Molecular characterization of L-CPT I deficiency in six patients: insights into function of the native enzyme.

Carnitine palmitoyltransferase I (CPT I) catalyzes the formation of acylcarnitine, the first step in the oxidation of long-chain fatty acids in mitochondria. The enzyme exists as liver (L-CPT I) and muscle (M-CPT I) isoforms that are encoded by separate genes. Genetic deficiency of L-CPT I, which has been reported in 16 patients from 13 families, is characterized by episodes of hypoketotic hypoglycemia beginning in early childhood and is usually associated with fasting or illness. To date, only two mutations associated with L-CPT I deficiency have been reported. In the present study we have identified and characterized the mutations underlying L-CPT I deficiency in six patients: five with classic symptoms of L-CPT I deficiency and one with symptoms that have not previously been associated with this disorder (muscle cramps and pain). Transfection of the mutant L-CPT I cDNAs in COS cells resulted in L-CPT I mRNA levels that were comparable to those expressed from the wild-type construct. Western blotting revealed lower levels of each of the mutant proteins, indicating that the low enzyme activity associated with these mutations was due, at least in part, to protein instability. The patient with atypical symptoms had approximately 20% of normal L-CPT I activity and was homozygous for a mutation (c.1436C-->T) that substituted leucine for proline at codon 479. Assays performed with his cultured skin fibroblasts indicated that this mutation confers partial resistance to the inhibitory effects of malonyl-CoA. The demonstration of L-CPT I deficiency in this patient suggests that the spectrum of clinical sequelae associated with loss or alteration of L-CPT I function may be broader than was previously recognized.

Prolonged inhibition of muscle carnitine palmitoyltransferase-1 promotes intramyocellular lipid accumulation and insulin resistance in rats.

Cross-sectional studies in human subjects have used 1H magnetic resonance spectroscopy (HMRS) to demonstrate that insulin resistance correlates more tightly with the intramyocellular lipid (IMCL) concentration than with any other identified risk factor. To further explore the interaction between these two elements in the rat, we used two strategies to promote the storage of lipids in skeletal muscle and then evaluated subsequent changes in insulin-mediated glucose disposal. Normal rats received either a low-fat or a high-fat diet (20% lard oil) for 4 weeks. Two additional groups (lowfat + etoxomir and lard + etoxomir) consumed diets containing 0.01% of the carnitine palmitoyltransferase-1 inhibitor, R-etomoxir, which produced chronic blockade of enzyme activity in liver and skeletal muscle. Both the high-fat diet and drug treatment significantly impaired insulin sensitivity, as measured with the hyperinsulinemic-euglycemic clamp. Insulin-mediated glucose disposal (IMGD) fell from 12.57 +/- 0.72 in the low-fat group to 9.79 +/- 0.59, 8.96 +/- 0.38, and 7.32 +/- 0.28 micromol x min(-1) x 100 g(-1) in the low-fat + etoxomir, lard, and lard + etoxomir groups, respectively. We used HMRS, which distinguishes between fat within the myocytes and fat associated with contaminating adipocytes located in the muscle bed, to assess the IMCL content of isolated soleus muscle. A tight inverse relationship was found between IMGD and IMCL, the correlation (R = 0.96) being much stronger than that seen between IMGD and either fat mass or weight. In conclusion, either a diet rich in saturated fat or prolonged inhibition of fatty acid oxidation impairs IMGD in rats via a mechanism related to the accumulation of IMCL.

Elucidation of the mechanism by which (+)-acylcarnitines inhibit mitochondrial fatty acid transport.

