The etiology of microalbuminuria in early non-insulin-dependent diabetes mellitus

Challenging the conventional wisdom on diabetic nephropathy: Is microalbuminuria the earliest event?

Microalbuminuria, urine albumin-to-creatinine ratio >30 and less than <300 mg/g has widely been accepted as biomarker of early diabetic kidney disease (DKD). Based on absence of beta-2 microglobulinuria in earlier studies on microalbuminuria, its possible tubular origin has been dismissed. Microalbuminuria has been assumed as a marker of endothelial injury. Low-molecular-weight (LMW) proteins are smaller than albumin and less restricted by the glomerular filtration barrier. Normal individuals excrete no >10 to 20 mg/day low-molecular-weight proteins in urine, as they are absorbed in the proximal tubules. Thus, LMW proteinuria, or non-albumin proteinuria (NAP) is a reliable marker of tubular dysfunction in patients without glomerular involvement. In some cohorts of patients with diabetes (DM), tubular proteinuria preceded microalbuminuria, and similar to the findings reported by Han et al. in this issue of the journal, the tubular origin of these proteins was confirmed through correlations with the increased urinary concentrations of N‑Acetyl‑β‑d‑Glucosaminidase (NAG), a marker of tubular-lysosomal injury. Observations show significant NAP in the urine of DM patients without microalbuminuria; and that NAP correlates with NAG. In many studies it appears that NAP often precedes microalbuminuria, and is likely not the earliest biomarker of diabetic kidney disease. The conclusion that microalbuminuria is a biomarker of glomerular endothelial injury and that it is the earliest finding in DKD requires a re-appraisal. Data increasingly suggest that in early stages of DKD, NAP precedes microalbuminuria, and that microalbuminuria itself may be a consequence of impaired tubular reabsorption.

Induction of microalbuminuria by l-arginine infusion in healthy individuals: an insight into the mechanisms of proteinuria

Despite evidence from individuals with diabetes mellitus or reduced renal mass, the actual relationship between protein- or amino acid-induced changes in renal function and urinary albumin excretion (UAE) is largely unknown in subjects without renal disease. In humans, infusions of l-arginine have been used recently in vascular and renal pathophysiological studies. The present study was undertaken to analyze the mechanisms involved in a particular effect; namely, the behavior of UAE during amino acid loading. A prospective interventional protocol was performed on 10 healthy adults by means of an intravenous infusion of l-arginine. The main results show that l-arginine induced a significant increase in UAE from 13.1 +/- 3.8 before to 53.3 +/- 11.1 microgram/min after the infusion (P < 0.005). This increment was simultaneous to an increase in glomerular filtration rate (GFR) and renal plasma flow (RPF). Furthermore, l-arginine markedly increased the urinary excretion of beta2-microglobulin. UAE correlated significantly with GFR (r = 0. 738; P = 0.014) and RPF (r = 0.942; P < 0.0001), but not with urinary beta2-microglobulin (r = 0.05; P = not significant). Furthermore, marked differences (P = 0.001) were found between the percentage of increase in UAE (306.8% +/- 163.2%) with respect to either albumin filtered load (FLAlb; 57.9% +/- 16.3%) and beta2-microglobulin excretion (1,088.5% +/- 424.6%). No changes were found in vehicle-infused individuals. In conclusion, the present study shows, in controlled conditions, that l-arginine infusion induces a relevant increase in UAE in healthy individuals that significantly exceeds that expected from the increase in GFR alone. The intense and simultaneous increment in beta2-microglobulin excretion strongly suggests that the effect of l-arginine on UAE is, in a relevant part, mediated through a blockade in the tubular protein reabsorption pathways. However, the profound differences observed in the changes induced by l-arginine on UAE and beta2-microglobulin excretion and the differences in the correlation of UAE and beta2-microglobulin with respect to GFR suggest that substantial diversity exists in the mechanisms by which l-arginine affects the renal management of albumin and beta2-microglobulin. These findings are relevant for understanding the renal response to l-arginine and protein/amino acid loads.

Capillary filtration coefficient in type II (non-insulin-dependent) diabetes

Changes in microvascular permeability may be important in the pathogenesis of diabetic microangiopathy. In order to assess microvascular fluid permeability, the capillary filtration coefficient was determined in the forearm of 24 normotensive type II diabetic patients with minimal evidence of microangiopathy and satisfactory glycemic control, and 24 age- and sex-matched control subjects, using a sensitive strain gauge plethysmographic system. The median capillary filtration coefficient was not significantly different in the type II diabetic patients and control subjects [5.3 (3.2 - 9.1) x 10(-3) mL.min-1.100 g tissue-1.mm Hg-1 versus 5.4 (3.5 - 8.0) x 10(-3) mL.min-1.100 g tissue-1.mm Hg-1, p = 0.98)]. There were no correlations between capillary filtration coefficient and age, blood pressure, body mass index, duration of diabetes, glycemic control, or the presence of microvascular complications. These findings contrast with type I diabetes, where capillary filtration coefficient is elevated at an early stage in the disease, and lend support to the theory that there are differences in early microvascular functional abnormalities between type I and type II diabetes.