Life Extension Magazine March 2013
Carnitine insufficiency caused by aging and overnutrition compromises mitochondrial performance and metabolic control.
In addition to its essential role in permitting mitochondrial import and oxidation of long chain fatty acids, carnitine also functions as an acyl group acceptor that facilitates mitochondrial export of excess carbons in the form of acylcarnitines. Recent evidence suggests carnitine requirements increase under conditions of sustained metabolic stress. Accordingly, we hypothesized that carnitine insufficiency might contribute to mitochondrial dysfunction and obesity-related impairments in glucose tolerance. Consistent with this prediction whole body carnitine diminution was identified as a common feature of insulin-resistant states such as advanced age, genetic diabetes, and diet-induced obesity. In rodents fed a lifelong (12 month) high fat diet, compromised carnitine status corresponded with increased skeletal muscle accumulation of acylcarnitine esters and diminished hepatic expression of carnitine biosynthetic genes. Diminished carnitine reserves in muscle of obese rats was accompanied by marked perturbations in mitochondrial fuel metabolism, including low rates of complete fatty acid oxidation, elevated incomplete beta-oxidation, and impaired substrate switching from fatty acid to pyruvate. These mitochondrial abnormalities were reversed by 8 weeks of oral carnitine supplementation, in concert with increased tissue efflux and urinary excretion of acetylcarnitine and improvement of whole body glucose tolerance. Acetylcarnitine is produced by the mitochondrial matrix enzyme, carnitine acetyltransferase (CrAT). A role for this enzyme in combating glucose intolerance was further supported by the finding that CrAT overexpression in primary human skeletal myocytes increased glucose uptake and attenuated lipid-induced suppression of glucose oxidation. These results implicate carnitine insufficiency and reduced CrAT activity as reversible components of the metabolic syndrome.
J Biol Chem. 2009 Aug 21;284(34):22840-52
Acetyl-L-carnitine-induced up-regulation of heat shock proteins protects cortical neurons against amyloid-beta peptide 1-42- mediated oxidative stress and neurotoxicity: implications for Alzheimer’s disease.
Alzheimer’s disease (AD) is a progressive neurodegenerative disorder characterized by loss of memory and cognition and by senile plaques and neurofibrillary tangles in brain. Amyloid-beta peptide, particularly the 42-amino-acid peptide (Abeta(1-42)), is a principal component of senile plaques and is thought to be central to the pathogenesis of the disease. The AD brain is under significant oxidative stress, and Abeta(1-42) peptide is known to cause oxidative stress in vitro and in vivo. Acetyl-L-carnitine (ALCAR) is an endogenous mitochondrial membrane compound that helps to maintain mitochondrial bioenergetics and lowers the increased oxidative stress associated with aging. Glutathione (GSH) is an important endogenous antioxidant, and its levels have been shown to decrease with aging. Administration of ALCAR increases cellular levels of GSH in rat astrocytes. In the current study, we investigated whether ALCAR plays a protective role in cortical neuronal cells against Abeta(1-42)-mediated oxidative stress and neurotoxicity. Decreased cell survival in neuronal cultures treated with Abeta(1-42) correlated with an increase in protein oxidation (protein carbonyl, 3-nitrotyrosine) and lipid peroxidation (4-hydroxy-2-nonenal) formation. Pretreatment of primary cortical neuronal cultures with ALCAR significantly attenuated Abeta(1-42)-induced cytotoxicity, protein oxidation, lipid peroxidation, and apoptosis in a dose-dependent manner. Addition of ALCAR to neurons also led to an elevated cellular GSH and heat shock proteins (HSPs) levels compared with untreated control cells. Our results suggest that ALCAR exerts protective effects against Abeta(1-42) toxicity and oxidative stress in part by up-regulating the levels of GSH and HSPs. This evidence supports the pharmacological potential of acetyl carnitine in the management of Abeta(1-42)-induced oxidative stress and neurotoxicity. Therefore, ALCAR may be useful as a possible therapeutic strategy for patients with AD.
J Neurosci Res. 2006 Aug 1;84(2):398-408
Mitochondrial turnover and aging of long-lived postmitotic cells: the mitochondrial-lysosomal axis theory of aging.
