L-Arginine inhibits in vitro nonenzymatic glycation and advanced glycosylated end product formation of human serum albumin.

L-Arginine (Arg) has a structure similar to that of aminoguanidine (AG) and may inhibit glycation and advanced glycosylated end product (AGE) formation. Human serum albumin (HSA) (100mg/ml) was incubated for 2 weeks with glucose (200mM) at 37°C or with glucose and equimolar concentrations of Arg, N-α-acetyl Arg, or AG with or without 25mM diethylenetriaminepentaacetic acid (DTPA). In the absence of DTPA, electrospray ionization mass spectrometry showed a 70% reduction of covalently bound glucose in the presence of Arg and a 30% reduction with AG. Digestibility by trypsin of HSA incubated with glucose and Arg was similar to that of HSA incubated alone. This suggests less covalent modification of HSA in the presence of Arg as compared with the absence of Arg. When incubations contained DTPA, autoradiography showed less(14)C labeling of HSA subunits in the presence of Arg and AG. When theα-amino group of Arg was blocked with an acetyl group, labeling was similar to that of HSA incubated with glucose, suggesting involvement of theα-amino group in the inhibition. Fluorescence of HSA at ex370 and em440 was reduced with Arg, but AG was more effective than Arg. These results suggest that Arg, like AG, can inhibit glycation and AGE formation.

Perilipin: unique proteins associated with intracellular neutral lipid droplets in adipocytes and steroidogenic cells.

For several reasons it seems reasonable to suspect that perilipins participate in lipid hydrolysis. First, they are located at the lipid droplet surface, the presumed site of HSL and cholesteryl esterase action. Secondly, they are polyphosphorylated by PKA in concert with lipid hydrolysis. Finally, these proteins appear to be expressed primarily, if not solely, in adipocytes and steroidogenic cells, cells in which lipid hydrolysis is stimulated by cyclic AMP and mediated by HSL or cholesteryl esterase(s), whereas other cells that contain abundant neutral lipid depositions contain no perilipin [13]. Interestingly, these closely related hydrolases share no homology with other mammalian lipases [3]. Although such attributes provide a link between perilipin and lipid hydrolysis, we have no evidence that perilipins participate directly in, or are necessary for, lipid catabolism. The basis for the strong affinity between the perilipins and neutral lipids is unknown. Clearly, lipids and perilipins are tightly linked, as evidenced by selective targeting of epitope-tagged perilipin to lipid droplets and by the paradoxical appearance of lipid droplets in pre-adipocytes transfected with a sense perilipin A construct. Indeed, in differentiating adipocytes the earliest lipid depositions are associated with perilipins, and restriction of perilipin synthesis with anti-sense constructs may impede lipid formation and deposition. It remains to be determined if, in the normal course of events, perilipins are directed toward lipid depositions or if lipids are transported to perilipin foci. Whatever the temporal sequence, the result is that neutral lipids are encased in perilipin-bounded droplets.(ABSTRACT TRUNCATED AT 250 WORDS)

Perilipins are associated with cholesteryl ester droplets in steroidogenic adrenal cortical and Leydig cells.

Steroidogenic cells store cholesteryl esters, precursors for steroid hormone synthesis, in intracellular lipid droplets. Cholesteryl ester hydrolysis is activated by protein kinase A and catalyzed by cholesteryl esterase. The esterase is similar, if not identical, to hormone-sensitive lipase in adipocytes where an analogous lipolytic mechanism occurs. Perilipins, proteins located exclusively at lipid droplet surfaces in adipocytes, are polyphosphorylated by protein kinase A in response to lipolytic stimuli, suggesting a role for these proteins in mediating lipid metabolism. The present study reveals that perilipins are associated with cholesteryl ester droplets in two steroidogenic cell lines: Y-1 adrenal cortical cells and MA-10 Leydig cells. The relative abundance of perilipin mRNAs and protein is much less in steroidogenic cells than in adipocytes. Like adipocytes, steroidogenic cells express perilipin A; additionally, the latter cells contain relatively abundant amounts of perilipin C, a protein that is not detectable in adipocytes by Western analysis. The data suggest a strong link between perilipins and lipid hydrolysis that is mediated by the hormone-sensitive lipase/cholesteryl esterase class of enzymes.

Development and characteristics of a new strain of obese hyperinsulinemic and hyperlipidemic Dahl salt-sensitive rat. The Dahl salt-sensitive/NIH-corpulent rat.

A new congenic rat strain, the Dahl salt-sensitive/NIH-corpulent (DSS/N-cp) rat, has been developed to study the role of obesity and type of dietary carbohydrate in the development of hypertension and its complications. Three groups (n = 6) of young male obese and lean DSS/N-cp rats were fed diets containing either 54% sucrose, 18% sucrose plus 36% starch, or 54% starch, with 0.1% dietary sodium for 12 weeks. Regardless of the diet, obese and lean rats showed mildly elevated systolic blood pressure (SBP), being significantly higher in obese than in lean rats (SBP 156 +/- 5 mm Hg v 141 +/- 3 mm Hg, P < .05). However, SBP was not different between the three diet groups. Levels of serum insulin, triglyceride, and cholesterol as well as urinary protein excretion were significantly higher in obese than in lean rats. Obese rats fed the sucrose diets as compared to the starch diet, had higher serum insulin and lipid levels, but had lower body weights and higher serum creatinine levels. Histopathologic examination of tissues from different organs revealed a vasculopathy seen almost exclusively in obese rats fed the sucrose diets. Vascular lesions were characterized by subintimal fibrin deposition, fibrinoid necrosis, and cell proliferation with "onion skinning" in small arteries and arterioles of kidneys, intestine, pancreas, and testes.(ABSTRACT TRUNCATED AT 250 WORDS)