The efflux of l-carnitine from cells in culture (CCL 27)

The efflux of l-[³H]carnitine was studied in cells from an established cell line from human heart (Girardi human heart cells, CCL 27). The cells were loaded with 4 μmol/l l-[³H]carnitine for 1 or 24 h, and the efflux of radioactivity into the medium was measured. The amount of intracellular l-[³H]carnitine retained was expressed as a function of time. The results were fitted to an exponential equation, from which efflux rate constants were computed.Increasing the extracellular concentration of butyrobetaine, l-carnitine, d-carnitine, betaine, dl-norcarnitine or 3-dimethylamino-2-hydroxypropionic acid each increased the observed efflux. This is most likely due to accelerated exchange diffusion. The substrate specificity of this accelerated exchange diffusion is different from what previously has been found in competitive uptake studies of l-carnitine. l-Carnitine was preferentially released to l-acetylcarnitine, and blocking the sulfhydryl groups with 5,5-dithiobis(2-nitrobenzoic acid) increased the efflux.     

L-Carnitine transport in mouse renal and intestinal brush-border and basolateral membrane vesicles

We characterized the uptake of carnitine in brush-border membrane (BBM) and basolateral membrane (BLM) vesicles, isolated from mouse kidney and intestine. In kidney, carnitine uptake was Na⁺-dependent, showed a definite overshoot and was saturable for both membranes, but for intestine, it was Na⁺-dependent only in BLM. The uptake was temperature-dependent in BLM of both kidney and intestine. The BBM transporter in kidney had a high affinity for carnitine: apparent K_m=18.7 μM; V_max=7.85 pmol/mg protein/s. In kidney BLM, similar characteristics were obtained: apparent K_m=11.5 μM and V_max=3.76 pmol/mg protein/s. The carnitine uptake by both membranes was not affected within the physiological pH 6.5-8.5. Tetraethylammonium, verapamil, valproate and pyrilamine significantly inhibited the carnitine uptake by BBM but not by BLM. By Western blot analysis, the OCTN2 (a Na⁺-dependent high-affinity carnitine transporter) was localized in the kidney BBM, and not in BLM. Strong OCTN2 expression was observed in kidney and skeletal muscle, with no expression in intestine in accordance with our functional study. We conclude that different polarized carnitine transporters exist in kidney BBM and BLM. L-Carnitine uptake by mouse renal BBM vesicles involves a carrier-mediated system that is Na⁺-dependent and is inhibited significantly by specific drugs. The BBM transporter is likely to be OCTN2 as indicated by a strong reactivity with the anti-OCTN2 polyclonal antibody.     

Uptake, metabolism and release of carnitine and acylcarnitines in the perfused rat liver

The uptake and release of carnitine and isovalerylcarnitine have been studied in the perfused rat liver. Labelled carnitine accumulates in rat livers perfused with 50 or 500 microM [3H]carnitine. When alpha-ketoisocaproate (5 mM) is added to the perfusate after 30 min of perfusion, the net uptake of carnitine in the liver stops, and there is even a decrease in liver radioactivity. The decrease in liver carnitine can be attributed to an enhanced formation and efflux to the perfusate of short-chain acylcarnitines. Thin-layer chromatography of liver and perfusate extracts showed that efflux rates for branched-chain acylcarnitines (isovalerylcarnitine) formed are at least 2.5-fold the efflux rate for carnitine. Acetylcarnitine is released about twice as fast as carnitine from the liver. Perfusion with 50 microM [3H]isovalerylcarnitine showed that the influx rate of isovalerylcarnitine exceeds that of carnitine 1.5-fold. Since the efflux rate is still higher, a net loss of carnitine from the liver to the perfusate will result when branched-chain acylcarnitines are formed in the perfused liver. The addition of 500 microM unlabelled carnitine to the perfusate does not influence the release of labelled carnitine or acylcarnitines from the liver, showing that uptake and release are independent processes. Isovalerylcarnitine accumulates faster than carnitine does, also in the perfused rat heart. A mechanism for the development of secondary carnitine deficiencies associated with organic acidemia is proposed.     