It is now generally accepted that aging and eventual death of multicellular organisms is to a large extent related to macromolecular damage by mitochondrially produced reactive oxygen species, mostly affecting long-lived postmitotic cells, such as neurons and cardiac myocytes. These cells are rarely or not at all replaced during life and can be as old as the whole organism. The inherent inability of autophagy and other cellular-degradation mechanisms to remove damaged structures completely results in the progressive accumulation of garbage, including cytosolic protein aggregates, defective mitochondria, and lipofuscin, an intralysosomal indigestible material. In this review, we stress the importance of crosstalk between mitochondria and lysosomes in aging. The slow accumulation of lipofuscin within lysosomes seems to depress autophagy, resulting in reduced turnover of effective mitochondria. The latter not only are functionally deficient but also produce increased amounts of reactive oxygen species, prompting lipofuscinogenesis. Moreover, defective and enlarged mitochondria are poorly autophagocytosed and constitute a growing population of badly functioning organelles that do not fuse and exchange their contents with normal mitochondria. The progress of these changes seems to result in enhanced oxidative stress, decreased ATP production, and collapse of the cellular catabolic machinery, which eventually is incompatible with survival.
Antioxid Redox Signal. 2010 Apr;12(4):503-35
Mitochondrial theory of aging in human age-related sarcopenia.
Understanding age-related sarcopenia and, more importantly, devising counterstrategies require an intimate knowledge of the underlying mechanism(s) of sarcopenia. The mitochondrial theory of aging (MTA) has been a leading theory on aging for the last decade; however, there is relatively little information from human tissue to support or rebut the involvement of the MTA in aging skeletal muscle. It is believed that mitochondria may contribute to sarcopenia in a stochastic fashion where regions of fibers containing dysfunctional mitochondria are forced to atrophy. Resistance exercise, a known hypertrophic stimulus, has been shown to improve the mitochondrial phenotype of aged skeletal muscle. Furthermore, activation of skeletal muscle stem cells by resistance exercise may attenuate sarcopenia in two ways. First by inducing nuclear addition to postmitotic fibers, and, second, by increasing the proportion of functional mitochondria donated by muscle stem cells in a process termed ‘gene shifting’. In this chapter we review the evidence supporting the MTA, the potential to attenuate the MTA with a known hypertrophic stimuli and explore the role of muscle stem cells in gene shifting to determine the connection between mitochondrial dysfunction and age-related sarcopenia.
Interdiscip Top Gerontol. 2010;37:142-56
Mitochondrial Dysfunction during Brain Aging: Role of Oxidative Stress and Modulation by Antioxidant Supplementation.
Mitochondrial dysfunction and oxidative stress are two interdependent and reinforcing damage mechanisms that play a central role in brain aging. Oxidative stress initiated and propagated by active oxyradicals and various other free radicals in the presence of catalytic metal ions not only can damage the phospholipid, protein and DNA molecules within the cell but can also modulate cell signalling pathways and gene expression pattern and all these processes may be of critical importance in the aging of brain. The present article describes the mechanism of formation of reactive oxyradicals within mitochondria and then explains how these can initiate mitochondrial biogenesis program and activate various transcriptional factors in the cytosol to boost up the antioxidative capacity of the mitochondria and the cell. However, a high level of oxidative stress finally inflicts critical damage to the oxidative phosphorylation machinery and mitochondrial DNA (mtDNA). The latter part of the article is a catalogue showing the accumulating evidence in favour of oxidative inactivation of mitochondrial functions in aged brain and the detailed reports of various studies with antioxidant supplementation claiming variable success in preventing the age-related brain mitochondrial decay and cognitive decline. The antioxidant supplementation approach may be of potential help in the management of neurodegenerative diseases like Alzheimer’s disease. The newly developed mitochondria-targeted antioxidants have brought a new direction to experimental studies related to oxidative damage and they may provide potential drugs in near future for a variety of diseases or degenerative conditions including brain aging and neurodegenerative disorders.
Aging Dis. 2011 Jun;2(3):242-56.
Contribution of impaired mitochondrial autophagy to cardiac aging: mechanisms and therapeutic opportunities.