It is well established that medium and long chain (+)-acylcarnitines (i.e. fatty acid esters of the unnatural d-isomer of carnitine) inhibit the oxidation of long chain fatty acids in mammalian tissues by interfering with some component(s) of the mitochondrial carnitine palmitoyltransferase (CPT) system. However, whether their site of action is at the level of CPT I (outer membrane), CPT II (inner membrane), carnitine-acylcarnitine translocase (CACT, inner membrane), or some combination of these elements has never been resolved. We chose to readdress this question using rat liver mitochondria and employing a variety of assays that distinguish between the three enzyme activities. The effect on each of (+)-acetylcarnitine, (+)-hexanoylcarnitine, (+)-octanoylcarnitine, (+)-decanoylcarnitine, and (+)-palmitoylcarnitine was examined. Contrary to longstanding belief, none of these agents was found to impact significantly upon the activity of CPT I or CPT II. Whereas (+)-acetylcarnitine also failed to influence CACT, both (+)-octanoylcarnitine and (+)-palmitoylcarnitine strongly inhibited this enzyme with a similar IC(50) value ( approximately 35 microm) under the assay conditions employed. Remarkably, (+)-decanoylcarnitine was even more potent (IC(50) approximately 5 microm), whereas (+)-hexanoylcarnitine was far less potent (IC(50) >200 microm). These findings resolve a 35-year-old puzzle by establishing unambiguously that medium and long chain (+)-acylcarnitines suppress mitochondrial fatty acid transport solely through the inhibition of the CACT component. They also reveal a surprising rank order of potency among the various (+)-acylcarnitines in this respect and should prove useful in the design of future experiments in which selective blockade of CACT is desired.

Regulation of the activity of caspases by L-carnitine and palmitoylcarnitine.

L-Carnitine facilitates the transport of fatty acids into the mitochondrial matrix where they are used for energy production. Recent studies have shown that L-carnitine is capable of protecting the heart against ischemia/reperfusion injury and has beneficial effects against Alzheimer's disease and AIDS. The mechanism of action, however, is not yet understood. In the present study, we found that in Jurkat cells, L-carnitine inhibited apoptosis induced by Fas ligation. In addition, 5 mM carnitine potently inhibited the activity of recombinant caspases 3, 7 and 8, whereas its long-chain fatty acid derivative palmitoylcarnitine stimulated the activity of all the caspases. Palmitoylcarnitine reversed the inhibition mediated by carnitine. Levels of carnitine and palmitoyl-CoA decreased significantly during Fas-mediated apoptosis, while palmitoylcarnitine formation increased. These alterations may be due to inactivation of beta-oxidation or to an increase in the activity of the enzyme that converts carnitine to palmitoylcarnitine, carnitine palmitoyltransferase I (CPT I). In support of the latter possibility, fibroblasts deficient in CPT I activity were relatively resistant to staurosporine-induced apoptosis. These observations suggest that caspase activity may be regulated in part by the balance of carnitine and palmitoylcarnitine.

Expression and possible role of muscle-type carnitine palmitoyltransferase I during sperm development in the rat.

Because we had found whole testis from adult rats to be much richer in the messenger RNA for the muscle (M) than for the liver (L) form of mitochondrial carnitine palmitoyltransferase I (CPT I), we sought to determine which cell type(s) accounts for this expression pattern and how it might relate to reproductive function. Studies with immature (14-day-old) and adult animals included 1) Northern blot analysis of testis mRNA; 2) in situ hybridization with slices of testis; 3) enzyme assays for CPT I, CPT II, and carnitine acetyltransferase (CAT) in testicular germ cells and nongerm cells, together with measurement of the malonyl-coenzyme A (CoA) sensitivity and affinity for carnitine of CPT I; 4) labeling of testicular CPT I with [3H]etomoxir, a covalent inhibitor of the enzyme; and 5) the response of testicular and nontesticular CPT I to dietary etomoxir. The data established the following: 1) L-CPT I was the sole isoform detected in immature testis. 2) Expression of the M-CPT I gene was associated only with meiotic and postmeiotic germ cells. 3) Adult testis contains a mixture of the L- and M-CPT I enzymes, the L and M form dominating in extratubular cells and spermatids, respectively. Mature epididymal spermatozoa appear to be devoid of CPT I activity while possessing abundant levels of CPT II and CAT. 4) Five days of dietary etomoxir treatment at a dose that resulted in essentially complete inhibition of CPT I in liver, heart, skeletal muscle, and kidney was totally without effect on either the L- or M-type enzyme in the testis of mature rats. The data point to an important role for transient expression of M-CPT I, coupled with sustained activity of CAT, in the maturation and/or function of rat sperm. They also suggest that, at least in the case of one CPT I inhibitor (etomoxir), the testis is unusually resistant to the agent when given orally.

