Production of delta-aminolevulinate: subcellular localization and purification of murine hepatic L-alanine: 4,5-dioxovaleric acid aminotransferase

1. L-Alanine: 4,5-dioxovaleric acid aminotransferase (DOVA transaminase) activity was measured in murine liver, kidney and spleen homogenates. 2. Among the organs examined, the specific activity of the enzyme was highest in kidney, followed by liver then spleen. 3. No differences in DOVA transaminase activity in kidney, liver and spleen homogenates were detected between mouse strains C57BL/6J and DBA/2J. 4. Based on enzyme activity, the capacity of DOVA transaminase to catalyze the formation of delta-aminolevulinic acid (ALA) in liver appeared much greater than the capacity of ALA synthase. 5. In DBA/2J animals, DOVA transaminase activity in liver mitochondrial fractions prepared by differential centrifugation was 24 nmol ALA formed/hr/mg protein compared with 0.63 nmol ALA formed/hr/mg protein for ALA synthase. 6. Cell fractionation analyses indicated that liver DOVA transaminase is located in the mitochondrial matrix. 7. The liver enzyme was purified from mitoplasts by chromatography on DEAE-Sephacel followed by affinity chromatography on L-alanine-AH-Sepharose. 8. The specific activity of the purified DOVA transaminase was 1600 nmol ALA formed/hr/mg protein. 9. The yield of the purification was ca 90 micrograms of protein per gram liver wet weight. 10. The purified enzyme had a subunit mol. wt of 146,000 +/- 5000 as determined by electrophoresis under denaturing conditions.     

Cloning of two adult hamster globin cDNAs (alpha and beta major).

A cDNA library was prepared from poly(A) mRNA extracted from adult anemic hamster spleen erythroid cells. cDNA clones containing inserts coding for adult alpha and beta major globin chains were isolated. Their identity was confirmed by (a) translation of hybrid selected mRNA and (b) nucleotide sequence analysis of the inserts and comparison to the adult globin cDNAs of mouse, rabbit and human. Availability of sequences for embryonic (Li et al. (1992) Biochim. Biophys. Acta 1130, 218-220) and adult globin cDNAs (this report) will aid in investigations of the molecular mechanisms involved in the globin ontogeny of hamsters.     

Regulation of haem biosynthesis in normoblastic erythropoiesis: role of 5-aminolaevulinic acid synthase and ferrochelatase

The development of haem biosynthetic enzyme activity during normoblastic human erythropoiesis was examined in seven patients. The first and last enzymes of the haem biosynthetic pathway, ALA synthase and ferrochelatase, were assayed by radiochemical/high performance liquid chromatographic (HPLC) methods. An assay for ferrochelatase activity in human bone marrow was developed. Enzyme substrates were protoporphyrin IX and ⁵⁹Fe²⁺ ions. ⁵⁹Fe-labelled haem was isolated by organic solvent extraction/sorbent extraction followed by reversed-phase HPLC. Optimal activity occurred at pH 7.3 in the presence of ascorbic acid, in darkness and under anaerobic conditions. Haem production was proportional to cell number and was linear with time to 30 min. The assay was sensitive to the picomolar range of haem production. ALA synthase and ferrochelatase activity was assayed in four highly purified age-matched erythroid cell populations. ALA synthase activity was maximal in the most immature erythoid cells and diminished as the cells matured with an overall five fold loss of activity from proerythroblast to late erythroblast development. Ferrochelatase activity was, however, more stable with less than a two fold change in activity observed during the same period of erythroid differentiation. Maximal activity occurred in erythroid fractions enriched with intermediate erythroblasts. These results support sequential rather than simultaneous appearance of these enzymes during normoblastic erythropoiesis. Quantitative analysis of relative enzyme activity however indicates that at all times during erythroid differentiation ferrochelatase activity is present in excess to that theoretically required relative to ALA synthase activity since ALA and haem are not produced in stoichiometric amounts. The lability of ALA synthase versus the stability and gross relative excess of ferrochelatase activity indicates a far greater role for ALA synthase in the regulation of erythroid haem biosynthesis than for ferrochelatase.     

Isolation of mouse and human cDNA clones encoding a protein expressed specifically in osteoblasts and brain tissues.

