Non-insulin-dependent diabetes mellitus and hypertriglyceridemia impair lipoprotein metabolism in chronic hemodialysis patients

Patients with diabetes mellitus undergoing chronic hemodialysis treatment have the worst outcome on dialysis due to an increased rate of cardiovascular complications. Nearly all patients present with dyslipidemia, a prominent vascular risk factor, probably responsible for the high rate of vascular injury. Since both uremia and diabetes predispose to hypertriglyceridemia, the present study was conducted to investigate the influence of diabetes mellitus and/or hypertriglyceridemia on lipoprotein metabolism in hemodialysis patients. LDL was isolated and characterized from hyper- and normotriglyceridemic diabetic and nondiabetic hemodialysis patients (n = 40; 10 in each group); also, LDL-receptor-dependent uptake and intracellular cholesterol metabolism were studied in HepG2 cells. In addition, scavenger-receptor-mediated uptake was examined in mouse peritoneal macrophages. LDL isolated from nondiabetic normotriglyceridemic hemodialysis patients exhibited impaired cellular uptake via the LDL receptor. Additionally, intracellular sterol synthesis was less inhibited and cholesterol esterification was reduced compared with LDL from healthy control subjects. Reduction of catabolic capacities was more marked in hemodialysis patients who were either diabetic or hypertriglyceridemic and even more pronounced in patients presenting with a combination of both diabetes and hypertriglyceridemia. Hypertriglyceridemic and diabetic patients showed reduced lipase activity and increased LDL oxidation. Furthermore, they accumulated a fraction of small, dense LDL, and LDL was predominantly taken up via the scavenger-receptor pathway in peritoneal macrophages. This study elucidates the distinct influence of diabetes and/or hypertriglyceridemia in hemodialysis patients on cellular LDL metabolism via specific and nonspecific metabolic pathways. Furthermore, it underscores the cumulative impact of these pathologic entities on impairment of lipoprotein metabolism and increase of cardiovascular risk.     

Creatine kinase knockout mice show left ventricular hypertrophy and dilatation, but unaltered remodeling post-myocardial infarction

OBJECTIVE: Creatine kinase (CK) is responsible for the transport of high-energy phosphates in excitable tissue and is of central importance in myocardial energy homeostasis. Significant changes in myocardial energetics have been reported in mice lacking the various CK isoenzymes. Our hypothesis was that ablation of CK isoenzymes leads to cardiac hypertrophy, impaired function, and aggravation of left ventricular remodeling post-myocardial infarction. METHODS: CK-deficient mice (CK KO) were examined by cardiac magnetic resonance imaging (MRI) to determine left ventricular volumes, ejection fraction, and mass: ten wild-type (WT), 6 mitochondrial CK KO (Mito-CK-/-), 10 cytosolic CK KO (M-CK-/-), and 10 mice with combined KO (M/Mito-CK-/-). RESULTS: While ejection fraction was similar in all groups, there was significant LV dilatation with a approximately 30% increase in LV end-diastolic volumes in Mito-CK-/- and in M/Mito-CK-/-. Compared to WT, there was a striking 73% and 64% increase of LV mass in Mito-CK-/- and in M/Mito-CK-/- mice, respectively, but no significant increase of LV mass (+33%; p=n.s.) in M-CK-/-. Furthermore, significant re-expression of beta-MHC, a marker of myocardial hypertrophy, was found in all CK-deficient hearts. LV remodeling was investigated by MRI in hearts of 7 WT and 10 M/Mito-CK-/- mice 4 weeks postmyocardial infarction (MI). Four weeks post-LAD ligation (MI size approximately 32%), WT and M/Mito-CK-/- showed a similar degree of cardiac dysfunction, dilatation, and hypertrophy. CONCLUSION: Mito-CK-/- and M/Mito-CK-/- mice show significant LV dilatation and marked LV hypertrophy, but LV remodeling post-MI is not aggravated. CK ablation leads to substantial adaptational changes in heart.     

Vasopeptidase Inhibition Prevents Endothelial Dysfunction of Resistance Arteries in Salt-Sensitive Hypertension in Comparison With Single ACE Inhibition

-To determine whether natriuretic peptides in addition to the renin-angiotensin system are involved in functional and structural vascular changes in salt-sensitive hypertension, we compared equipotent hypotensive treatment with the dual neutral endopeptidase/ACE inhibitor omapatrilat (35 mg. kg(-1). d(-1)) or the ACE inhibitor captopril (100 mg. kg(-1). d(-1)). The reactivity and geometry of mesenteric resistance arteries from Dahl salt-sensitive rats were studied in vitro under perfused and pressurized conditions. Chronic salt administration increased systolic blood pressure by 57+/-4 mm Hg, whereas concentrations of atrial natriuretic peptide were reduced in heart and in plasma (P:<0.05). In addition, the medial cross-sectional area of small mesenteric arteries was increased and endothelium-dependent relaxation in response to acetylcholine and contraction in response to endothelin-1 were impaired in the mesenteric arteries of salt-sensitive rats on a high-salt diet (P:<0.05). Concomitant treatment with either omapatrilat or captopril reduced the increase in systolic blood pressure and hypertrophic remodeling to a similar degree (P:<0.05) but affected plasma and cardiac atrial natriuretic peptide levels differently (P:<0.05). In addition, omapatrilat normalized endothelium-dependent relaxations to a greater extent than captopril (P:<0.05). Furthermore, vasopeptidase inhibition increased cGMP levels compared with captopril (P:<0.05). Contractions to endothelin-1 were normalized by either antihypertensive drug. These results suggest that in the Dahl rat, with similar reductions in systolic blood pressure, omapatrilat is superior to captopril in preventing impaired endothelial function in small resistance arteries. Thus, vasopeptidase inhibition may have therapeutic advantages of the prevention of changes in vascular function and structure in salt-sensitive forms of hypertension.     