The prevalence of cardiovascular disease increases with advancing age. Although long-term exposure to cardiovascular risk factors plays a major role in the etiopathogenesis of cardiovascular disease, intrinsic cardiac aging enhances the susceptibility to developing heart pathologies in late life. The progressive decline of cardiomyocyte mitochondrial function is considered a major mechanism underlying heart senescence. Damaged mitochondria not only produce less ATP but also generate increased amounts of reactive oxygen species and display a greater propensity to trigger apoptosis. Given the postmitotic nature of cardiomyocytes, the efficient removal of dysfunctional mitochondria is critical for the maintenance of cell homeostasis, because damaged organelles cannot be diluted by cell proliferation. The only known mechanism whereby mitochondria are turned over is through macroautophagy. The efficiency of this process declines with advancing age, which may play a critical role in heart senescence and age-related cardiovascular disease. The present review illustrates the putative mechanisms whereby alterations in the autophagic removal of damaged mitochondria intervene in the process of cardiac aging and in the pathogenesis of specific heart diseases that are especially prevalent in late life (eg, left ventricular hypertrophy, ischemic heart disease, heart failure, and diabetic cardiomyopathy). Interventions proposed to counteract cardiac aging through improvements in macroautophagy (eg, calorie restriction and calorie restriction mimetics) are also presented.
Circ Res. 2012 Apr 13;110(8):1125-38
Mitochondria, body fat and type 2 diabetes: what is the connection?
This review will consider the concept that the development of a mitochondrial dysfunction in adipocytes is an early step in the pathogenesis for type 2 diabetes. Upon expansion of the adipose mass it becomes gradually inflamed and hypoxic. TNF-alpha, locally produced, induces insulin resistance of adipocytes leading to enhanced lipolysis. The excess of fatty acids, in combination with local hypoxia, results in the induction of mitochondrial damage in the adipocytes. As a result of this decline in mitochondrial activity less fatty acids can be removed within adipocytes by uncoupled mitochondrial beta-oxidation and by re-esterification, as mitochondrial activity provides substrates for glyceroneogenesis. As a result these fatty acids redistribute to other compartments of the body where they are stored as ectopic triglyceride deposits. This situation is associated with the development of insulin resistance of the liver and muscle. Furthermore, it contributes to damage the pancreatic beta-cells. Ultimately, this situation results in the development of a hyperglycemic state.
Minerva Med. 2008 Jun;99(3):241-51
Mitochondrial dysfunction in insulin insensitivity: implication of mitochondrial role in type 2 diabetes.
Abundant evidence has been accumulated to suggest that mitochondrial dysfunction is associated with type 2 diabetes. Research findings from this and other laboratories have supported the notion that impaired mitochondrial function is a cause of insulin insensitivity in myocytes and adipocytes as a result of insufficient supply of energy or defects in the insulin signaling pathway. We demonstrated that inhibition of respiration and oxidative phosphorylation by respiratory inhibitors or knockdown of genes involved in mitochondrial biogenesis can impair the differentiation of preadipocytes and response of adipocytes to insulin. Moreover, defective mitochondria also cause a decrease in adiponectin secretion that leads to decline glucose utilization of other tissues. Besides, it has been elucidated that some environmental factors, pollutants, and mitochondrial toxins are involved in the pathogenesis of type 2 diabetes. Taken together, we suggest that mitochondrial dysfunction plays a role in the pathophysiology of insulin insensitivity, and that activation of mitochondrial biogenesis may be an effective strategy in the prevention or treatment of insulin resistance and type 2 diabetes.
Ann N Y Acad Sci. 2010 Jul;1201:157-65
L-carnitine supplementation and physical exercise restore age-associated decline in some mitochondrial functions in the rat.
In mammals, during the aging process, an atrophy of the muscle fibers, an increase in body fat mass, and a decrease in skeletal muscle oxidative capacities occur. Compounds and activities that interact with lipid oxidative metabolism may be useful in limiting damages that occur in aging muscle. In this study, we evaluated the effect of L-carnitine and physical exercise on several parameters related to muscle physiology. We described that supplementing old rats with L-carnitine at 30 mg/kg body weight for 12 weeks (a) allowed the restoration of L-carnitine level in muscle cells, (b) restored muscle oxidative activity in the soleus, and (c) induced positive changes in body composition: a decrease in abdominal fat mass and an increase in muscle capabilities without any change in food intake. Moderate physical exercise was also effective in (a) limiting fat mass gain and (b) inducing an increase in the capacities of the soleus to oxidize fatty acids.
