltered glomerular stiffness renders hypertension-induced MC stretch unopposed. More importantly, the accumulation of ECM caused by any degree of mechanical strain is greatly aggravated in a milieu of high glucose concentration.

Cyclic stretching force selectively up-regulates transforming growth factor-beta isoforms in cultured rat mesangial cells.

Glomerular distention from increased intraglomerular pressure stretches mesangial cells (MCs). Stretching MCs in culture stimulates extracellular matrix accumulation, suggesting that this may be a mechanism for glomerular hypertension-associated glomerulosclerosis. We examined whether mechanical stretching serves as a stimulus for the synthesis and activation of the prosclerotic molecule transforming growth factor (TGF)-beta, thus providing a potential system for auto-induction of extracellular matrix. Rat MCs cultured on flexible-bottom plates were subjected to cyclic stretching for up to 3 days and then assayed for TGF-beta mRNA, secretion of TGF-beta, and localization of active TGF-beta by immunostaining. MCs contained mRNA for all three mammalian isoforms of TGF-beta. Cyclic stretching for 36 hours increased TGF-beta1 and TGF-beta3 mRNA levels approximately twofold, without altering the levels of TGF-beta2 mRNA. This was followed at 48 to 72 hours by the increased secretion of both latent and active TGF-beta1. Latent, but not active, TGF-beta3 secretion also increased whereas the levels of TGF-beta2 were unaffected by mechanical force. The stretching force in this system is unequally distributed over the culture membrane. Localization of active TGF-beta by immunostaining demonstrated that the quantity of cell-associated cytokine across the culture was directly proportional to the zonal amplitude of the stretching force. These results demonstrate that stretching force stimulates MCs to selectively release and activate TGF-beta1. This mechanical induction of TGF-beta1 may help explain the increased extracellular matrix associated with intraglomerular hypertension.

Regulation of glomerular volume in normal and partially nephrectomized rats.

Glomerular extracellular matrix accumulation may derive from the stretching of mesangial cells caused by excessive glomerular dilatation. The relationship of glomerular volume (VG) to intraglomerular pressure, expressed as compliance or as mean VG in the isolated, perfused rat glomerulus, was used to analyze factors that regulate VG. Glomeruli were highly distensible over the normal and relevant abnormal range of pressure. Compliance increased directly with basal VG (P < 0.001), i.e., larger glomeruli dilated more than smaller ones at any given pressure. Perfusion with atrial natriuretic peptide did not alter compliance, and inhibitors of nitric oxide synthesis exerted only a trivial effect. VG expansion was consistently reduced by angiotensin II, but this effect was small (3.8%, P < 0.001). After subtotal nephrectomy, compliance increased by 59% in the remnant glomeruli (P < 0.001); 22% of this increase was attributable to structural changes, and the remainder was attributable to the large basal VG of the hypertrophied glomeruli. Thus the major determinants of VG expansion include capillary wall tension, basal VG, and intrinsic distensibility, which is markedly influenced by the character of the extracellular matrix and only slightly altered by an angiotensin II-modified mesangial cell tone.

Intraglomerular pressure and mesangial stretching stimulate extracellular matrix formation in the rat.

To define the interplay of glomerular hypertension and hypertrophy with mesangial extracellular matrix (ECM) deposition, we examined the effects of glomerular capillary distention and mesangial cell stretching on ECM synthesis. The volume of microdissected rat glomeruli (Vg), perfused ex vivo at increasing flows, was quantified and related to the proximal intraglomerular pressure (PIP). Glomerular compliance, expressed as the slope of the positive linear relationship between PIP and Vg was 7.68 x 10(3) microns 3/mmHg. Total Vg increment (PIP 0-150 mmHg) was 1.162 x 10(6) microns 3 or 61% (n = 13). A 16% increase in Vg was obtained over the PIP range equivalent to the pathophysiological limits of mean transcapillary pressure difference. A similar effect of renal perfusion on Vg was also noted histologically in tissue from kidneys perfused/fixed in vivo. Cultured mesangial cells undergoing cyclic stretching increased their synthesis of protein, total collagen, and key components of ECM (collagen IV, collagen I, laminin, fibronectin). Synthetic rates were stimulated by cell growth and the degree of stretching. These results suggest that capillary expansion and stretching of mesangial cells by glomerular hypertension provokes increased ECM production which is accentuated by cell growth and glomerular hypertrophy. Mesangial expansion and glomerulosclerosis might result from this interplay of mechanical and metabolic forces.