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Query: UMLS:C0033687 (
proteinuria
)
24,015
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Proteinaceous cast formation in the distal nephron of the kidney from low molecular weight
proteinuria
is a significant, but poorly characterized, cause of renal failure. To study this phenomenon, we: (a) microperfused the loop segment (LS) of rats in vivo with artificial tubule fluid (ATF) containing four different low molecular weight proteins, 0.01-50 mg/ml, to detect alterations in LS function, and (b) examined the interaction between several proteins and Tamm-Horsfall glycoprotein (THP) in vitro with turbidity and dynamic light-scattering measurements. Perfusion of the LS for less than 2 min with cast-forming proteins (Bence Jones protein [BJP3] and myoglobin) decreased chloride absorption and elevated early distal tubule fluid (ED) [Cl-], compared with results obtained with control perfusions that used ATF alone. BJP3 decreased chloride absorption in a concentration-dependent fashion. Perfusion with non-cast-forming proteins (albumin and BJP1) enhanced chloride absorption and decreased ED [Cl-]. In vitro, proteins that had isoelectric points (pI) greater than 5.1 aggregated with THP. Aggregation was enhanced with increasing [NaCl] or [
CaCl2
]. Albumin (pI 4.8) and beta-lactoglobulin (pI 5.1) did not coprecipitate. The molecular size of THP alone increased when [NaCl] greater than 80 mM. Thus, cast-forming proteins aggregated with THP in vitro and caused in vivo LS dysfunction, which elevated ED [Cl-], facilitating aggregation. In contrast, non-cast-forming proteins either did not interact with THP or lowered ED [Cl-], which did not provide an environment for aggregation. Altered LS function and interaction of some proteins with THP were related to different physicochemical properties of the proteins and independently contributed to the formation of proteinaceous casts in the kidney.
...
PMID:Mechanisms of intranephronal proteinaceous cast formation by low molecular weight proteins. 229 21
Metabolic acidosis is a common finding in uremia. The metabolic consequences, however, are poorly understood. Thus, the aim of our study was to assess the effect of chronic metabolic acidosis in 5/6-nephrectomized male Sprague-Dawley rats given a normal (18%; n = 19) and a low-protein diet (8%; n = 23). Each of these groups was sequentially given CaCO3 and
CaCl2
in the drinking water for a fortnight each. The animals were randomly assigned to start either with CaCO3 or
CaCl2
(random cross-over design). The blood pH decreased significantly in both
CaCl2
groups (18% protein: CaCO3 7.18 vs.
CaCl2
7.11; 8% protein: CaCO3 7.26 vs.
CaCl2
7.09) as did standardized base excess (18% protein: CaCO3-5.9 vs.
CaCl2
-9.7; 8% protein: CaCO3-3.6 vs.
CaCl2
-12.6). Food intake declined during acidosis in both groups, but more in the 18% protein group. The same occurred with body weight (g) in the 18% group, which decreased dramatically (8% protein: CaCO3 389 vs.
CaCl2
390; 18% protein: CaCO3 413 vs.
CaCl2
366). The change in body weight was reflected in the urinary urea excretion (mg/24 h/g food) (8% protein: CaCO3 0.9 vs.
CaCl2
1.0; 18% protein: CaCO3 2.2 vs.
CaCl2
30.8). There was a significant increase in
proteinuria
(mg/24 h) in the 8% group (CaCO3 10 vs.
CaCl2
15), while in the 18% group no real change occurred (CaCO3 24 vs.
CaCl2
18). Factoring the
proteinuria
for food intake, however, also resulted in a tendency towards an increased
proteinuria
in the 18% group.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:A low-protein diet protects uremic rats against the negative sequelae of metabolic acidosis. 232 98
Several lines of evidence suggest that increased neuraminidase activity may be responsible for the loss of glomerular N-acetylneuraminic acid (AcNeu) observed in various glomerular diseases. However, virtually no information is available on the activity of neuraminidase in glomeruli or the potential role of this enzyme in glomerular pathophysiology. Utilizing 2'-(4-methylumbelliferyl)-alpha-D-N-acetylneuraminic acid (4MU-AcNeu) as substrate, we defined optimal assay conditions and characterized neuraminidase activity in glomeruli and, for comparison, in other renal fractions and liver. Neuraminidase activity in glomeruli, cortex and tubules was maximal at pH 4.4. The Km for 4MU-AcNeu was estimated to be 195 microM for glomeruli and 226 microM for cortex. Glomerular neuraminidase was inhibited by AcNeu (90% at 25 mM) and high concentrations of Triton X-100 (26% at 0.5%), but unaffected by
CaCl2
, EDTA or N-ethylmaleimide (each 1 mM). Neuraminidase activity (nmol/h per mg of protein; mean +/- S.E.M.) in normal rat kidney was: cortex, 14.47 +/- 0.76; medulla, 7.85 +/- 0.64; papilla, 2.64 +/- 0.11; tubules, 13.79 +/- 0.70; glomeruli, 5.57 +/- 0.28. In comparison, neuraminidase activity in rat liver was 2.58 +/- 0.14. Puromycin aminonucleoside (PAN)-induced nephrotic syndrome is a model of glomerular disease in which the loss of glomerular AcNeu is well documented. In two separate studies, we observed no change in the specific activity of neuraminidase in either glomeruli or cortex isolated from rats treated with PAN (15 mg/100 g, intraperitoneally) and killed at either the onset or the peak of
proteinuria
. Results were similar whether neuraminidase activity was expressed per mg of protein or per microgram of DNA.
...
PMID:Renal neuraminidase. Characterization in normal rat kidney and measurement in experimentally induced nephrotic syndrome. 382 21
Acidosis is a common finding in uremia. We analysed the effect of changes in acid-base balance in 42 Sprague-Dawley rats having longstanding uremia (> 3 mon). The rats were treated with CaCO3 or
CaCl2
in a random cross-over trial after being divided into two dietary groups (8% or 18% protein). At the end of each observation period parameters were assessed. The main finding was that plasma amino and keto acid concentrations varied significantly with the acid-base balance and the protein intake. Furthermore a considerable degree of catabolism and anorexia was observed. In addition other confounding variables were observed, e.g. increased corticosterone excretion, electrolyte losses, and
proteinuria
. Our data underline that plasma amino acid concentrations in uremic rats are highly dependent on acid-base balance and overall protein intake.
...
PMID:Plasma amino acids are highly dependent on acid-base balance in uremic rats. 2419 29