Topological and functional analysis of the rat liver carnitine palmitoyltransferase 1 expressed in Saccharomyces cerevisiae.

The rat liver carnitine palmitoyltransferase 1 (L-CPT 1) expressed in Saccharomyces cerevisiae was correctly inserted into the outer mitochondrial membrane and shared the same folded conformation as the native enzyme found in rat liver mitochondria. Comparison of the biochemical properties of the yeast-expressed L-CPT 1 with those of the native protein revealed the same detergent lability and similar sensitivity to malonyl-CoA inhibition and affinity for carnitine. Normal Michaelis-Menten kinetics towards palmitoyl-CoA were observed when careful experimental conditions were used for the CPT assay. Thus, the expression in S. cerevisiae is a valid model to study the structure-function relationships of L-CPT 1.

Mouse white adipocytes and 3T3-L1 cells display an anomalous pattern of carnitine palmitoyltransferase (CPT) I isoform expression during differentiation. Inter-tissue and inter-species expression of CPT I and CPT II enzymes.

The outer mitochondrial membrane enzyme carnitine palmitoyltransferase I (CPT I) represents the initial and regulated step in the beta-oxidation of fatty acids. It exists in at least two isoforms, denoted L (liver) and M (muscle) types, with very different kinetic properties and sensitivities to malonyl-CoA. Here we have examined the relative expression of the CPT I isoforms in two different models of adipocyte differentiation and in a number of rat tissues. Adipocytes from mice, hamsters and humans were also evaluated. Primary monolayer cultures of undifferentiated rat preadipocytes expressed solely L-CPT I, but significant levels of M-CPT I emerged after only 3 days of differentiation in vitro; in the mature cell M-CPT I predominated. In sharp contrast, the murine 3T3-L1 preadipocyte expressed essentially exclusively L-CPT I, both in the undifferentiated state and throughout the differentiation process in vitro. This was also true of the mature mouse white fat cell. Fully developed adipocytes from the hamster and human behaved similarly to those of the rat. Thus the mouse white fat cell differs fundamentally from those of the other species examined in terms of tis choice of a key regulatory enzyme in fatty acid metabolism. In contrast, brown adipose tissue from all three rodents displayed the same isoform profiles, each expressing overwhelmingly M-CPT I. Northern blot analysis of other rat tissues established L-CPT I as the dominant isoform not only in liver but also in kidney, lung, ovary, spleen, brain, intestine and pancreatic islets. In addition to its primacy in skeletal muscle, heart and fat, M-CPT I was also found to dominate the testis. The same inter-tissue isoform pattern (with the exception of white fat) was found in the mouse. Taken together, the data bring to light an intriguing divergence between white adipocytes of the mouse and other mammalian species. They also raise a cautionary note that should be considered in the choice of animal model used in further studies of fat cell physiology.

Increased lipogenic capacity of the islets of obese rats: a role in the pathogenesis of NIDDM.

The onset of NIDDM in obese Zucker diabetic fatty (fa/fa) rats is preceded by a striking increase in the plasma levels of free fatty acids (FFAs) and by a sixfold rise in triglyceride content in the pancreatic islets. The latter finding provides clear evidence of elevated tissue levels of long-chain fatty acyl CoA, which can impair beta-cell cell function. To determine if the triglyceride accumulation is entirely the passive consequence of high plasma FFA levels or if prediabetic islets have an increased lipogenic capacity that might predispose to NIDDM, the metabolism of long-chain fatty acids was compared in islets of obese prediabetic and nonprediabetic Zucker diabetic fatty (ZDF) rats and of lean Wistar and lean ZDF rats. When cultured in 1 or 2 mmol/l FFA, islets of both female and male obese rats accumulated, respectively, 7 and 15 times as much triglyceride as islets from lean rats exposed to identical FFA concentrations. The esterification of [14C]palmitate and 9,10-[3H]palmitate was increased in islets of male obese rats and could not be accounted for by defective oxidation of 9,10-[3H]-palmitate. Glycerol-3-PO4 acyl-transferase (GPAT) activity was 12 times that of controls. The mRNA of GPAT was increased in islets of obese rats. We conclude that, in the presence of comparable elevations in FFA concentrations, the islets of obese prediabetic rats have a higher lipogenic capacity than controls. This could be a factor in their high risk of diabetes.

