A cross-link breaker has sustained effects on arterial and ventricular properties in older rhesus monkeys.

Nonenzymatic glycosylation and cross-linking of proteins by glucose contributes to an age-associated increase in vascular and myocardial stiffness. Some recently sythesized thiazolium compounds selectively break these protein cross-links, reducing collagen stiffness. We investigated the effects of 3-phenacyl-4,5-dimethylthiazolium chloride (ALT-711) on arterial and left ventricular (LV) properties and their coupling in old, healthy, nondiabetic Macaca mulatta primates (age 21 +/- 3.6 years). Serial measurements of arterial stiffness indices [i.e., aortic pulse wave velocity (PWV) and augmentation (AGI) of carotid arterial pressure waveform] as well as echocardiographic determinations of LV structure and function were made before and for 39 weeks after 11 intramuscular injections of ALT-711 at 1.0 mg/kg body weight every other day. Heart rate, brachial blood pressure, and body weight were unchanged by the drug. PWV and AGI decreased to a nadir at 6 weeks [PWV to 74.2 +/- 4.4% of baseline (B), P = 0.007; AGI to 41 +/- 7.3% of B, P = 0.046], and thereafter gradually returned to baseline. Concomitant increases in LV end diastolic diameter to 116.7 +/- 2.7% of B, P = 0.02; stroke volume index (SV(index)) to 173.1 +/- 40.1% of B, P = 0.01; and systolic fractional shortening to 180 +/- 29.7% of B, P = 0.01 occurred after drug treatment. The LV end systolic pressure/SV(index), an estimate of total LV vascular load, decreased to 60 +/- 12.1% of B (P = 0.02). The LV end systolic diameter/SV(index), an estimate of arterio-ventricular coupling, was improved (decreased to 54.3 +/- 11% of B, P < 0.002). Thus, in healthy older primates without diabetes, ALT-711 improved both arterial and ventricular function and optimized ventriculo-vascular coupling. This previously unidentified cross-link breaker may be an effective pharmacological therapy to improve impaired cardiovascular function that occurs in the context of heart failure associated with aging, diabetes, or hypertension, conditions in which arterial and ventricular stiffness are increased.

Analysis of the HNF4 alpha gene in Caucasian type II diabetic nephropathic patients.

AIMS/HYPOTHESIS: Linkage and association studies in Caucasian patients with Type II (non-insulin-dependent) diabetes mellitus suggest that one or more diabetes susceptibility gene(s) reside within human chromosome 20q12-13.1. This region of chromosome 20 contains the maturity-onset diabetes of the young type 1 gene, HNF4 alpha. The purpose of this study was to assess the possible involvement of HNF4 alpha in Type II diabetes. METHODS: Mutation analysis was done on the 12 exons and promoter regions of the HNF4 alpha gene in 182 Caucasian diabetic nephropathic patients and 100 Caucasian control subjects. The functional consequences of a novel promoter mutation were examined using a reporter system in the HepG2 liver cell line and electrophoretic mobility shift assays. RESULTS: We identified two novel mutations in the HNF4 alpha, an R323H missense mutation in exon 8, and a 7 bp deletion (delta 7) in the proximal promoter region resulting in deletion of a single putative Sp1 binding site. Using a reporter assay system, the delta 7 sequence was found to exhibit a 51.2% (standard error +/- 4.2%) reduction in promoter activity relative to the normal sequence. In electrophoretic mobility shift assays using specific and non-specific competitors, the delta 7 sequence had a 45.5% (range 40.4-46.6) reduction in binding compared with the normal sequence. The delta 7 allele occurs in a family with multiple cases of Type II diabetes in a pattern consistent with coinheritance of the delta 7 allele and diabetes. CONCLUSION/INTERPRETATION: Analysis of the HNF4 alpha gene revealed two possible mutations in 182 diabetic patients which suggests that the HNF4 alpha gene does not make a large contribution to diabetes susceptibility in the general population of Caucasian diabetic nephropathic patients. Functional analysis of the delta 7 promoter deletion suggests, however, that promoter mutations in otherwise normal genes could contribute to diabetes susceptibility.

Design and baseline characteristics for the aminoguanidine Clinical Trial in Overt Type 2 Diabetic Nephropathy (ACTION II).