J Gerontol A Biol Sci Med Sci. 2008 Oct;63(10):1027-33
Acetyl-L-carnitine supplementation restores decreased tissue carnitine levels and impaired lipid metabolism in aged rats.
The effects of long-term carnitine supplementation on age-related changes in tissue carnitine levels and in lipid metabolism were investigated. The total carnitine levels in heart, skeletal muscle, cerebral cortex, and hippocampus were approximately 20% less in aged rats (22 months old) than in young rats (6 months old). On the contrary, plasma carnitine levels were not affected by aging. Supplementation of acetyl-l-carnitine (ALCAR; 100 mg/kg body weight/day for 3 months) significantly increased tissue carnitine levels in aged rats but had little effect on tissue carnitine levels in young rats. Plasma lipoprotein analyses revealed that triacylglycerol levels in VLDL and cholesterol levels in LDL and in HDL were all significantly higher in aged rats than in young rats. ALCAR treatment decreased all lipoprotein fractions and consequently the levels of triacylglycerol and cholesterol. The reduction in plasma cholesterol contents in ALCAR-treated aged rats was attributable mainly to a decrease of cholesteryl esters rather than to a decrease of free cholesterol. Another remarkable effect of ALCAR was that it decreased the cholesterol content and cholesterol-phospholipid ratio in the brain tissues of aged rats. These results indicate that chronic ALCAR supplementation reverses the age-associated changes in lipid metabolism.
J Lipid Res. 2004 Apr;45(4):729-35
Acetyl-L-carnitine supplementation to old rats partially reverts the age-related mitochondrial decay of soleus muscle by activating peroxisome proliferator-activated receptor gamma coactivator-1alpha-dependent mitochondrial biogenesis.
The age-related decay of mitochondrial function is a major contributor to the aging process. We tested the effects of 2-month-daily acetyl-L-carnitine (ALCAR) supplementation on mitochondrial biogenesis in the soleus muscle of aged rats. This muscle is heavily dependent on oxidative metabolism. Mitochondrial (mt) DNA content, citrate synthase activity, transcript levels of some nuclear- and mitochondrial-coded genes (cytochrome c oxidase subunit IV [COX-IV], 16S rRNA, COX-I) and of some factors involved in the mitochondrial biogenesis signaling pathway (peroxisome proliferator-activated receptor gamma [PPARgamma] coactivator-1alpha [PGC-1alpha], mitochondrial transcription factor A mitochondrial [TFAM], mitochondrial transcription factor 2B [TFB2]), as well as the protein content of PGC-1alpha were determined. The results suggest that the ALCAR treatment in old rats activates PGC-1alpha-dependent mitochondrial biogenesis, thus partially reverting the age-related mitochondrial decay.
Rejuvenation Res. 2010 Apr-Jun;13(2-3): 148-51
L-Carnitine attenuates angiotensin II-induced proliferation of cardiac fibroblasts: role of NADPH oxidase inhibition and decreased sphingosine-1-phosphate generation.
The heart is unable to synthesize L-carnitine and is strictly dependent on the L-carnitine provided by the blood stream; however, additional studies are needed to better understand the mechanism of L-carnitine supplementation to the heart. The aim of this study was to evaluate the effects of L-carnitine on angiotensin II (Ang II)-induced cardiac fibroblast proliferation and to explore its intracellular mechanism(s). Cultured rat cardiac fibroblasts were pretreated with L-carnitine (1-30 mM) then stimulated with Ang II (100 nM). Ang II increased fibroblast proliferation and endothelin-1 expression, which were partially inhibited by L-carnitine. L-carnitine also attenuated Ang II-induced NADPH oxidase activity, reactive oxygen species formation, extracellular signal-regulated kinase phosphorylation, activator protein-1-mediated reporter activity and sphingosine-1-phosphate generation. In addition, L-carnitine increased prostacyclin (PGI(2)) generation in cardiac fibroblasts. siRNA transfection of PGI(2) synthase significantly reduced L-carnitine-induced PGI(2) and its anti-proliferation effects on cardiac fibroblasts. Furthermore, blockading potential PGI(2) receptors, including immunoprecipitation (IP) receptors and peroxisome proliferator-activated receptors alpha (PPAR alpha) and delta, revealed that siRNA-mediated blockage of PPAR alpha considerably reduced the anti-proliferation effect of L-carnitine. In summary, these results suggest that L-carnitine attenuates Ang II-induced effects (including NADPH oxidase activation, sphingosine-1-phosphate generation and cell proliferation) in part through PGI(2) and PPAR alpha-signaling pathways.