Metabolism of labeled carnitine in the rat

In two series of rats, the concentration of carnitine in plasma was 39.9 and 37.8 μmol/ liter, in skeletal muscle tissue 2.97 and 3.26 μmol/g dry wt and the urinary excretion 3.2 and 2.4 μmol/24 h. The renal clearance of carnitine was calculated to 88 and 76 ml/24 h. L-[Me-¹⁴C]Carnitine and DL-[Me-¹⁴C]carnitine have been administered to rats. Only labeled l-carnitine has been found on chromatographic analysis of plasma, urine, and muscle tissue. The specific radioactivity of carnitine in plasma, urine, and muscle tissue has been followed for up to 16 days. A two-compartment metabolic model has been used to interpret the result of the experiment with labeled l-carnitine and the rate constants and compartment sizes have been calculated. The total body content of carnitine was 57 μmol (about 35 μmol/100 g body wt) and the daily turnover was about 7% of the body pool. The daily synthesis of carnitine in the rat is estimated to about 2 μmol/100 g body wt.     

The determination of the specific activity of picomolar amounts of long-chain acylcarnitine esters

Measurement of the specific activity of cellular pools of long-chain acylcarnitines is complicated by interference of other labeled cellular lipids, especially phosphatidylcholine and sphingomyelin. To overcome these problems the lipid extract from rabbit aorta labeled with [1-¹⁴C]palmitate was treated with phospholipase C. Upon two-dimensional thin-layer chromatography, the long-chain acylcarnitines could be isolated in an area free of interfering radioactivity. Mobility of long-chain carnitines was inversely proportional to the fatty acid chain length. The amount of long-chain acylcarnitine was quantified from their carnitine content after alkaline hydrolysis using carnitine acetyltransferase.     

Expression of OCTN2 and OCTN3 in the apical membrane of rat renal cortex and medulla

Immunological assays and transport measurements in apical membrane vesicles revealed that the apical membrane of rat kidney cortex and medulla presents OCTN2 and OCTN3 proteins and transports L ‐[³H]‐carnitine in a Na⁺‐dependent and ‐independent manner. OCTN2 mediates the Na⁺/L ‐carnitine transport activity measured in medulla because (i) the transport showed the same characteristics as the cortical Na⁺/L ‐carnitine transporter and (ii) the medulla expressed OCTN2 mRNA and protein. The Na⁺‐independent L ‐carnitine transport activity appears to be mediated by both OCTN2 and OCTN3 since: (i) Na⁺‐independent L ‐carnitine uptake was inhibited by both, anti‐OCTN2 and anti‐OCTN3 antibodies, (ii) kinetics studies revealed the involvement of a high‐ and a low‐affinity transport systems, and (iii) Western and immunohistochemistry studies revealed that OCTN3 protein is located at the apical membrane of the kidney epithelia. The Na⁺‐independent L ‐carnitine uptake exhibited trans‐stimulation by intravesicular L ‐carnitine or betaine. This trans‐stimulation was inhibited by anti‐OCTN3 antibody, but not by anti‐OCTN2 antibody, indicating that OCTN3 can function as an L ‐carnitine/organic compound exchanger. This is the first report showing a functional apical OCTN2 in the renal medulla and a functional apical OCTN3 in both renal cortex and medulla. J. Cell. Physiol. 223: 451–459, 2010. © 2010 Wiley‐Liss, Inc.     

