Ralph Rabkin

Transcriptional Profiling of Aging in Human Muscle Reveals a Common Aging Signature

We analyzed expression of 81 normal muscle samples from humans of varying ages, and have identified a molecular profile for aging consisting of 250 age-regulated genes. This molecular profile correlates not only with chronological age but also with a measure of physiological age. We compared the transcriptional profile of muscle aging to previous transcriptional profiles of aging in the kidney and the brain, and found a common signature for aging in these diverse human tissues. The common aging signature consists of six genetic pathways; four pathways increase expression with age (genes in the extracellular matrix, genes involved in cell growth, genes encoding factors involved in complement activation, and genes encoding components of the cytosolic ribosome), while two pathways decrease expression with age (genes involved in chloride transport and genes encoding subunits of the mitochondrial electron transport chain). We also compared transcriptional profiles of aging in humans to those of the mouse and fly, and found that the electron transport chain pathway decreases expression with age in all three organisms, suggesting that this may be a public marker for aging across species.

The renal metabolism of insulin

SummaryThe kidney plays a pivotal role in the clearance and degradation of circulating insulin and is also an important site of insulin action. The kidney clears insulin via two distinct routes. The first route entails glomerular filtration and subsequent luminal reabsorption of insulin by proximal tubular cells by means of endocytosis. The second involves diffusion of insulin from peritubular capillaries and subsequent binding of insulin to the contraluminal membranes of tubular cells, especially those lining the distal half of the nephron. Insulin delivered to the latter sites stimulates several important processes, including reabsorption of sodium, phosphate, and glucose. In contrast, insulin delivered to proximal tubular cells is degraded to oligopeptides and amino-acids by one of two poorly delineated enzymatic pathways. One pathway probably involves the sequential action of insulin protease and either GIT or non-specific proteases; the other probably involves the sequential action of GIT and lysosomal proteases. The products of insulin degradation are reabsorbed into the peritubular capillaries, apparently via simple diffusion. Impairment of the renal clearance of insulin prolongs the half-life of circulating insulin by a number of mechanisms and often results in a decrease in the insulin requirement of diabetic patients. Much needs to be learned about these metabolic events at the subcellular level and how they are affected by disease states. Owing to the heterogeneity of cell types within the kidney and to their anatomical and functional polarity, investigation of these areas will be challenging indeed.

Effect of Renal Disease on Renal Uptake and Excretion of Insulin in Man

Abstract Renal handling of insulin was studied over plasma insulin levels of 6 to 40 μU per milliliter in 13 patients by renal-vein catheterization. The kidney in normal subjects and 7 patients with moderate renal insufficiency — glomerular filtration rate (GFR) over 22.5 ml per minute per kidney per 1.73 M2 — removed 39 ± 4 per cent (SD) of the insulin from arterial plasma. Severe renal insufficiency (GFR less than 6) reduced insulin uptake to 9 per cent in four subjects, two with diabetic glomerulosclerosis. Mean GFR in normal subjects was 61 ± 11 (SD) and renal insulin extraction —renal plasma flow (RPF) × % uptake — was 106 ± 28 (SD). These findings suggest that a decreased uptake of insulin by damaged kidneys accounts in part for the diminished insulin requirements seen in patients with diabetic glomerulosclerosis and that all the renal uptake of insulin cannot be explained by glomerular filtration alone.

Impaired JAK-STAT signal transduction contributes to growth hormone resistance in chronic uremia

Chronic renal failure (CRF) is associated with resistance to the growth-promoting and anabolic actions of growth hormone (GH). In rats with CRF induced by partial renal ablation, 7 days of GH treatment had a diminished effect on weight gain and hepatic IGF-1 and IGFBP-1 mRNA levels, compared with sham-operated pair-fed controls. To assess whether GH resistance might be due to altered signal transduction, activation of the JAK-STAT pathway was studied 10 or 15 minutes after intravenous injection of 5 mg/kg GH or vehicle. Hepatic GH receptor (GHR) mRNA levels were significantly decreased in CRF, but GHR protein abundance and GH binding to microsomal and plasma membranes was unaltered. JAK2, STAT1, STAT3, and STAT5 protein abundance was also unchanged. However, GH-induced tyrosine phosphorylation of JAK2, STAT5, and STAT3 was 75% lower in the CRF animals. Phosphorylated STAT5 and STAT3 were also diminished in nuclear extracts. The expression of the suppressor of cytokine signaling-2 (SOCS-2) was increased twofold in GH-treated CRF animals, and SOCS-3 mRNA levels were elevated by 60% in CRF, independent of GH treatment. In conclusion, CRF causes a postreceptor defect in GH signal transduction characterized by impaired phosphorylation and nuclear translocation of GH-activated STAT proteins, which is possibly mediated, at least in part, by overexpression of SOCS proteins.