Vasopeptidase inhibition for blood pressure control: emerging experience

Vasopeptidase inhibition is a novel treatment approach in cardiovascular disease such as hypertension and heart failure. Since the inhibition of the angiotensin-converting enzyme (ACE) turned out to represent a very successful principle in the treatment of hypertension in numerous large scale clinical studies, their results encouraged attempts to inhibit other key enzymes in the regulation of vascular tone as well--such as the neutral endopeptidase (NEP). Similar to ACE, NEP is an endothelial cell surface metalloproteinase, which is involved in the degradation of several regulatory peptides including the natriuretic peptides and thus augments vasodilatation and natriuresis through increased levels of atrial natriuretic peptide (ANP). By simultaneous inhibition of the RAS and potentiation of the natriuretic peptide system, combined NEP/ACE inhibitors--the so called vasopeptidase inhibitors--reduce vasoconstriction and enhance vasodilatation, therefore, decreasing peripheral vascular resistance and blood pressure. Based on these considerations, numerous preclinicial studies with vasopeptidase inhibitors were performed and revealed promising results in experimental hypertension. Correspondingly, large scale clinical studies in patients with hypertension are on the way. Their preliminary results indicate that combined inhibition of ACE and NEP by vasopeptidase inhibitors represents an effective strategy in the treatment of hypertension and other cardiovascular disease such as heart failure. However, clinical data also suggest that the incidence of angioedema may increase on vasopeptidase inhibition. Therefore, careful evaluation of the safety of this promising therapeutic principle in large scale clinical studies is mandatory before vasopeptidase inhibition may be considered a novel option in the treatment of cardiovascular disease.     

Endothelial dysfunction and inflammation: what is the link?

Cardiovascular disease, resulting from arteriosclerotic remodeling of the vasculature, is the main cause of death in end-stage renal disease (ESRD) patients. Early during the course of arteriosclerosis, endothelial dysfunction can be detected in various vascular beds, including peripheral forearm arteries, as well as the coronary circulation. Furthermore, endothelial dysfunction seems to predict the prognosis of cardiovascular disease. Therefore, the question deserves attention whether endothelial dysfunction is simply a marker of cardiovascular disease, or an active player in the progress of the disease. A possible link between arteriosclerosis, endothelial dysfunction, and cardiovascular disease is increased oxidative stress. Inflammatory processes involved in the pathogenesis of arteriosclerosis enhance vascular O2- formation, leading to endothelial dysfunction. An activated renin angiotensin system, together with oxidized low-density lipoprotein, may play a prominent role for enhanced vascular oxidative stress. In this context, the endothelium is not only a target of oxygen radicals, but may also contribute to O2- formation. It is the aim of this article to highlight the interplay of inflammation, endothelial dysfunction, and oxidative stress.     

Dyslipidemia and renal disease: pathogenesis and clinical consequences

Patients with chronic renal disease suffer from a secondary form of complex dyslipidemia. The most important abnormalities are an increase in serum triglyceride levels (elevated VLDL-remnants/IDL), small LDL particles and a low HDL cholesterol level. The highly atherogenic LDL subclass, namely LDL-6 or small dense LDL, accumulates preferentially in hypertriglyceridemic diabetic patients with nephropathy or on hemodialysis treatment. All these lipoprotein particles contain apolipoprotein B, thus the complex disorder can be summarized as an elevation of triglyceride-rich apolipoprotein B-containing complex lipoprotein particles. Growing evidence suggests that all of the components of this type of dyslipidemia are independently atherogenic. These particles, specifically the apolipoprotein B moiety, are predominantly prone to modification such as oxidation and glycosilation, which contributes to impaired clearance by the LDL receptor. These complex alterations in lipoprotein composition not only passively accompany chronic renal disease but on the contrary also promote its progression and the development of atherosclerosis. Therefore, renal patients with dyslipidemia should be subjected to lipid-lowering therapy. The effectiveness of lipid lowering on the reduction of cardiovascular endpoints or the progression of renal disease is under investigation or remains to be studied.     

Vasopeptidase inhibition: Effective blood pressure control for vascular protection

Angiotensin converting enzyme (ACE) inhibition is a well-established principle in the treatment of hypertension, and numerous large scale clinical studies have clearly demonstrated the beneficial effects of inhibiting the renin-angiotensin-aldosterone system (RAS) in hypertension. The clinical success of ACE inhibitors encouraged attempts to inhibit other key enzymes in the regulation of vascular tone, such as the neutral endopeptidase (NEP). Similar to ACE, NEP is an endothelial cell surface metalloproteinase, which is involved in the degradation of several regulatory peptides including the natriuretic peptides, and augments vasodilatation and natriuresis through increased levels of atrial natriuretic peptide. By inhibiting the RAS and potentiating the natriuretic peptide system at the same time, combined NEP/ACE inhibitors, the so-called “vasopeptidase inhibitors,” reduce vasoconstriction and enhance vasodilatation, and in turn decrease peripheral vascular resistance and blood pressure. Within the vessel wall this may lead to a reduction of vasoconstrictor and proliferative mediators such as angiotensin II and endothelin-1, and may increase local levels of bradykinin as well as natriuretic peptides. Based on these considerations, numerous preclinicial studies with vasopeptidase inhibitors have been performed and reveal promising results in experimental hypertension. Correspondingly, large-scale clinical studies in patients with hypertension are on the way, to transfer the principle of vasopeptidase inhibition from bench to bedside.