Carnitine uptake and fatty acid utilization by diploid cells aging in culture

Uptake of carnitine by cultured human fetal lung flbroblasts (WI-38 and IMR-90) and by smooth muscle cells from calf aorta and from human uterus was found to be temperature dependent and saturable. IMR-90 cells showed an apparent K_m of 6–8 μM and a V of 21–28 pmol/h/10⁶ cells for l-carnitine. Transport was abolished by N-ethylmaleimide and was inhibited variably by octanoyl-d-carnitine, d-carnitine, and carbonyl cyanide p-trifluoromethoxyphenylhydrazone. Although WI-38 and IMR-90 cells accumulate lipids as they age in culture, they take up carnitine as rapidly as do smooth muscle cells of aorta and uterus that do not exhibit such accumulation. Comparison of the rates of carnitine uptake by IMR-90 fibroblasts during the logarithmic phase of growth shows no difference between “young” and “old” cultures. In contrast, when confluent or postconfluent monolayers were compared and uptake expressed as a function of cell number, cells grown from late passages took up carnitine more rapidly than did cells grown from early passages. However, when account was taken of cell size, and carnitine expressed as a function of cell volume, the differences in carnitine uptake between early and late passages were no longer apparent for the confluent or postconfluent monolayers examined. Moreover, late passage fibroblasts took up and oxidized radioactive palmitate at least as rapidly as did cells from early passages. Our results suggest that accumulation of lipid in aging fibroblasts is not due to decreased carnitine uptake or fatty acid oxidation.     

Properties of carnitine transport in rat kidney cortex slices

The properties of carnitine transport were studied in rat kidney cortex slices. Tissue: medium concentration gradients of 7.9 for L-[methyl-¹⁴C]carnitine were attained after 60-min incubation at 37°C in 40 μM substrate. L- and D-carnitine uptake showed saturability. The concentration curves appeared to consist of (1) a high-affinity component, and (2) a lower affinity site. When corrected for the latter components, the estimated K_m for L-carnitine was 90 μM and $\text{V = 22}\text{nmol/min}$ per ml intracellular fluid; for D-carnitine, $\text{K}{}_{\mathrm{<mtext>m</mtext>}}\text{= 166}\text{μM}$ and $\text{V = 15}\text{nmol/min}$ per ml intracellular fluid. The system was stereospecific for L-carnitine. The uptake of L-carnitine was inhibited by (1) D-carnitine, γ-butyrobetaine, and (2) acetyl-L-carnitine. γ-Butyrobetaine and acetyl-L-carnitine were competitive inhibitors of L-carnitine uptake. Carnitine transport was not significantly reduced by choline, betaine, lysine or γ-aminobutyric acid. Carnitine uptake was inhibited by 2,4-dinitrophenol, carbonyl cyanide $\text{m-}\text{chlorophenylhydrazone}$, N₂ atmosphere, KCN, $\text{N-}\text{ethylmaleimide}$, low temperature (4°C) and ouabain. Complete replacement of Na⁺ in the medium by Li⁺ reduced L- and D-carnitine uptake by 75 and 60%, respectively. Complete replacement of K⁺ or Ca²⁺ in the medium also significantly reduces carnitine uptake. Two roles for the carnitine transport system in kidney are proposed: (1) a renal tubule reabsorption system for the steady-state maintenance of plasma carnitine; and (2) maintenance of normal carnitine levels in kidney cells, which is required for fatty acid oxidation.     

Biosynthesis of carnitine and 4-N-trimethylaminobutyrate from lysine

The conversion of l-[U-(14)C]lysine into carnitine was demonstrated in normal, choline-deficient and lysine-deficient rats. In other experiments in vivo radioactivity from l-[4,5-(3)H]lysine and dl-[6-(14)C]lysine was incorporated into carnitine; however, radioactivity from dl-[1-(14)C]lysine and dl-[2-(14)C]lysine was not incorporated. Administered l-[Me-(14)C]methionine labelled only the 4-N-methyl groups whereas lysine did not label these groups. Therefore lysine must be incorporated into the main carbon chain of carnitine. The methylation of lysine by a methionine source to form 6-N-trimethyl-lysine is postulated as an intermediate step in the biosynthesis of carnitine. Radioactive 4-N-trimethylaminobutyrate (butyrobetaine) was recovered from the urine of lysine-deficient rats injected with [U-(14)C]lysine. This lysine-derived label was incorporated only into the butyrate carbon chain. The specific radioactivity of the trimethylaminobutyrate was 12 times that of carnitine isolated from the urine or carcasses of the same animals. These data further support the idea that the last step in the formation of carnitine from lysine was the hydroxylation of trimethylaminobutyric acid, and are consistent with the following sequence: lysine+methionine --> 6-N-trimethyl-lysine --> --> 4-N-trimethylaminobutyrate --> carnitine.     