J Nutr Biochem. 2010 Jul;21(7):580-8
Acetyl-L-carnitine supplementation reverses the age-related decline in carnitine palmitoyltransferase 1 (CPT1) activity in interfibrillar mitochondria without changing the L-carnitine content in the rat heart.
The aging heart displays a loss of bioenergetic reserve capacity partially mediated through lower fatty acid utilization. We investigated whether the age-related impairment of cardiac fatty acid catabolism occurs, at least partially, through diminished levels of L-carnitine, which would adversely affect carnitine palmitoyltransferase 1 (CPT1), the rate-limiting enzyme for fatty acyl-CoA uptake into mitochondria for β-oxidation. Old (24-28 mos) Fischer 344 rats were fed±acetyl-L-carnitine (ALCAR; 1.5% [w/v]) for up to four weeks prior to sacrifice and isolation of cardiac interfibrillar (IFM) and subsarcolemmal (SSM) mitochondria. IFM displayed a 28% (p<0.05) age-related loss of CPT1 activity, which correlated with a decline (41%, p<0.05) in palmitoyl-CoA-driven state 3 respiration. Interestingly, SSM had preserved enzyme function and efficiently utilized palmitate. Analysis of IFM CPT1 kinetics showed both diminished V(max) and K(m) (60% and 49% respectively, p<0.05) when palmitoyl-CoA was the substrate. However, no age-related changes in enzyme kinetics were evident with respect to L-carnitine. ALCAR supplementation restored CPT1 activity in heart IFM, but not apparently through remediation of L-carnitine levels. Rather, ALCAR influenced enzyme activity over time, potentially by modulating conditions in the aging heart that ultimately affect palmitoyl-CoA binding and CPT1 kinetics.
Mech Ageing Dev. 2012 Feb-Mar;133(2-3): 99-106
L-carnitine treatment for congestive heart failure—experimental and clinical study.
To evaluate the therapeutic efficacy of l-carnitine in heart failure, the myocardial carnitine levels and the therapeutic efficacy of l-carnitine were studied in cardiomyopathic BIO 14.6 hamsters and in patients with chronic congestive heart failure and ischemic heart disease. BIO 14.6 hamsters and patients with heart failure were found to have reduced myocardial free carnitine levels (BIO 14.6 vs FI, 287 +/- 26.0 vs 384.8 +/- 83.8 nmol/g wet weight, p less than 0.05; patients with heart failure vs without heart failure, 412 +/- 142 vs 769 +/- 267 nmol/g p less than 0.01). On the other hand, long-chain acylcarnitine level was significantly higher in the patients with heart failure (532 +/- 169 vs 317 +/- 72 nmol/g, p less than 0.01). Significant myocardial damage in BIO 14.6 hamsters was prevented by the intraperitoneal administration of l-carnitine in the early stage of cardiomyopathy. Similarly, oral administration of l-carnitine for 12 weeks significantly improved the exercise tolerance of patients with effort angina. In 9 patients with chronic congestive heart failure, 5 patients (55%) moved to a lower NYHA class and the overall condition was improved in 6 patients (66%) after treatment with l-carnitine. L-carnitine is capable of reversing the inhibition of adenine nucleotide translocase and thus can restore the fatty acid oxidation mechanism which constitutes the main energy source for the myocardium. Therefore, these results indicate that l-carnitine is a useful therapeutic agent for the treatment of congestive heart failure in combination with traditional pharmacological therapy.
