Growth hormone action is blunted by acidosis in experimental uremia or acid load.

The effects of rhGH (H) daily injection (2 IU/d) and of vehicle (V) during two weeks were studied in young (60 g) growing rats. Experiment I was performed in uremic rats (mean plasma creatinine: 65-71 mumol/l) either acidotic (mean HCO3-:11.5 mmol/l: UAH, n = 20; UAV, n = 18), or with corrected acidosis by addition of NaHCO3 in the diet (mean HCO3-:26 mmol/l: UBH, n = 25; UBV, n = 23). Experiment II used rats with normal renal function (plasma creatinine: 25 mumol/l), either non-acidotic but food restricted to the dietary intake of uremic rats (CRH: n = 18, CRV: n = 18), or rendered acidotic by NH4Cl (CAH: n = 16, CAV: n = 16). GH induced an augmentation of body weight and length gains in non-acidotic uremic rats (+33% and +41%: p < 0.01), and in non-acidotic food restricted rats (+13% and 42%: p < 0.05 and p < 0.0001). This was associated with increased protein synthesis rate in muscle and with little change of food intake as well as of plasma IGF 1. Plasma IGF 1 kept the same relationship to food intake, regardless of treatment, but length gain for each level of plasma IGF 1 was enhanced by GH in GH responding groups. In both acidotic rat groups, GH altered none of the parameters studied. Thus: 1) the presence of severe metabolic acidosis blunts the response to GH in uremic and non-uremic rats. 2) The increment of growth rate does not depend on a rise of plasma IGF 1.

Acidosis prevents growth hormone-induced growth in experimental uremia.

The effects of 2 weeks of a daily injection (2 IU/day) of recombinant human growth hormone (GH) were studied in young (60-g) growing rats in two experiments. Experiment 1 was performed in uremic animals (mean plasma creatinine 65-71 mumol/l) who were either acidotic (mean bicarbonate 11.5 mmol/l) or had acidosis corrected (mean bicarbonate 26 mmol/l) by addition of sodium bicarbonate to the diet. Experiment 2 used rats with normal renal function (plasma creatinine 25 mumol/l) who were either non-acidotic but restricted to the dietary intake of uremic rats or rendered acidotic by ammonium chloride. GH induced an increase in body weight and length in non-acidotic uremic (+33% and +41%) and in non-acidotic food-restricted (+13% and +42%) rats, associated with an increased rate of protein synthesis and little change in plasma insulin-like growth factor 1 (IGF 1). In both acidotic rat groups, GH altered none of the parameters studied. Thus: (1) the presence of severe metabolic acidosis blunts the response to GH in uremic and non-uremic rats and (2) the increment of growth rate does not depend on a rise in plasma IGF 1.

Continuous enteral feeding in uremic rats.

Because of constant uremia-induced anorexia, food restriction of normal rats is generally used to study the consequences of uremia. The effects of a normal food supply in uremic rats has never been tested, since no author has succeeded in providing normal intakes. Uremic rats either fed ad lib (U rats, n = 12) or force-fed through a gastric catheter (UF rats, n = 10), and sham-operated rats (C rats, n = 10) were compared from days 7 to 21 after surgery. U rats had lower food intake (13.8 vs. 17 g/day), weight gain (5.16 vs. 6.23 g/day), length gain (4 vs. 5 mm/day), nitrogen balance (228 vs. 279 mg/day) and muscle fractional protein synthesis rate (9.5 vs. 10.6%) measured in vivo by 3H-phenylalanine injection (p < 0.05 for all). All parameters were restored to normal values in UF rats, possibly due to correction of underhydration in addition to undernutrition. Such continuous enteral feeding may provide a model for normal nutritional supply in uremia.

Subtotal but not unilateral nephrectomy induces hyperplasia and protooncogene expression.

It is generally accepted that renal compensatory growth after unilateral nephrectomy (Uni) is due to prominent hypertrophy with no involvement of protooncogenes. Neither the balance between hypertrophy and hyperplasia nor the expression of the early-growth-related genes has been studied after subtotal nephrectomy (Nx). The occurrence of cystic tubular dilatations after Nx may suggest an excessive cell proliferation in this model. We measured DNA, RNA, and protein content, number of nuclei per tubular section, as well as c-fos, c-jun, c-myc, c-H-ras, c-sis, and c-erb-B2 protooncogene expression in kidneys taken at time of surgery and 2, 7, and 14 days after sham operation (control rats), Uni, or Nx. After Uni, hyperplasia was greater than expected (+79% for DNA at day 14) and was associated with moderate hypertrophy (+11% for protein/DNA ratio). After Nx, compensatory growth was due only to hyperplasia (+117% for DNA at day 14), with unchanged protein/DNA ratio (vs. Uni, P < 0.02). The greater hyperplasia after Nx was confirmed by nuclei counting. The protooncogene mRNA expression was constantly absent in control and Uni rats, whereas that of c-fos and c-jun genes was detected in Nx rats at day 14 with a 2- to 12-fold increment. The c-fos and c-jun protein levels were also increased at that time in Nx rats. This suggests the following: 1) the cellular events following Uni and Nx are not the same, and 2) the late protooncogene expression in Nx exclusively could favor a particular type of cell proliferation possibly more related with cystic formation than with actual compensatory growth.

In vivo unaltered muscle protein synthesis in experimental chronic metabolic acidosis.

Chronic metabolic acidosis (CMA) is a major cause of growth defect, implying disturbances of protein metabolism. Previously, in vivo studies performed in the fasting state showed enhanced whole body protein turnover, whereas in vitro studies showed unchanged muscle protein synthesis. The present study is the first to determine the effects of CMA on muscle protein synthesis and degradation in vivo. Two studies were performed in 60 g male rats fed a 30% casein diet. In study I, one group was sham-operated (C rats), and two groups underwent subtotal nephrectomy. One of them developed acidosis (UA rats) which was corrected in the other by NaHCO3 in the diet (UNA rats). Study II compared sham-operated rats rendered acidotic by NH4Cl in the drinking water (CA rats) and normal pair-fed (CNA) rats. Fractional protein synthesis rate (FSR) was determined in gastrocnemius muscle after injection of 3H-phenylalanine. Fractional protein degradation rate (FDR) was calculated as FSR minus fractional rate of muscle growth (FGR). In study I, UA rats had lower growth and N balance (163 +/- 12 vs. 216 +/- 11 mg N/day; P < 0.001) than UNA rats, despite identical food intake (11 g/day). This was associated with identical FSR (10.4 +/- 0.5 vs. 10.9 +/- 0.5%/day), but enhanced protein degradation (6.30 +/- 0.99 vs. 5.10 +/- 0.71%/day; P < 0.05). Plasma insulin, C peptide, PTH and corticosterone did not differ in UA and UNA rats, whereas plasma IGF-I was markedly reduced (147 +/- 21 vs. 283 +/- 27 ng/ml; P < 0.01) in UA rats.(ABSTRACT TRUNCATED AT 250 WORDS)