l-Carnitine uptake by mouse brain synaptosomal preparations: Competitive inhibition by GABA

The uptake ofl-carnitine was characterized in mouse brain synaptosomal preparations, with an emphasis on mutual interactions with GABA uptake systems. The uptake consisted of nonsaturable diffusion and one saturable energy- and sodium-dependent component. GABA,l-DABA and nipecotate were strong and hypotaurine and homotaurine moderate inhibitors of the uptake. The inhibition by GABA was shown to be competitive. GABA uptake contained two saturable transport components, high- and low-affinity. It was most strongly inhibited by nipecotate andl-DABA, but also by carnitine and hypotaurine. The high-affinity uptake of GABA was competitively inhibited by carnitine, but the inhibition of the low-affinity uptake of GABA was of the mixed type. The results suggest that GABA and carnitine share the same carrier system at synaptosomal membranes. However, GABA is the preferred substrate and the carnitine concentrations which significantly inhibited GABA uptake exceed the physiological carnitine levels in vivo.     

Gbu Glycine Betaine Porter and Carnitine Uptake in Osmotically Stressed Listeria monocytogenes Cells

The food-borne pathogen Listeria monocytogenes grows actively under high-salt conditions by accumulating compatible solutes such as glycine betaine and carnitine from the medium. We report here that the dominant transport system for glycine betaine uptake, the Gbu porter, may act as a secondary uptake system for carnitine, with a K_m of 4 mM for carnitine uptake and measurable uptake at carnitine concentrations as low as 10 μM. This porter has a K_m for glycine betaine uptake of about 6 μM. The dedicated carnitine porter, OpuC, has a K_m for carnitine uptake of 1 to 3 μM and a V_max of approximately 15 nmol/min/mg of protein. Mutants lacking either opuC or gbu were used to study the effects of four carnitine analogs on growth and uptake of osmolytes. In strain DP-L1044, which had OpuC and the two glycine betaine porters Gbu and BetL, triethylglycine was most effective in inhibiting growth in the presence of glycine betaine, but trigonelline was best at inhibiting growth in the presence of carnitine. Carnitine uptake through OpuC was inhibited by γ-butyrobetaine. Dimethylglycine inhibited both glycine betaine and carnitine uptake through the Gbu porter. Carnitine uptake through the Gbu porter was inhibited by triethylglycine. Glycine betaine uptake through the BetL porter was strongly inhibited by trigonelline and triethylglycine. These results suggest that it is possible to reduce the growth of L. monocytogenes under osmotically stressful conditions by inhibiting glycine betaine and carnitine uptake but that to do so, multiple uptake systems must be affected.     

Uptake of benzyladenine by excised watermelon cotyledons

The uptake of 8-[¹⁴C]N⁶-benzyladenine (BA) was studied in excised watermelon (Citrullus vulgaris Schrad.) cotyledons 24 hours after the start of imbibition. The passive nature of this uptake is suggested by the following evidence: (a) no sign of saturation on increasing external concentration of BA; (b) no decrease in uptake under conditions that inhibit ATP synthesis; (c) no change in amount of radioactivity absorbed when cotyledons are frozen and thawed before the uptake test. About two-thirds of the radioactivity taken up is released after 12 hours of washing. If the washing is performed at 2 C very little radioactivity is released.     