Using the differential hybridization screening method between osteoblastic and fibroblastic cells, a cDNA clone coding for an osteoblast specific protein, named OSF-1, consisting of 168 amino acid residues including a possible 32 amino acid long leader sequence, was isolated from murine osteoblastic cell line MC3T3-E1. The OSF-1 gene was shown by Northern blotting analysis to be expressed in mouse calvarial osteoblast-enriched cells and in mouse brain tissues, but not in thymus, spleen, kidney, liver, lung, testis or heart. The human counterpart was also found in cDNA libraries from human osteosarcoma cell line MG63 and normal brain tissues. DNA sequence analysis revealed four amino acid sequence differences between the mouse and human, of which only one is located in the mature protein. This extremely high sequence conservation suggests that OSF-1 plays a fundamental role in bone and brain functions.     

Molecular cloning, sequencing, and expression of mouse ferrochelatase

The cDNA encoding mouse ferrochelatase (protoheme ferrolyase, EC 4.99.1.1) was isolated from a mouse erythroleukemia (MEL) cell cDNA library in lambda gt11 expression vector, by immunoscreening with a polyclonal antibody. Two full-length clones containing cDNA inserts of 2.2 and 2.90 kilobases were obtained. These clones have the same entire enzyme coding region, but alternative putative polyadenylation sites in the 3'-noncoding regions. From the deduced primary structure, a putative leader sequence of 53 amino acid residues resulted in a precursor protein of 420 amino acid residues (Mr 47,130) and a mature protein of 367 residues (Mr 41,692). The cDNA allows for the expression of active ferrochelatase by transfected culture cells. RNA blot analysis showed two species of ferrochelatase mRNA consistent with findings of two polyadenylation sites. Both the mRNAs increased by treatment of the MEL cells with dimethyl sulfoxide. The band pattern of the RNA of the mouse liver was the same as that of the MEL cells. Based on these results, we deduce that ferrochelatase in erythroid and hepatic cells can be only of one type.     

Cell surface antigens on erythroid cells: A comparison of normal and anemic (WW) mice

Cell surface antigens of normal and anemic ($\text{W}\text{W}$) mouse erythroid cells have been examined in cytotoxicity assays with two rat antisera. When tested on fetal liver cells, a rat anti-erythroblast serum recognized antigen(s) present on erythroid cells early in development, while rat anti-adult red blood cell serum recognized antigen(s) present on mature erythroid cells. Each of these sera had different activity on normal (+/+ or $\text{W}\text{+}$) as compared to anemic ($\text{W}\text{W}$) erythroid cells.     

The nucleotide sequence of the HEM1 gene and evidence for a precursor form of the mitochondrial 5-aminolevulinate synthase in Saccharomyces cerevisiae

The biosynthesis of yeast 5-aminolevulinate (ALA) synthase, a mitochondrial protein encoded by the nuclear HEM1 gene, has been studied in vitro in a cell-free translation system and in vivo in whole cells. In vitro translation of mRNA hybrid-selected by the cloned HEM1 gene, or of total RNA followed by immunoprecipitation with anti-(ALA synthase) antibody yielded a single polypeptide of higher molecular mass than the purified ALA synthase. This larger form, also seen in pulse-labeled cells, can be post-translationally processed by isolated mitochondria. These results show that the cytoplasmically made ALA synthase is synthesized with a cleavable extension which was estimated to be about 3.5 kDa by sodium dodecyl sulfate polyacrylamide gel electrophoresis. The complete nucleotide sequence of the HEM1 gene and its flanking regions was determined. The 5' ends of the HEM1 mRNAs map from -76 to -63 nucleotides upstream of the translation initiation codon. The open reading frame of 1644 base pairs encodes a protein of 548 amino acids with a calculated Mr of 59,275. The predicted amino-terminal sequence of the protein is strongly basic (five basic and no acidic amino acids within the first 35 residues), rich in serine and threonine and must represent the transient presequence that targets this protein to the mitochondria. Comparison of deduced amino acid sequences indicates a clear homology between the mature yeast and chick embryo liver ALA synthases.     

Change in message sequences during erythrodifferentiation.