Jpn Circ J. 1992 Jan;56(1):86-94
Additional antiischemic effects of long-term L-propionylcarnitine in anginal patients treated with conventional antianginal therapy.
Cardiac L-carnitine content, essential for mitochondrial fatty acid transport and ATP-ADP exchange, decreases during ischemia. In animal models, administration of the natural derivative, L-propionylcarnitine, may reduce ischemia and improve cardiac function. To evaluate possible antiischemic effects of L-propionylcarnitine was compared with placebo in a randomized, double-blind, parallel design, in addition to preexisting therapy. Patients with > or = 2 anginal attacks per week and objective signs of ischemia with angina during bicycle exercise testing were included. After an initial 2-week, single-blind placebo phase, 37 patients received 500 mg L-propionylcarnitine tid, and 37 patients received placebo for 6 weeks. Both groups were comparable at baseline. Three patients discontinued the study while on placebo (two because of noncompliance, one because of palpitations) and one while on L-propionylcarnitine (noncompliance). Although heart rate, blood pressure at rest, and maximal exercise were not affected, L-propionylcarnitine increased the time to 0.1 mV ST-segment depression [44 +/- 3 vs. 8 +/- 2 seconds (mean +/- SEM) in the placebo group; p = 0.05], and exercise duration improved by 5% compared with placebo. Anginal attacks and the consumption of nitroglycerin were not affected in either group. Thus, following a 6 week treatment period, L-propionylcarnitine induced additional, albeit marginal, antiischemic effects in anginal patients who were still symptomatic despite maximal conventional antianginal therapy. It is questionable whether in these patients this form of metabolic treatment will achieve great benefit, although in some improvement can be expected.
Cardiovasc Drugs Ther. 1995 Dec;9(6):749-53
Value of carnitine therapy in kidney dialysis patients and effects on cardiac function from human and animal studies.
Cardiovascular complications are the leading cause of mortality, accounting for 50% of all deaths among patients with end-stage renal disease (ESRD). The majority of these deaths are from cardiac causes. The mechanisms underlying the enhanced susceptibility to myocardial ischaemia and subsequent morbidity in ESRD remain ill-defined. Numerous metabolic derangements accompany myocardial ischaemia and reperfusion and play a pivotal role in the development of concurrent myocardial dysfunction. Carnitine plays a critical role in myocardial energy metabolism, as the transporter of long chain fatty acyl intermediates across the inner mitochondrial membrane for oxidation and as a central regulator of carbohydrate metabolism. Myocardial carnitine is significantly depleted during ischaemia and more particularly in uraemic patients and those on dialysis therapy. Carnitine treatment has cardiovascular benefits including modulation of myocardial metabolism, reduction in necrotic cell death and infarct size, decrease in the incidence of arrhythmias and preservation of mechanical function. This review details the profile of substrate metabolism in the uraemic heart and the impact of carnitine supplementation on metabolism and function of the reperfused heart and finally the experimental and clinical evidence for carnitine replacement therapy, in particular its impact on the uraemic heart via modulation of function and energetics.
Curr Drug Targets. 2012 Feb;13(2):285-93
Controlled study on L-carnitine therapeutic efficacy in post-infarction.
A controlled study was carried out on 160 patients of both sexes (age between 39 and 86 years) discharged from the Cardiology Department of the Santa Chiara Hospital, Pisa, with a diagnosis of recent myocardial infarction. L-carnitine was randomly administered to 81 patients at an oral dose of g 4/die for 12 months, in addition to the pharmacological treatment generally used. For the whole period of 12 months, these patients showed, in comparison with the controls, an improvement in heart rate (p < 0.005), systolic arterial pressure (p < 0.005) and diastolic arterial pressure (NS); a decrease of anginal attacks (p < 0.005), of rhythm disorders (NS) and of clinical signs of impaired myocardial contractility (NS), and a clear improvement in the lipid pattern (p < 0.005). The above changes were accompanied by a lower mortality in the treated group (1.2%, p < 0.005), while in the control group there was a mortality of 12.5%. Furthermore, in the control group there was a definite prevalence of deaths caused by reinfarction and sudden death. On the basis of these results, it is concluded that L-carnitine represents an effective treatment in post-infarction ischaemic cardiopathy, since it can improve the clinical evolution of this pathological condition as well as the patient’s quality of life and life expectancy.