A fixation procedure suitable for autoradiography of endogenous long-chain acyl carnitine

A tissue processing procedure was evaluated for fixation of endogenous long-chain acyl carnitine (LCA) to facilitate autoradiographic subcellular localization of this amphiphile. Suspensions of neonatal rat myocytes labeled with exogenous 14C-palmitoyl carnitine retained 85.2% of the radiolabel after tissue processing. Autoradiography demonstrated no significant translocation of radiolabeled LCA from myocytes to unlabeled sheep erythrocytes mixed in equal proportions and processed together. To evaluate endogenous LCA fixation, cultured myocytes were incubated for 3 days with 3H-carnitine. Radioactivity was distributed in LCA, short-chain acyl carnitine, and free carnitine pools in proportion to the physiological concentrations of the metabolites traced. Before tissue processing, LCA contained 4.5% of total radioactivity. After tissue processing, labeled water-soluble components were lost and 88% of the retained radioactivity was in the LCA pool. The enrichment of endogenous LCA radioactivity was attributable to the selective extraction of endogenous short-chain and free carnitine. Nearly 75% of endogenous LCA was preserved. In contrast, 99.5% of both endogenous short-chain and free carnitine were extracted. Thus, endogenous LCA can be selectively preserved, permitting quantitative subcellular localization of this amphiphile with ultrastructural autoradiography.     

Muscle contraction increases carnitine uptake via translocation of OCTN2

Since carnitine plays an important role in fat oxidation, influx of carnitine could be crucial for muscle metabolism. OCTN2 (SLC22A5), a sodium-dependent solute carrier, is assumed to transport carnitine into skeletal muscle cells. Acute regulation of OCTN2 activity in rat hindlimb muscles was investigated in response to electrically induced contractile activity. The tissue uptake clearance (CL(uptake)) of l-[(3)H]carnitine during muscle contraction was examined in vivo using integration plot analysis. The CL(uptake) of [(14)C]iodoantipyrine (IAP) was also determined as an index of tissue blood flow. To test the hypothesis that increased carnitine uptake involves the translocation of OCTN2, contraction-induced alteration in the subcellular localization of OCTN2 was examined. The CL(uptake) of l-[(3)H]carnitine in the contracting muscles increased 1.4-1.7-fold as compared to that in the contralateral resting muscles (p<0.05). The CL(uptake) of [(14)C]IAP was much higher than that of l-[(3)H]carnitine, but no association between the increase in carnitine uptake and blood flow was obtained. Co-immunostaining of OCTN2 and dystrophin (a muscle plasma membrane marker) showed an increase in OCTN2 signal in the plasma membrane after muscle contraction. Western blotting showed that the level of sarcolemmal OCTN2 was greater in contracting muscles than in resting muscles (p<0.05). The present study showed that muscle contraction facilitated carnitine uptake in skeletal muscles, possibly via the contraction-induced translocation of its specific transporter OCTN2 to the plasma membrane.     

Calcium uptake and release by rat liver mitochondria in the presence of rat liver cytosol or the components of cytosol

Summary A study has been made of factors present in rat liver cytosol that might regulate the calcium content of mitochondria. A cytosol preparation containing all the components of molecular weight greater than 10,000 prevented uptake and caused early release of accumulated calcium. These effects were due to free long-chain fatty acids and their coenzyme A derivatives present in the cytosol, and these inhibitory effects were controlled by inclusion of Mg²⁺, carnitine, and adenosine triphosphate at physiological levels in the incubation medium. Palmitoyl carnitine was a good substrate for calcium uptake and did not cause release of calcium from mitochondria. A specific fatty acid-binding protein was found in cytosol which may be the intracellular transport protein for fatty acids.     

Evidence for pituitary-brain transport of a behaviorally potent ACTH analog.

Following intrapituitary injection of ³H-ACTH 4–9 analog, the radioactivity of various brain regions was determined in intact rats and in rats with the pituitary stalk cut one or eight days previously. The regional distribution of radioactivity in the brain was also investigated after intravenous and intrasellar administration. Intrasellar and intrapituitary administration resulted in significantly higher radioactivity levels in the brain than did intravenous injection of an equimolar dose of labeled peptide. Intrapituitary injection resulted in an uptake with clear regional differences and which was highest in the hypothalamus. Twenty four hours after stalk section the uptake of radioactivity in the hypothalamus, but not in other brain regions was markedly depressed. Hypothalamic uptake, however, was restored at eight days after stalk section. The results suggest a significant flow of radioactivity from the pituitary to the brain, particularly to the hypothalamus. Transport to the hypothalamus is presumably partly vascular via the stalk. Transport to other brain areas may occur via the cerebrospinal fluid, but a neural route cannot be excluded.     