Fatty acids rapidly induce the carnitine palmitoyltransferase I gene in the pancreatic beta-cell line INS-1.

Fatty acids are important metabolic substrates for the pancreatic beta-cell, and long term exposure of pancreatic islets to elevated concentrations of fatty acids results in an alteration of glucose-induced insulin secretion. Previous work suggested that exaggerated fatty acid oxidation may be implicated in this process by a mechanism requiring changes in metabolic enzyme expression. We have therefore studied the regulation of carnitine palmitoyltransferase I (CPT I) gene expression by fatty acids in the pancreatic beta-cell line INS-1 since this enzyme catalyzes the limiting step of fatty acid oxidation in various tissues. Palmitate, oleate, and linoleate (0.35 mM) elicited a 4-6-fold increase in CPT I mRNA. The effect was dose-dependent and was similar for saturated and unsaturated fatty acids. It was detectable after 1 h and reached a maximum after 3 h. The induction of CPT I mRNA by fatty acids did not require their oxidation, and 2-bromopalmitate, a nonoxidizable fatty acid, increased CPT I mRNA to the same extent as palmitate. The induction was not prevented by cycloheximide treatment of cells indicating that it was mediated by pre-existing transcription factors. Neither glucose nor pyruvate and various secretagogues had a significant effect except glutamine (7 mM) which slightly induced CPT I mRNA. The half-life of the CPT I transcript was unchanged by fatty acids, and nuclear run-on analysis showed a rapid (less than 45 min) and pronounced transcriptional activation of the CPT I gene by fatty acids. The increase in CPT I mRNA was followed by a 2-3-fold increase in CPT I enzymatic activity measured in isolated mitochondria. The increase in activity was time-dependent, detectable after 4 h, and close to maximal after 24 h. Fatty acid oxidation by INS-1 cells, measured at low glucose, was also 2-3-fold higher in cells cultured with fatty acid in comparison with control cells. Long term exposure of INS-1 cells to fatty acid was associated with elevated secretion of insulin at a low (5 mM) concentration of glucose and a decreased effect of higher glucose concentrations. It also resulted in a decreased oxidation of glucose. The results indicate that the CPT I gene is an early response gene induced by fatty acids at the transcriptional level in beta- (INS-1) cells. It is suggested that exaggerated fatty acid oxidation caused by CPT-1 induction is implicated in the process whereby fatty acids alter glucose-induced insulin secretion.

Essentiality of circulating fatty acids for glucose-stimulated insulin secretion in the fasted rat.

We asked whether the well known starvation-induced impairment of glucose-stimulated insulin secretion (GSIS) seen in isolated rat pancreas preparations also applies in vivo. Accordingly, fed and 18-24-h-fasted rats were subjected to an intravenous glucose challenge followed by a hyperglycemic clamp protocol, during which the plasma-insulin concentration was measured. Surprisingly, the acute (5 min) insulin response was equally robust in the two groups. However, after infusion of the antilipolytic agent, nicotinic acid, to ensure low levels of plasma FFA before the glucose load, GSIS was essentially ablated in fasted rats, but unaffected in fed animals. Maintenance of a high plasma FFA concentration by coadministration of Intralipid plus heparin to nicotinic acid-treated rats (fed or fasted), or further elevation of the endogenous FFA level in nonnicotinic acid-treated fasted animals by infusion of etomoxir (to block hepatic fatty acid oxidation), resulted in supranormal GSIS. The in vivo findings were reproduced in studies with the perfused pancreas from fed and fasted rats in which GSIS was examined in the absence and presence of palmitate. The results establish that in the rat, the high circulating concentration of FFA that accompanies food deprivation is a sine qua non for efficient GSIS when a fast is terminated. They also serve to underscore the powerful interaction between glucose and fatty acids in normal beta cell function and raise the possibility that imbalances between the two fuels in vivo could have pathological consequences.