Drugs Exp Clin Res. 1992;18(8):355-65
Propionyl-L-carnitine improves postischemic blood flow recovery and arteriogenetic revascularization and reduces endothelial NADPH-oxidase 4-mediated superoxide production.
OBJECTIVE: The beneficial effect of the natural compound propionyl-l-carnitine (PLC) on intermittent claudication in patients with peripheral arterial disease is attributed to its anaplerotic function in ischemic tissues, but inadequate information is available concerning action on the vasculature. METHODS AND RESULTS: We investigated the effects of PLC in rabbit hind limb collateral vessels after femoral artery excision, mouse dorsal air pouch, chicken chorioallantoic membrane, and vascular cells by angiographic, Doppler flow, and histomorphometrical and biomolecular analyses. PLC injection accelerated hind limb blood flow recovery after 4 days (P<0.05) and increased angiographic quadriceps collateral vascularization after 7 days (P<0.001) Histomorphometry confirmed the increased vascular area (P<0.05), with unchanged intramuscular capillary density. PLC-induced dilatative adaptation, and growth was found associated with increased inducible nitric oxide synthase and reduced arterial vascular endothelial growth factor and intracellular adhesion molecule-1 expression. PLC also increased vascularization in air pouch and chorioallantoic membrane (P<0.05), particularly in large vessels. PLC increased endothelial and human umbilical vascular endothelial cell proliferation and rapidly reduced inducible nitric oxide synthase and NADPH-oxidase 4-mediated reactive oxygen species production in human umbilical vascular endothelial cells; NADPH-oxidase 4 also regulated NF-kappaB-independent intracellular adhesion molecule-1 expression. CONCLUSIONS: Our results provided strong evidence that PLC improves postischemic flow recovery and revascularization and reduces endothelial NADPH-oxidase-related superoxide production. We recommend that PLC should be included among therapeutic interventions that target endothelial function.
Arterioscler Thromb Vasc Biol. 2010 Mar;30(3):426-35
Effects of propionyl-L-carnitine on ischemia-reperfusion injury in hamster cheek pouch microcirculation.
BACKGROUND AND PURPOSE: Propionyl-l-carnitine (pLc) exerts protective effects in different experimental models of ischemia-reperfusion (I/R). The aim of the present study was to assess the effects of intravenously and topically applied pLc on microvascular permeability increase induced by I/R in the hamster cheek pouch preparation. METHODS: The hamster cheek pouch microcirculation was visualized by fluorescence microscopy. Microvascular permeability, leukocyte adhesion to venular walls, perfused capillary length, and capillary red blood cell velocity (V(RBC)) were evaluated by computer-assisted methods. E-selectin expression was assessed by in vitro analysis. Lipid peroxidation and reactive oxygen species (ROS) formation were determined by thiobarbituric acid-reactive substances (TBARS) and 2’-7’-dichlorofluorescein (DCF), respectively. RESULTS: In control animals, I/R caused a significant increase in permeability and in the leukocyte adhesion in venules. Capillary perfusion and V(RBC) decreased. TBARS levels and DCF fluorescence significantly increased compared with baseline. Intravenously infused pLc dose-dependently prevented leakage and leukocyte adhesion, preserved capillary perfusion, and induced vasodilation at the end of reperfusion, while ROS concentration decreased. Inhibition of nitric oxide synthase prior to pLc caused vasoconstriction and partially blunted the pLc-induced protective effects; inhibition of the endothelium-derived hyperpolarizing factor (EDHF) abolished pLc effects. Topical application of pLc on cheek pouch membrane produced the same effects as observed with intravenous administration. pLc decreased the E-selectin expression. CONCLUSIONS: pLc prevents microvascular changes induced by I/R injury. The reduction of permeability increase could be mainly due to EDHF release induce vasodilatation together with NO. The reduction of E-selectin expression prevents leukocyte adhesion and permeability increase
Front Physiol. 2010 Oct 19;1:132