Biochemical and evolutionary significance of phospholipid methylation

All nucleated mammalian cells synthesize phosphatidylcholine from choline via the CDP-choline pathway. Hepatocytes have a second pathway for the synthesis of phosphatidylcholine, a stepwise methylation of phosphatidylethanolamine, catalyzed by phosphatidylethanolamine N-methyltransferase and encoded by the Pempt gene. We report that when Pempt-deficient mice were fed a choline-deficient diet for 3 days, severe liver pathology occurred apparently due to a lack of phosphatidylcholine biosynthesis. The hepatic concentration of phosphatidylcholine decreased by 50% compared with wild type mice on the diet. The levels of plasma triacylglycerols and cholesterol were decreased by greater than 90% in the Pempt-deficient mice. We suggest that the Pempt gene has been maintained during evolution to provide phosphatidylcholine when dietary choline is insufficient, as might occur during starvation or pregnancy.     

Phosphatidylethanolamine N-methyltransferase: unexpected findings from curiosity-driven research

In the process of investigating basic questions about the function of the enzyme phosphatidyl-ethanolamine N-methyltransferase (PEMT), we have made several unexpected findings. PEMT catalyzes the conversion of phosphatidylethanolamine to phosphatidylcholine in hepatocytes. A novel isoform, PEMT2, has been cloned, expressed and localized to a mitochondria-associated membrane in rat liver. Expression of PEMT2 in cultured rat hepatoma cells decreased the rate of cell division. Mechanistic studies suggest that the slower growth of transfected hepatoma cells is due to down regulation of CTP:phosphocholine cytidylyltransferase and the CDP-choline pathway for phosphatidylcholine biosynthesis. A role for PEMT2 in the regulation of hepatocyte cell division is also indicated by PEMT2 down-regulation in regenerating rat liver. Another unexpected finding was the discovery that PEMT2 is a liver specific tumor suppressor. Also surprising was the finding that expression of PEMT2 does not rescue mutant Chinese hamster ovary cells that have a temperature sensitive defect in the CDP-choline pathway even though the levels of phosphatidylcholine are returned to normal. Thus, curiosity-driven research has resulted in unexpected findings about PEMT and its function in liver.     

Cloning of a human cDNA for CTP-phosphoethanolamine cytidylyltransferase by complementation in vivo of a yeast mutant

CTP-phosphoethanolamine cytidylyltransferase (ET) is the enzyme that catalyzes the formation of CDP-ethanolamine in the phosphatidylethanolamine biosynthetic pathway from ethanolamine. We constructed a Saccharomyces cerevisiae mutant of which the ECT1 gene, putatively encoding ET, was disrupted. This mutant showed a growth defect on ethanolamine-containing medium and a decrease of ET activity. A cDNA clone was isolated from a human glioblastoma cDNA expression library by complementation of the yeast mutant. Introduction of this cDNA into the yeast mutant clearly restored the formation of CDP-ethanolamine and phosphatidylethanolamine in cells. ET activity in transformants was higher than that in wild-type cells. The deduced protein sequence exhibited homology with the yeast, rat, and human CTP-phosphocholine cytidylyltransferases, as well as yeast ET. The cDNA gene product was expressed as a fusion with glutathione S-transferase in Escherichia coli and shown to have ET activity. These results clearly indicate that the cDNA obtained here encodes human ET.     

Regulation of human erythropoietin gene induction by upstream flanking sequences in transgenic mice