Expression of a cDNA isolated from rat brown adipose tissue and heart identifies the product as the muscle isoform of carnitine palmitoyltransferase I (M-CPT I). M-CPT I is the predominant CPT I isoform expressed in both white (epididymal) and brown adipocytes.

We set out to determine if the cDNA encoding a carnitine palmitoyltransferase (CPT)-like protein recently isolated from rat brown adipose tissue (BAT) by Yamazaki et al. (Yamazaki, N., Shinohara, Y., Shima, A., and Terada, H. (1995) FEBS Lett. 363, 41-45) actually encodes the muscle isoform of mitochondrial CPT I (M-CPT I). To this end, a cDNA essentially identical to the original BAT clone was isolated from a rat heart library. When expressed in COS cells, the novel cDNA and our previously described cDNA for rat liver CPT I (L-CPT I) gave rise to products with the same kinetic characteristics (sensitivity to malonyl-CoA and Km for carnitine) as CPT I in skeletal muscle and liver mitochondria, respectively. When labeled with [3H]etomoxir, recombinant L-CPT I and putative M-CPT I, although having approximately the same predicated masses (88.2 kDa), migrated differently on SDS gels, as did CPT I from liver and muscle mitochondria. The same was true for the products of in vitro transcription and translation of the L-CPT I and putative M-CPT I cDNAs. We conclude that the BAT cDNA does in fact encode M-CPT I. Northern blots using L- and M-CPT I cDNA probes revealed the presence of L-CPT I mRNA in liver and heart and its absence from skeletal muscle and BAT. M-CPT I mRNA, which was absent from liver, was readily detected in skeletal muscle and was particularly strong in heart and BAT. Whereas the signal for L-CPT I was more abundant than that for M-CPT I in RNA isolated from whole epididymal fat pad, this was reversed in purified adipocytes from this source. These findings, coupled with the kinetic properties and migration profiles on SDS gels of CPT I in brown and white adipocytes, indicate that the muscle form of the enzyme is the dominant, if not exclusive, species in both cell types.

Cyclic AMP and fatty acids increase carnitine palmitoyltransferase I gene transcription in cultured fetal rat hepatocytes.

In the rat, the gene for liver mitochondrial carnitine palmitoyltransferase I (CPT I), though dormant prior to birth, is rapidly activated postnatally. We sought to elucidate which hormonal and/or nutritional factors might be responsible for this induction. In cultured hepatocytes from 20-day-old rat fetus, the concentration of CPT I mRNA, which initially was very low, increased dramatically in a dose-dependent manner after exposure of the cells to dibutyryl cAMP (Bt2cAMP). Similar results were obtained when long-chain fatty acids (LCFA), but not medium-chain fatty acids, were added to the culture medium. The effects of Bt2cAMP and LCFA were antagonized by insulin, also dose dependently. In contrast, CPT II gene expression, which was already high in fetal hepatocytes, was unaffected by any of the above manipulations. Bt2cAMP stimulated CPT I gene expression even when endogenous triacylglycerol breakdown was suppressed by lysosomotropic agents suggesting that the actions of cAMP and LCFA were distinct. Moreover, half-maximal concentrations of Bt2cAMP and linoleate produced an additive effect CPT I mRNA accumulation. While linoleate and Bt2cAMP stimulated CPT I gene transcription by twofold and fourfold, respectively, the fatty acid also increased the half-life of CPT I mRNA (50%). When hepatocytes were cultured in the presence of 2-bromopalmitate, (which is readily converted by cells into its non-metabolizable CoA ester) CPT I mRNA accumulation was higher than that observed with oleate or linoleate. Similarly, the CPT I inhibitor, tetradecylglycidate, which at a concentration of 20 microM did not itself influence the CPT I mRNA level, enhanced the stimulatory effect of linoleate. The implication is that induction of the CPT I message by LCFA does not require mitochondrial metabolism of these substrates; however, formation of their CoA esters is a necessary step. Unlike linoleate, the peroxisome proliferator, clofibrate, increased both CPT I and CPT II mRNA levels and neither effect was offset by insulin. It thus appears that the mechanism of action of LCFA differs from that utilized by clofibrate, which presumably works through the peroxisome proliferator activated receptor. We conclude that the rapid increase in hepatic CPT I mRNA level that accompanies the fetal to neonatal transition in the rat is triggered by the reciprocal change in circulating insulin and LCFA concentrations, coupled with elevation of the liver content of cAMP.