The prophylactic value of propranolol in angina pectoris

Abstract In a double-blind trial of propranolol over an 8 week period in 16 patients with angina pectoris, drug and placebo were each given at random for 2 two-week periods to equal numbers of patients according to one of four possible paired sequences. At a uniform daily dosage of 200 mg. given in four divided doses, the individual glyceryl trinitrate consumption, which served as the criterion of therapeutic response, was significantly lower with propranolol therapy in 10 patients, whereas 6 reported no preference for either medication. In a separate single-blind trial in 20 patients in which the dosage of propranolol was adjusted and the duration of drug and placebo medication varied according to each individual response, significant improvement in the angina was observed with propranolol therapy in 16 patients. After discontinuation of propranolol therapy in a number of cases in both trials, a carry-over effect was noted which appeared to be related to the duration of therapy.

Growth hormone resistance in uremia, a role for impaired JAK/STAT signaling

Resistance to growth hormone (GH) is a significant complication of advanced chronic renal failure. Thus while the circulating GH levels are normal or even elevated in uremia, resistance to the hormone leads to stunting of body growth in children and contributes to muscle wasting in adults. Insensitivity to GH is the consequence of multiple defects in the GH/insulin-like growth factor-1 (IGF-1) system. Expression of the GH receptor may be reduced, although this is not a consistent finding, GH activation of the Janus kinase 2-signal transducer (JAK2) and activator of transcription (STAT) signal transduction pathway is depressed and this leads to reduced IGF-1 expression, and finally there is resistance to IGF-1, a major mediator of GH action. We review these various defects with an emphasis on the GH-activated JAK2-STAT5 pathway, since this pathway is essential for normal body growth and there has been recent progress in our understanding of the perturbations that occur in uremia.

Suppressors of cytokine signaling in health and disease.

Cytokines consist of a large family of secreted proteins, including pro-inflammatory agents, growth hormone and erythropoietin, that utilize the Janus kinase (JAK) signal transducer and activator of transcription (STAT) signal transduction pathway to mediate many of their key physiologic and pathologic actions. These actions include cytokine-mediated inflammation, immunoregulation, hematopoiesis and growth. The JAK-STAT pathway is regulated by several processes, among which negative feedback regulation by the suppressors of cytokine signaling (SOCS), members of a family of eight proteins, is particularly important. Each cytokine induces one or more specific SOCS proteins that in turn down-regulate the signal initiated by the cytokine. Through their impact on the cytokine-activated JAK-STAT pathway, the SOCS proteins are involved in many diseases that come to the attention of the pediatric nephrologist. For example, an increase in the expression of SOCS-2 and -3 may be a cause of growth hormone resistance and thus may contribute to the growth retardation that affects children with chronic renal failure. Because of their obvious biologic importance, the SOCS proteins have been the subject of intense research that includes the development of strategies to utilize these proteins to control cytokine-induced JAK/STAT signal transduction for therapeutic purposes.

Chronic Uremia Attenuates Growth Hormone–Induced Signal Transduction in Skeletal Muscle

Malnutrition and muscle wasting are common in chronic renal failure (CRF) and adversely affect morbidity and mortality. Contributing to the muscle wasting is resistance to growth hormone (GH). For testing whether impaired GH signaling is a cause of the skeletal muscle GH resistance and for elucidating its mechanisms, muscle GH signaling and action were studied in GH-deficient rats with surgically induced CRF and sham-operated pairfed control rats. GH treatment increased gastrocnemius muscle IGF-1 mRNA levels significantly in control but not in CRF rats. GH-activated Janus-associated kinase 2 (JAK2)-signal transducers and activators of transcription 5 (STAT5) signaling was impaired in CRF rats, despite normal GH receptor (GHR), JAK2, and STAT5 protein levels. Phosphorylation of the GHR, JAK2, and STAT5 in response to GH was depressed by nearly half in CRF (P < 0.05), and nuclear phospho-STAT5 levels were depressed by approximately one third (P < 0.01). GH-stimulated suppressors of cytokine signaling 2 mRNA levels were significantly higher in CRF. This may be related to inflammatory cytokine activity because C-reactive protein levels were elevated. Muscle protein-tyrosine phosphatase activity was also increased significantly by twofold. In conclusion, rats with CRF acquire skeletal muscle resistance to GH that is caused at least in part by impaired JAK2-GHR-STAT5 phosphorylation and nuclear STAT5 translocation. Furthermore, it seems that the attenuated JAK2-STAT5 phosphorylation may be caused by at least two different processes. One involves depressed phosphorylation of the signaling proteins because of increased suppressors of cytokine signaling 2 expression that may be linked to low-grade inflammation. The other may involve increased signaling protein dephosphorylation because of heightened protein-tyrosine phosphatase activity.