The change in the poly A(+) mRNA population during erythrodifferentiation was analyzed by cDNA-RNA hybridization. Poly A(+) RNA was isolated from spleen erythroblasts. When mice became anemic, the amount of globin mRNA increased to 50% of the total poly A(+) mRNA. cDNA from anemic spleen erythroblasts that did not contain globin mRNA sequences was cross-hybridized with mRNAs from mouse reticulocytes and cultured Friend leukemia (FL) cells. Only half the spleen cDNA hybridized with reticulocyte mRNA, whereas most of it hybridized with mRNA from FL cells. The results suggest that decrease in the complexity of the message population and increase in the concentration of globin mRNA are important in erythrodifferentiation.     

Cloning and expression of mouse fatty acid synthase and other specific mRNAs. Developmental and hormonal regulation in 3T3-L1 cells

Mouse liver mRNA enriched in sequence coding for fatty acid synthase by sucrose density gradient centrifugation was used as template for cDNA synthesis. Double-stranded cDNA sequences were inserted into pBR322 and lambda gt10 and cloned. Clones containing putative cDNA sequences for fatty acid synthase were identified by differential hybridization with [32P] cDNAs synthesized from sucrose gradient-purified liver mRNA from mice fasted or fasted and refed a high carbohydrate diet. Thirteen out of 45 differentially expressed clones were found to contain sequences complementary to fatty acid synthase mRNA. Northern blot analysis revealed that, unlike in avian and rat tissues, a single 8.2-kilobase (kb) mRNA codes for fatty acid synthase in mice. In addition to the fatty acid synthase cDNA clones, cDNA clones to two specific mRNAs of 5.1 and 7.2 kb were selected to study nutritional, hormonal, and developmental regulation at the level of mRNA abundance in mouse liver and in 3T3-L1 cells. The induction of fatty acid synthase in the livers of previously fasted mice fed a high carbohydrate diet was controlled pretranslationally by modulation of the fatty acid synthase mRNA content. The level of the two mRNAs with sizes of 5.1 and 7.2 kb were also elevated dramatically in the liver of mice fasted and refed a high carbohydrate diet. A detectable, but very low level of fatty acid synthase mRNA was found in 3T3-L1 preadipocytes. During the differentiation to adipocytes, both the rate of synthesis and relative mRNA level for fatty acid synthase increased in a parallel fashion to a maximum of 17-fold. The levels of 5.1- and 7.2-kb mRNAs, coding for proteins possibly involved in lipogenesis, increased 45- and 25-fold, respectively, during differentiation of 3T3-L1 adipocytes. Treatment of mature 3T3-L1 adipocytes with insulin elicited a 3-fold increase in both rate of synthesis and mRNA content of fatty acid synthase, while treatment with dibutyryl cAMP caused a 60% decrease in fatty acid synthase mRNA and an 80% decrease in the rate of the enzyme synthesis, indicating pretranslational control of fatty acid synthase expression by the lipogenic and lipolytic hormones. Similarly, insulin caused a 2- to 3-fold increase in both 7.2- and 5.1-kb mRNAs and dibutyryl cAMP decreased the levels of 7.2- and 5.1-kb mRNAs to 10 and 20% of control levels, respectively.     

Sequence of a cDNA for mouse thymidylate synthase reveals striking similarity with the prokaryotic enzyme

We report the nucleotide sequence of a cloned cDNA, pMTS-3, that contains a 1-kb insert corresponding to mouse thymidylate synthase (E.C. 2.1.1.45). The open reading frame of 921 nucleotides from the first AUG to the termination codon specifies a protein with a molecular mass of 34,962 daltons. The predicted amino acid sequence is 90% identical with that of the human enzyme. The mouse sequence also has an extremely high degree of similarity (as much as 55% identity) with prokaryotic thymidylate synthase sequences, indicating that thymidylate synthase is among the most highly conserved proteins studied to date. The similarity is especially pronounced (as much as 80% identity) in the 44-amino-acid region encompassing the binding site for deoxyuridylic acid. The cDNA sequence also suggests that mouse thymidylate synthase mRNA lacks a 3' untranslated region, since the termination codon, UAA, is followed immediately by a poly(A) segment.      