Human liver mitochondrial carnitine palmitoyltransferase I: characterization of its cDNA and chromosomal localization and partial analysis of the gene.

Using the cDNA for rat liver mitochondrial carnitine palmitoyltransferase I (CPT I; EC 2.3.1.21) as a probe, we isolated its counterpart as three overlapping clones from a human liver cDNA library. Both the nucleotide sequence of the human cDNA and the predicted primary structure of the protein (773 aa) proved to be very similar to those of the rat enzyme (82% and 88% identity, respectively). The CPT I mRNA size was also found to be the same (approximately 4.7 kb) in both species. Screening of a human genomic library with the newly obtained cDNA yielded a positive clone of approximately 6.5 kb which, upon partial analysis, was found to contain at least two complete exons linked by a 2.3-kb intron. Oligonucleotide primers specific to upstream and downstream regions of one of the exon/intron junctions were tested in PCRs with DNA from a panel of somatic cell hybrids, each containing a single human chromosome. The results allowed unambiguous assignment of the human liver CPT I gene to the q (long) arm of chromosome 11. Additional experiments established that liver and fibroblasts express the same isoform of mitochondrial CPT I, legitimizing the use of fibroblast assays in the differential diagnosis of the "muscle" and "hepatic" forms of CPT deficiency. The data provide insights into the structure of a human CPT I isoform and its corresponding gene and establish unequivocally that CPT I and CPT II are distinct gene products. Availability of the human CPT I cDNA should open the way to an understanding of the genetic basis of inherited CPT I deficiency syndromes, how the liver CPT I gene is regulated, and which tissues other than liver express this particular variant of the enzyme.

Expression of a cDNA for rat liver carnitine palmitoyltransferase I in yeast establishes that catalytic activity and malonyl-CoA sensitivity reside in a single polypeptide.

A cDNA encoding full-length carnitine palmitoyltransferase I (CPT I) from rat liver was expressed in Saccharomyces cerevisiae, a system devoid of endogenous CPT activity. The recombinant enzyme was of the expected size (as deduced from immunoblots), membrane-bound, and detergent-labile. It was also potently inhibited by malonyl-CoA, with an I50 value (concentration causing 50% inhibition) of approximately 5 microM, similar to that of the native enzyme in rat liver mitochondria. A truncated variant of the enzyme that lacked the amino-terminal 82 residues encompassing the first hydrophobic domain retained catalytic function but was much less sensitive to malonyl-CoA (I50 > 80 microM). Deletion of the cDNA segment encoding amino acids 31-148 (which includes both first and second hydrophobic stretches) resulted in no detectable product. The data establish unequivocally that a single polypeptide possesses both catalytic and malonyl-CoA binding domains, as well as the other properties previously attributed by us to native CPT I in mammalian mitochondria, and should thus put to rest the controversy surrounding this issue (Kerner, J., Zaluzec, E., Gage, D., and Bieber, L. L. (1994) J. Biol. Chem. 269, 8209-8219). In addition, the results strengthen the view that one site of interaction of malonyl-CoA with the rat liver enzyme involves the NH2-terminal region of the molecule.

Rat heart expresses two forms of mitochondrial carnitine palmitoyltransferase I. The minor component is identical to the liver enzyme.