Factors Influencing the Handling of Insulin by the Isolated Rat Kidney

The renal handling of immunoreactive insulin was studied in the isolated perfused normothermic rat kidney to determine (a) the relative contributions of glomerular clearance and peritubular clearance to the renal clearance of insulin under different conditions, (b) what metabolic factors influence the ability of tubular cells to remove insulin from the glomerular filtrate and the peritubular circulation, and (c) whether the same factors influence the luminal and contraluminal uptake of insulin.In control kidneys the organ clearance of insulin (OCi) was 974+/-63 mul/min (SEM), of which a maximum of 46% could theoretically be accounted for by filtration. OCi was not altered by fasting, lack of exogenous fuel (glucose), or the addition of cyanide. The glomerular filtration rate did not correlate with the OCi, but there was a significant (P < 0.001) negative correlation (r = -0.828) between the peritubular clearance and glomerular filtration rate. Both N-ethylmaleimide and cold (10 degrees C) reduced the rate of insulin removal. Fractional excretion of filtered insulin (9.7+/-1.7% in controls) was not significantly altered by fasting or perfusing without glucose. In contrast, KCN increased fractional excretion of insulin to 41.9+/-3.7% whereas cold increased fractional excretion to 69.0+/-3.3%. This study indicates that renal tubular cells remove insulin from the tubular lumen and the peritubular compartment. Furthermore, the data suggest that insulin removal by tubular cells is a temperature-sensitive process consisting of two different systems. The system associated with the luminal aspect of the cell appears to be dependent on oxidative metabolism, whereas the system associated with the contraluminal aspects of the cell appears to be independent thereof. Under several circumstances when the glomerular clearance of insulin falls thereby reducing the amount of insulin absorbed by the luminal aspect of the cell, contraluminal uptake increases, and a constant rate of insulin removal is maintained by the kidney.

Binding and Degradation of Insulin by Isolated Renal Brush Border Membranes

Filtered proteins including insulin are absorbed in the proximal tubule by means of pinocytosis. The first step in this process is binding of the protein to brush border membrane. As it is not known whether absorption exhibits specificity, we set out to determine whether specific binding sites for insulin are present in brush border membranes. Rabbit-isolated brush border membranes were incubated with 125I-insulin and varying concentrations of cold insulin or other peptide hormones. Binding and degradation of 125I-insulin occurred in a time- and temperature–dependent manner. Native insulin competitively inhibited 125I-insulin binding, but calcitonin, arginine vasopressin, glucagon, and growth hormone (10−6 M) were relatively ineffective. Nonspecific binding averaged one-third of the total radioactivity bound. Scatchard analysis of binding data revealed two classes of insulin receptors: high affinity, low capacity receptors and low affinity, high capacity receptors. Gel filtration analysis of 125I-insulin exposed to brush border membrane revealed the formation of low-molecular-weight products similar to that produced by intact kidneys. The degrading process exhibited some specificity, for cold insulin (10−6 M) was more effective than calcitonin, vasopressin, glucagon, or growth hormone in inhibiting degradation (32% versus <13% inhibition; P < 0.01). Whether this reflects inhibition of insulin specific binding before exposure to degradation or inhibition of specific enzymes is unclear. In summary, it appears that renal brush border membranes have a major insulin-specific receptor component that could potentially mediate tubular insulin absorption. In addition, there is a smaller nonspecific component that may also have the potential to mediate insulin absorption. Finally, it appears that brush border membranes have the ability to degrade insulin to low-molecular-weight products by a process that exhibits some specificity for insulin.