Advanced glycosylation endproduct (AGE) formation has been implicated in the development and progression of nephropathy in type 2 diabetes mellitus. In diabetic animals, aminoguanidine inhibits AGE-mediated cross-linking of proteins in vascular and renal tissue and slows the progression of renal disease. ACTION II is a randomized, double-blind, placebo-controlled trial comparing two dose levels of aminoguanidine with placebo on the progression of nephropathy in 599 type 2 diabetic patients with renal disease from 84 centers in the United States and Canada. The primary endpoint is time to doubling of serum creatinine concentration. Secondary endpoints include the effect of aminoguanidine on time to all-cause mortality, end-stage renal disease (ESRD), cardiovascular morbidity and mortality, rate of change in indices of renal function (iothalamate, Cockcroft and Gault [C&G] calculated creatinine and measured creatinine clearances), proteinuria, retinopathy, circulating and urinary AGE levels, and estimation of the relationship between plasma aminoguanidine concentrations and primary and secondary efficacy endpoints and adverse events. Progression of macrovascular disease was monitored and fundus photography performed. Type 2 diabetic patients aged 30 to 70 years were eligible for the trial if their blood pressure was < or =180 mm Hg systolic and < or =120 mm Hg diastolic, serum creatinine concentration > or =1.0 mg/dL (in women) or > or =1.2 mg/dL (in men), C&G clearance > or =40 mL/min, and proteinuria > or =500 mg/d with diabetic retinopathy or diabetic nephropathy on renal biopsy. Recruitment began in July 1995 and terminated in December 1996. The trial randomized a total of 599 subjects. At baseline, the mean (standard deviation [SD]) age was 58 (7.7) years, diabetes duration 16.5 (7.5) years, body mass index 32 kg/m2 (10-90% range 2642), arterial blood pressure 105 (12) mm Hg, C-peptide concentration 2.55 (1.71) ng/mL, serum glucose concentration 201 (89) mg/dL, hemoglobin A1c 8.7% (1.6), serum creatinine concentration 1.6 (0.5) mg/dL, iothalamate clearance 52 (25) mL/min/1.73 m2, proteinuria 4.1 (4.2) g/d, triglycerides 259 (214) mg/dL, and LDL cholesterol 144 (40) mg/dL. Patients are 72% male, 68% white, 16% black, and 16% Asian American and Native American. At baseline, 76% were receiving concomitant angiotensin-converting enzyme (ACE) inhibitors and 43% lipid-lowering agents. Follow-up in ACTION II was scheduled to continue through December 1998, so that follow-up was to be 2 years after the date of randomization of the final enrolled patient. The trial in fact ended in March 1998. This trial will contribute to our understanding of the natural history of type 2 diabetes mellitus-associated nephropathy and determine whether aminoguanidine will slow the progression of established diabetic renal disease.

Formation of plasma advanced glycosylation end products (AGEs) has no influence on plasma viscosity.

Plasma viscosity is mainly determined by large non-spherical proteins. In Type 1 diabetes mellitus, plasma viscosity increases with deterioration of diabetic control. Since protein glycation and formation of advanced glycosylation end products (AGEs) alter the structural and functional properties of proteins, AGEs might influence the rheological properties of plasma proteins. Therefore, we investigated the influence of plasma-AGEs on plasma viscosity in 34 normoalbuminuric diabetic patients (17 Type 1, 17 Type 2) with normal renal and liver function. In an additional experiment, 6 ml plasma of 9 healthy volunteers were incubated under sterile conditions for 14 days at 37.5 degrees C in the presence of 5.2 and 32.9 mmol l(-1) glucose. In diabetic patients, plasma-AGE levels were not correlated with plasma viscosity. Plasma-AGE levels in healthy controls (246 +/- 37 U ml[-1], mean +/- SD) were raised significantly (p<0.001) after the incubation at 37.5 degrees C (392 +/- 57 U ml[-1] and 552 +/- 58 U ml[-1], respectively). However, no difference was found in plasma viscosity pre- and post-incubation (pre-incubation: 1.25 +/- 0.04 mPas, post-incubation: 1.23 +/- 0.03 and 1.24 +/- 0.03, respectively). We conclude that there is no influence of plasma-AGEs on plasma viscosity.

Divergent dimerization properties of mutant beta 1 thyroid hormone receptors are associated with different dominant negative activities.

Syndromes of resistance to thyroid hormones are caused by mutations in the T3-binding domain of the c-erbA beta thyroid hormone receptor gene. The S receptor (deletion of THR332) is a potent dominant negative protein cloned from a kindred with generalized resistance to thyroid hormones. The G-H receptor (ARG311HIS) has compromised dominant negative function and was found in both normal individuals and in a patient with severe pituitary resistance to thyroid hormones. We have investigated the mechanism responsible for the difference in receptor phenotypes by analyzing the binding of S and G-H receptors to thyroid hormone response elements with electrophoretic mobility shift analysis. Wild-type human c-erbA beta 1 (WT), S, and G-H receptors were synthesized in reticulocyte lysate, reacted with a thyroid hormone response element consisting of a direct repeat with 4 base pairs (DR+4; AGGTCA CAGG AGGTCA), and the products analyzed by gel shift. G-H receptor homodimerization was greatly impaired; G-H formed predominantly monomeric complex compared with monomeric and homodimeric WT complexes. The G-H receptor was able to form heterodimeric complexes with cellular thyroid hormone receptor auxiliary protein (TRAP) factors including the human retinoid X receptor-alpha. When TRAP was limiting, the levels of G-H heterodimeric complex were 2- to 3-fold reduced compared with WT receptor. In contrast to the WT and G-H receptors, the S receptor formed almost exclusively homodimeric complex with DR+4; the approximate ratio of S:WT:G-H homodimeric complexes at equivalent concentrations of receptors was 60:20:1. A measurable increase (1.2- to 2.6-fold) in heterodimeric complex formation was observed with the S receptor relative to WT when TRAP was at limiting concentration. As reported previously by others, thyroid hormone significantly reduced the WT homodimeric complex with DR+4. There was no effect on the S homodimeric complex. Finally, the WT, S, and G-H receptors formed different complexes with the element consisting of an inverted repeat with 5 base pairs (IR+5; AGGTCA ACAGT TGACCT) and the IR element (AGGTCA TGACCT), which were differently regulated by thyroid hormone. The S receptor bound as a homodimer with IR+5, whereas the WT receptor bound as a homodimer only with thyroid hormone. No homodimeric complex formed with IR+5 and the G-H receptor. Qualitatively similar results were observed with the IR element. We conclude that the ARG311HIS mutation severely perturbs the homodimerization and, to a much less degree, heterodimerization functions of the c-erbA beta 1 receptor. Furthermore, the THR332 deletion mutation augments homodimerization of the c-erbA beta 1 receptor. These results indicate that different mutations in the c-erbA beta 1 thyroid hormone receptor have divergently affected dimerization activities which seem to influence the level of dominant negative activity in man.