To begin to explore the basis for the tissue-specific expression of mitochondrial carnitine palmitoyltransferase I (CPT I), we focused on three rat tissues (liver, heart, and skeletal muscle) in which the enzyme was known to display very different properties. In Northern blot analysis, a cDNA probe corresponding to liver CPT I readily hybridized to a 4.5-kilobase species of mRNA in liver and heart, but not in skeletal muscle. Using the same probe to screen a neonatal rat heart cDNA library, a full-length clone, surprisingly having 100% sequence identity to the liver CPT I cDNA, was isolated. The paradox was resolved by two additional experiments. First, in Western blots of mitochondrial membranes, an antibody raised against liver CPT I recognized the 88-kDa protein in heart, as well as in liver, but not in skeletal muscle. Second, high specific activity [3H]deschloroetomoxir (a covalent ligand for CPT I) reacted with a single form of CPT I in liver (approximately 88 kDa) and skeletal muscle (approximately 82 kDa), while proteins of both sizes were labeled in the cardiac myocyte. Tritiated ligand binding to the two heart proteins was blocked by excess unlabeled malonyl-CoA. It is concluded that liver and skeletal muscle each contains a single and distinct isoform of CPT I with monomeric size of approximately 88 and 82 kDa, respectively. The heart contains a CPT I protein of approximately 82 kDa in size (probably identical to the skeletal muscle protein) but, importantly, also expresses the liver-type enzyme. The results likely explain why previous studies of heart CPT I yielded an apparent Km for carnitine and I50 value for malonyl-CoA inhibition that were intermediate between those of the liver and skeletal muscle enzymes.

Expression of liver carnitine palmitoyltransferase I and II genes during development in the rat.

The enzyme activity and the expression (protein and mRNA concentrations) of genes encoding for hepatic carnitine palmitoyl-transferases (CPT) I and II were studied during neonatal development, in response to nutritional state at weaning and during the fed-starved transition in adult rats. The activity, the protein concentration and the level of mRNA encoding CPT I are low in foetal-rat liver and increase 5-fold during the first day of extra-uterine life. The activity and gene expression of CPT I are high during the entire suckling period, in the liver of 30-day-old rats weaned at 20 days on to a high-fat diet and in the liver of 48 h-starved adult rats. The activity and CPT I gene expression are markedly decreased in the liver of rats weaned on to a high-carbohydrate diet. By contrast, the activity, the protein concentration and the level of mRNA encoding CPT II are already high in the liver of term foetuses and remain at this level throughout the suckling period, irrespective of the nutritional state of the animals either at weaning or in the adult.

Inhibitors of mitochondrial carnitine palmitoyltransferase I limit the action of proteases on the enzyme. Isolation and partial amino acid analysis of a truncated form of the rat liver isozyme.

Our objective was to isolate from rat liver mitochondria the malonyl-CoA-regulated and detergent-labile enzyme, carnitine palmitoyltransferase I (CPT I), whose properties and relationship to CPT II have been the subject of debate. After exposure of mitochondria to the dinitrophenol derivative of etomoxir-CoA (DNP-Et-CoA, a covalent inhibitor of CPT I), followed by detergent solubilization and blue Sepharose chromatography, the DNP-Et-labeled CPT I could be readily visualized on immunoblots using an anti-DNP monoclonal antibody. This material was used to raise a rabbit polyclonal antibody that recognized CPT I regardless of whether it was carrying a covalent ligand. Exposure of membranes from untreated mitochondria to a mixture of trypsin and chymotrypsin caused rapid loss of CPT I activity with a concomitant disappearance of immunodetectable protein. However, inclusion of malonyl-CoA in such incubations afforded major protection of CPT I activity. Under these conditions CPT I simply underwent truncation from approximately 90 to approximately 82 kDa. This was also true if CPT I had first been labeled with Et-CoA or DNP-Et-CoA prior to protease treatment. Thus, the presence of an inhibitor, whether reversible or irreversible, at the active site of CPT I limited the action of trypsin/chymotrypsin to removal of a small portion of the protein which was probably not necessary for catalytic function. These and other experiments with antibodies and proteases provided additional insight into the membrane topology of CPT I. They also strengthened our conviction that CPT I and CPT II are distinct proteins and that the former exists as tissue-specific isoforms. Finally, the 82-kDa truncated form of rat liver CPT I was isolated and subjected to partial amino acid analysis. Four unambiguous peptide sequences were obtained.