Human erythropoietin (Epo) gene expression is inducible by hypoxia or anaemia in the kidney and liver. Previous transgenic mouse experiments have demonstrated that sequences required for Epo gene induction in the kidney reside in a 7 8 kb Barn HI fragment located 6 kb upstream of the gene. To sublocalize these sequences, we performed Desoxyribonuclease I (DNAse I) mapping studies using transgenic mice which carried this DNA fragment. These studies revealed a DNAse I hypersensitive site (DNAse I HS) located 4 6 kb from the upstream end of the 7.8 kb fragment in anaemic kidney and liver samples. Sequence analysis of the region encompassing the DNAse I HS revealed an element with remarkable homology to the 3' Epo gene hypoxia-inducible enhancer. This suggested the presence of an additional regulatory element that contributes to the control of hypoxia-inducible Epo gene expression in kidney and liver. We constructed transgenic mice containing the human Epo gene linked to either the 5 kb upstream or 2.5 kb downstream portion of the 7.8kb fragment. Inducible expression was limited to the liver. Thus, neither fragment was alone sufficient to confer kidney inducible expression. These findings indicate that sequences more than 8.5 kb upstream of the Epo gene are required for kidney-specific induction. They suggest that either those sequences reside in an 0.3 kb Hind III fragment located between the 5 kb and the 2.5 kb fragments or that sequences in the 5 kb or 0.3 kb fragments must interact with sequences in the 2.5 kb fragment to allow Epo gene induction in the kidney.     

Adriamycin depresses in vivo and in vitro phosphatidylethanolamine N-methylation in rat heart sarcolemma

Adriamycin, an effective anticancer chemotherapeutic agent, causes an insidious and delayed cardiotoxicity. Different subcellular abnormalities including calcium transport changes in the sarcolemma (SL) as well as downregulation of the adrenergic system have been shown to be associated with the development of this cardiomyopathy. Since both of these activities are influenced by phospholipid methylation, effects of adriamycin on the three catalytic sites of SL phosphatidylethanolamine N-methyltransferase were examined. Rats were administered with a cumulative dose of adriamycin (15 mg/kg) over 2 weeks and examined after 3 weeks. Vehicle injected animals served as controls. Dyspnea, high mortality rate, ascites and decrease in aortic and left ventricular systolic pressure, as well as increase in left ventricular end diastolic pressure were seen in the adriamycin group. Myocardial cell damage typical of adriamycin cardiomyopathy, i.e. sarcotubular swelling, vacuolization and myofibrillar drop-out, was also apparent. Total methyl group incorporation into SL phosphatidylethanolamine using radiolabeled S-adenosyl-L-methionine as the donor was significantly depressed in the 3 week group at catalytic sites II and III. Decreased production of methylated intermediates, phosphatidyl-N-monomethylethanolamine and phosphatidyl-N,N-dimethylethanolamine as well as phosphatidylcholine (PC) was seen. Depression of phosphatidylethanolamine N-methylation was also noticed when SL, isolated from untreated hearts, was exposed in vitro to different concentrations (10, 100 and 1000 microM) of adriamycin. Inhibition of phosphatidylethanolamine N-methylation appears to be mediated by adriamycin-induced increase in the oxidative stress and may contribute in the pathogenesis of subcellular changes associated with this cardiomyopathy.     

cDNA cloning, sequencing, and characterization of male and female rat liver aldehyde oxidase (rAOX1). Differences in redox status may distinguish male and female forms of hepatic APX

Molecular characterization of male and female rat liver aldehyde oxidase is reported. As described for the mouse liver, male and female rat liver expressed kinetically distinct forms of aldehyde oxidase. Our data suggest that the two forms arise as a result of differences in redox state and are most simply explained by expression of a single gene encoding aldehyde oxidase in rats. In support of this argument we have sequenced cDNAs from male and female rat liver. We examined mRNA expression by Northern blot analysis with RNA from males and females, from several tissues, and following androgen induction. Purified rat liver enzyme from males or females revealed a single 150-kDa species consistent with cDNA sequence analysis. Both male and female forms were reactive to the same carboxyl-terminal directed antisera. Km(app) values obtained in crude extracts of male or female rat liver and post-benzamidine-purified aldehyde oxidase differed substantially from each other but could be interconverted by chemical reduction with dithiothreitol or oxidation with 4,4'-dithiodipyridine. Our data indicate that a single gene is most likely expressed in male or female rat liver and that the kinetic differences between male and female rat liver aldehyde oxidases are sensitive to redox manipulation.     