The metabolism of dl-(1,6-14C)lipoic acid in the rat

dl-[1,6-¹⁴C]Lipoic acid was synthesized and administered to rats or incubated in vitro with rat liver systems. The urinary excretion of radioactivity after labeled lipoate was administered intraperitoneally at a level of 0.5 mg/100 g body weight was maximal at 3–6 hr, with 60% of the injected radioactivity recovered within 24 hr. Respiratory ¹⁴CO₂ from the same animals is maximal at 3 hr, after which it falls off markedly. Approximately 30% of the injected radioactivity was recovered as ¹⁴CO₂ within 24 hr. The excretion of radioactivity after lipoate was administered by stomach tube was similar to that after intraperitoneal injection. Localization of radioactivity in the body was greatest in liver, intestinal contents, and muscle in all cases. Ionexchange and paper chromatographies of 24-hr pooled urine revealed several watersoluble radioactive metabolites. Incubation of [¹⁴C]lipoate with homogenates or mitochondrial preparations in vitro resulted in the production of ¹⁴CO₂, which was decreased by incubation with unlabeled fatty acids and unaffected by the addition of carnitine or (+)-decanoylcarnitine. The rat, like certain bacteria, metabolizes lipoate via β-oxidation of the valeric acid side chain and by other metabolic reactions on the dithiolane ring, which render the molecule more water soluble.     

Mechanisms of DNA Utilization by Estuarine Microbial Populations

The mechanisms of utilization of DNA by estuarine microbial populations were investigated by competition experiments and DNA uptake studies. Deoxyribonucleoside monophosphates, thymidine, thymine, and RNA all competed with the uptake of radioactivity from [³H]DNA in 4-h incubations. In 15-min incubations, deoxyribonucleoside monophosphates had no effect or stimulated [³H]DNA binding, depending on the concentration. The uptake of radioactivity from [³H]DNA resulted in little accumulation of trichloroacetic acid-soluble intracellular radioactivity and was inhibited by the DNA synthesis inhibitor novobiocin. Molecular fractionation studies indicated that some radioactivity from [³H]DNA appeared in the RNA (10 and 30% at 4 and 24 h, respectively) and protein (approximately 3%) fractions. The ability of estuarine microbial assemblages to transport gene sequences was investigated by plasmid uptake studies, followed by molecular probing. Although plasmid DNA was detected on filters after filtration of plasmid-amended incubations, DNase treatment of filters removed this DNA, indicating that there was little transport of intact gene sequences. These observations led to the following model for DNA utilization by estuarine microbial populations. (i) DNA is rapidly bound to the cell surface and (ii) hydrolyzed by cell-associated and extracellular nonspecific nucleases. (iii) DNA hydrolysis products are transported, and (iv) the products are rapidly salvaged into nucleic acids, with little accumulation into intracellular nucleotide pools.     

Oxidation of acetate,acetyl CoA and acetylcarnitine by pea mitochondria

Acetylcarnitine was rapidly oxidised by pea mitochondria. (-)-carnitine was an essential addition for the oxidation of acetate or acetyl CoA. When acetate was sole substrate, ATP and Mg²⁺ were also essential additives for maximum oxidation. CoASH additions inhibited the oxidation of acetate, acetyl CoA and acetylcarnitine. It was shown that CoASH was acting as a competitive inhibitor of the carnitine stimulated O₂ uptake. It is suggested that acetylcarnitine and carnitine passed through the mitochondrial membrane barrier with ease but acetyl CoA and CoA did not. Carnitine may also buffer the extra- and intra-mitochondrial pools of CoA. The presence of carnitine acetyltransferase (EC 2.3.1.7) on the pea mitochondria is inferred.