Cloning, sequencing, and expression of a cDNA encoding rat liver carnitine palmitoyltransferase I. Direct evidence that a single polypeptide is involved in inhibitor interaction and catalytic function.

We report the isolation and characterization of a full-length cDNA encoding rat liver carnitine palmitoyltransferase I (CPT I). Oligonucleotides corresponding to two tryptic peptides derived from the malonyl-CoA/etomoxir-CoA-binding protein of rat liver mitochondria (Esser, V., Kuwajima, M., Britton, C. H., Krishnan, K., Foster, D. W., and McGarry, J. D. (1993) J. Biol. Chem. 268, 5810-5816) were used to screen a rat liver cDNA library constructed in the plasmid cloning vector, pcDV. The clone obtained consisted of a 102-nucleotide 5'-untranslated region, a single open reading frame of 2,319 bases predicting a protein of 773 amino acids (M(r) = 88,150), and a 3'-untranslated segment of 1,957 nucleotides followed by the poly(A)+ tail. A 0.9-kilobase fragment of the cDNA recognized a single species of mRNA (approximately 4.7 kilobases in size) in rat liver. The identity of the cDNA was confirmed by the findings that (i) the open reading frame encoded all four peptides found in the original protein; (ii) transfection of COS cells with the cDNA subcloned into the expression vector, pCMV6, resulted in a selective and 10-20-fold induction of a malonyl-CoA- and etomoxir-CoA-sensitive CPT activity; and (iii) the overexpressed product was readily detected on Western blots by an antibody raised against the starting material. It seems likely that the de novo synthesized enzyme is targeted to the mitochondrial outer membrane via a leader peptide and that the mature protein achieves membrane anchoring through a stretch of 20 amino acids present near its amino terminus. The predicted amino acid sequence of the protein shows regions of strong identity with those of three other rat acyltransferases, namely, liver CPT II, liver carnitine octanoyltransferase, and brain choline acetyltransferase. The findings provide the first insight into the structure of a CPT I isoform. They also establish unequivocally that CPT I and CPT II are distinct proteins and that inhibitors of CPT I interact within its catalytic domain, not with an associated regulatory component.

Cholesterol-mediated suppression of alpha 1-inhibitor III, a plasma alpha-macroglobulin family protein.

Using differential hybridization techniques we have isolated a hamster cDNA encoding a cholesterol-regulated protein. By sequence homology we concluded that the isolated cDNA encodes alpha 1-inhibitor III (alpha 1 I3), a protein of the alpha-macroglobulin (alpha M) family. When hamsters were fed diets rich in cholesterol, cholic acid, or chenodeoxycholic acid, the amount of alpha 1I3 RNA was reduced between 5- and 10-fold. Drugs that lower plasma cholesterol levels, such as colestipol and mevinolin, increased alpha 1I3 RNA between 2- and 3-fold. Additionally, plasma alpha 1I3 protein levels, as measured by immunoblotting techniques using an anti-human alpha 2M antibody, correlate well with alpha 1I3 RNA levels in those hamsters. Plasma alpha 1I3 protein was inversely proportional to plasma cholesterol levels in those hamsters. The observed suppression of alpha 1I3 expression by cholesterol mimics the cholesterol-mediated regulation of other genes that maintain cholesterol homeostasis, such as 3-hydroxy-3-methylglutaryl coenzyme A synthase, 3-hydroxy-3-methylglutaryl coenzyme A reductase, and low density lipoprotein receptor. We hypothesize that alpha 1I3 may play a role in the onset of atherosclerosis and may provide a link between cholesterol and the clotting system. Furthermore, the availability of another sterol-regulated gene, like alpha 1I3, should help elucidate the molecular mechanisms of cholesterol-mediated regulation of gene transcription.