Open questions in photobiology. IV. Photoaging of the skin

Two isoforms of troponin C (TnC) are encoded by distinct single copy genes. Expression of fast TnC is restricted to the skeletal muscle, whereas the slow isoform is expressed in both skeletal and cardiac muscle. Chicken slow TnC (cTnC) gene is also expressed in some non-muscle tissues like the liver and the brain. Expression of cTnC gene is regulated by two distinct enhancers in cardiac and skeletal muscles. The cardiac specific enhancer is located in the immediate 5' flanking region (bp-124 to -79) of the murine cTnC gene whereas the skeletal enhancer is located within the first intron (bp 997 to 1141). In the present study we have examined how cTnC gene expression is regulated in the chicken liver. Transient transfection of liver cells with CTnC-CAT reporter constructs containing various regions of the murine cTnC gene showed that its expression in chicken liver is regulated by the cardiac specific enhancer. Furthermore, electrophoretic mobility shift assays using synthetic oligonucleotides corresponding to both CEF-1 and CEF-2 regions of the murine cardiac enhancer revealed formation of specific DNA-protein complexes. Ultraviolet light induced covalent linking of nuclear proteins to CEF-1 and CEF-2 oligomers were used to examine the nature of the cardiac enhancer binding polypeptides; one polypeptide of 48 kDa appeared to bind to both CEF-1 and CEF-2 sequences.     

Genomic imprinting and Igf2 influence liver tumorigenesis and loss of heterozygosity in SV40 T antigen transgenic mice

Maternal-specific loss of heterozygosity (LOH) and allelic imbalances [i.e., partial LOH (pLOH)] observed in SV40 T/t antigen-induced liver tumors suggests that an imprinted gene on chromosome 7 is involved in liver tumorigenesis. Maternal-specific LOH/pLOH may reflect the loss of a maternally expressed tumor suppressor gene or the acquisition of paternally active alleles of a growth promoter. In addition, two oppositely imprinted genes on distal chromosome 7, Igf2 and H19, are re-expressed in most liver tumors from an SV40 T/t antigen transgenic line (M11T-G). Igf2 is a paternally expressed growth promoter, and H19 is a maternally expressed gene that can suppress growth in some tumor cell lines. We studied the role of Igf2 during liver tumorigenesis by creating Igf2 (+/-) M11T-G mice. These mice are essentially null for Igf2 expression because imprinting normally precludes maternal Igf2 expression. M11T-G, Igf2 (+/-) males exhibit a 15-fold reduction in the frequency of large tumors. Igf2 (+/-) tumors do not express maternal Igf2, indicating rigid imprinting control in the liver. LOH/pLOH analysis was performed on the tumors and indicates that acquisition of paternally active Igf2 alleles is a major selective event for M11T-G liver tumorigenesis. This also implies the existence of an imprinted, maternally expressed tumor suppressor gene on chromosome 7 that is unlikely to be H19.     

Biodistribution and gene expression of lipid/plasmid complexes after systemic administration

The objectives of this study were to investigate the influence of physicochemical properties of lipid/plasmid complexes on in vivo gene transfer and biodistribution characteristics. Formulations based on 1,2-di-O-octadecenyl-3-trimethylammonium propane (DOTMA) and novel biodegradable cationic lipids, such as ethyl dioleoyl phosphatidylcholine (EDOPC), ethyl palmitoyl myristyl phosphatidylcholine (EPMPC), myristyl myristoyl carnitine ester (MMCE), and oleyl oleoyl L-carnitine ester (DOLCE), were assessed for gene expression after tail vein injection of lipid/plasmid complexes in mice. Gene expression was influenced by cationic lipid structure, cationic lipid-to-colipid molar ratios, plasmid-to-lipid charge ratios, and precondensation liposome size. Detectable levels of human growth hormone (hGH) in serum, human factor IX (hFIX) in plasma, and chloramphenicol acetyltransferase (CAT) in the lung and liver were observed with positively charged lipid/plasmid complexes prepared from 400-nm extruded liposomes with a cationic lipid-to-colipid ratio of 4:1 (mol/mol). Intravenous administration of lipid/CAT plasmid complexes resulted in distribution of plasmid DNA mainly to the lung at 15 min after injection. Plasmid DNA accumulation in the liver increased with time up to 24 hr postinjection. There was a 10-fold decrease in the amount of plasmid DNA in the lung at 15 min after injection, when the lipid/plasmid complex charge ratio was decreased from 3:1 to 0.5:1 (+/-). Bright fluorescent aggregates were evident in in vivo-transfected lung with the positively charged pCMV-CAT/DOLCE:dioleyl phosphatidylethanolamine (DOPE) (1:1, mol/mol) complexes, while more discrete punctate fluorescence was observed with a 4:1 molar ratio of cationic lipid:colipid formulations. Preinjection of polyanions such as plasmid, dextran sulfate, polycytidic acid, and polyinosinic acid decreased hGH expression, whereas the preinjection of both positively charged and neutral liposomes had no effect on hGH serum levels. Of the cationic lipids tested, DOLCE was found to be the most effective potentially biodegradable cationic lipid. A correlation between gene expression and cationic lipid:colipid ratios and lipid-to-plasmid charge ratio was also observed for DOTMA- and DOLCE-based formulations.     