Maturation of embryonic chick liver delta-aminolevulinate synthase: precursor pools and regulation by intra-cellularly produced heme

1. Immunoblot analyses were carried out to determine the relative distributions of delta-aminolevulinate synthase (ALA synthase) in mitochondrial and cytosol fractions prepared from embryos at different times after injections with allylisopropylacetamide (AIA). 2. The results indicated that the molecular mass of mature ALA synthase (Mr 65,000) increased with time in mitochondria. 3. At no time was the precursor form (Mr 75,000) of the enzyme detected either in mitochondria or in the cytosol. 4. In primary cultures of hepatocytes, where the increased production of ALA synthase had been induced with AIA, addition of delta-aminolevulinic acid (ALA) and Fe2(SO4)3 into the culture medium completely blocked the processing of the precursor form of the enzyme. 5. On the other hand, the addition of ALA together with deferoxamine mesylate into the medium had no detectable effect on the maturation of ALA synthase in the hepatocytes. 6. The results indicated: first, that upon induction of porphyria the pools of pre-ALA synthase in liver are relatively low in chick embryos when compared with those in other organisms; and second, that increased heme production by the hepatocytes caused the inhibition of processing of the precursor form of ALA synthase.     

Cytoplasmic 3-hydroxy-3-methylglutaryl coenzyme A synthase from the hamster. I. Isolation and sequencing of a full-length cDNA

We here report the isolation and nucleotide sequencing of a full-length 3.3-kilobase cDNA for the cytoplasmic form of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) synthase, a regulated enzyme in the cholesterol biosynthetic pathway. The cDNA was isolated from UT-1 cells, a compactin-resistant line of Chinese hamster ovary cells. UT-1 cells produce large amounts of mRNA for HMG-CoA synthase and the next enzyme in the pathway, HMG-CoA reductase, as a result of growth in the presence of compactin, a competitive inhibitor of the reductase. The identity of the cDNA for HMG-CoA synthase was confirmed through comparison of the NH2-terminal amino acid sequence predicted from the cDNA with that determined chemically from the purified enzyme. Anti-peptide antibodies directed against the amino acid sequence predicted from the cDNA precipitated HMG-CoA synthase activity from liver cytoplasm. The feeding of cholesterol to hamsters led to a decrease of more than 85% in the amount of mRNA for HMG-CoA synthase and HMG-CoA reductase in hamster liver. These data indicate that the mRNAs for cytoplasmic HMG-CoA synthase and for HMG-CoA reductase, two sequential enzymes in the cholesterol biosynthetic pathway, are coordinately regulated by cholesterol.     

Heme biosynthesis in a chicken hepatoma cell line (LMH): comparison with primary chick embryo liver cells (CELC)

5-Aminolevulinic acid synthase (ALA synthase), the rate-controlling enzyme of hepatic heme biosynthesis, is feed-back repressed by heme. In the liver, chemicals such as barbiturates markedly induce ALA synthase, especially in the presence of partial defects of heme biosynthesis. The inducibility and regulation of ALA synthase have been investigated using a variety of models, including intact animals and liver cell culture systems. A widely used model that closely approximates what occurs in vivo and in humans is that of primary cultures of chick embryo liver cells (CELCs). However, CELCs have some limitations: the cells obtained are somewhat heterogeneous; isolation and culture must be repeated every week resulting in weekly variations; and cells are short-lived limiting the feasibility of time-course and transfection studies. The aim of this study was to determine if LMH cells, a chick hepatoma cell line, are a good model comparable to that of CELCs. In both cells similar patterns of response of, ALA synthase activities and mRNA levels, and of porphyrin accumulation were obtained following treatments known to affect heme biosynthesis. Similarly, heme repressed ALA synthase mRNA levels in both cell types and ALA synthase activities in LMH cells. We conclude that LMH cells are a useful model for the study of hepatic heme biosynthesis and regulation of ALA synthase.     

Structural comparisons between mouse and human prealbumin

In an attempt to construct model systems for familial amyloidotic polyneuropathy, prealbumin cDNA was cloned from a mouse liver cDNA library, using previously cloned human prealbumin cDNA as a hybridization probe. The primary structure of mouse prealbumin deduced from the cDNA sequence shows that it consists of 147 amino acids, including a whole prealbumin sequence (127 amino acids) and a putative signal sequence (20 amino acids). These numbers are in complete agreement with those determined for the human prealbumin. Among the 127 amino acid residues of the mature human prealbumin, 25 are replaced by different amino acids in the mouse prealbumin. Interestingly, 24 out of the 25 substituted amino acids are located at the outer surface of the protein, and the regions corresponding to the core and central channel of the protein are almost completely conserved. The cloned cDNA provided essential information for manipulating amyloidosis in mice.