Refined structures of bobwhite quail lysozyme uncomplexed and complexed with the HyHEL-5 Fab fragment

The structure and expression pattern of a human gene located within a homozygously deleted region of a metastatic prostate cancer have been characterized. Multiple cDNA fragments of this gene were isolated by hybrid capture with yeast artificial chromosome clones covering the deletion region. Eleven coding exons spanned 205-220 kb of the 730- to 970-kb deletion. The predicted amino acid sequence was 43% identical to that of an anonymous Caenorhabditis elegans gene and 20% identical to an accessory or regulatory subunit of the oligosaccharyltransferase enzyme complex in Saccharomyces cerevisiae. Hydrophobicity profiles of all three gene products were similar and showed four putative membrane-spanning domains in the molecules' C-terminal halves, suggesting a general conservation of function. The gene was expressed as an approximately 1.5-kb mRNA in most nonlymphoid human cells/tissues including prostate, lung, liver, and colon. Expression was detected in many epithelial tumor cell lines, but was undetectable by Northern blot or RT-PCR in 14 of 15 colorectal, 1 of 8 lung, and 1 of 4 liver cancer cell lines. Lack of expression in tumor cell lines was highly correlated with hypermethylation of a CpG island located at the gene's 5' end. These findings form a basis for further work on this candidate tumor suppressor gene.     

Mouse liver nicotinamide N-methyltransferase: cDNA cloning, expression, and nucleotide sequence polymorphisms

Nicotinamide N-methyltransferase (NNMT) catalyzes the N-methylation of nicotinamide and structurally related compounds. We cloned mouse liver NNMT cDNA to make it possible to test the hypothesis that large differences among strains in levels of hepatic NNMT activity might be associated with strain-dependent variation in NNMT amino acid sequence. Mouse liver NNMT cDNA was 1015 nucleotides in length with a 792 nucleotide open reading frame (ORF) that was 83% identical to the nucleotide sequence of the human liver NNMT cDNA ORF. The mouse liver cDNA encoded a 264 amino acid protein with a calculated Mr value of 29.6 kDa. NNMT cDNA ORF sequences were then determined in five inbred strains of mice with very different levels of hepatic NNMT enzymatic activity. Although multiple differences among strains in nucleotide sequence were observed, none altered encoded amino acids. cDNA sequences for C57BL/6J and C3H/HeJ mice, prototypic strains with "high" and "low" levels of hepatic NNMT activity, respectively, were then expressed in COS-1 cells. Both expression constructs yielded comparable levels of enzyme activity, and biochemical properties of the expressed enzyme, including apparent Km values for substrates and IC50 values for inhibition by N1-methylnicotinamide, were very similar to those of mouse liver NNMT. Growth and development experiments were then conducted, which demonstrated that, although at 8 weeks of age average hepatic NNMT activity in C57BL/6J mice was 5-fold higher than that in C3H/HeJ mice, activities in the two strains were comparable by 30 weeks of age--indicating strain-dependent variation in the developmental expression of NNMT in mouse liver. These observations will serve to focus future studies of strain-dependent differences in murine hepatic NNMT on the regulation of the enzyme activity during growth and development.