Partial structure of the human H-protein gene

In a span of approximately 13 kb, two genomic fragments showing an obvious overlap encoded the 1,192 base pair (bp) cDNA sequence for human H-protein. Because of the close similarity in the genomic organization comprised of five exons to that for the chicken H-protein gene, this region was assigned to the true H-protein gene in human. Primer extension analysis suggested and S1 protection analysis confirmed that at least one additional exon for the 74 bases-long 5' untranslated region in H-protein mRNA exists as the presumable first exon. None of the 5.0- and 5.5-kb SacI and the 5.2-kb EcoRI fragments which were undetectable in the genomes of patients with nonketotic hyperglycinemia was included in the true H-protein gene.     

One of the two genomic copies of the glycine decarboxylase cDNA has been deleted at a 5' region in a patient with nonketotic hyperglycinemia

One of eight patients with nonketotic hyperglycinemia resulted by the lesion in glycine decarboxylase showed the deletion of 0.6-kb SacI and 1.5-kb PstI fragments identified by the cDNA for this protein. A genomic clone, lambda HGDG10, encodes a 5' region of this cDNA in an organized structure and can produce these two fragments. The other clone, lambda HGDG8, carries a processed gene. Southern analysis using a limited segment of this cDNA demonstrated that the 1.7-kb and 1.5-kb PstI fragments predicted from its recognition sites in both genomic clones occur actually in the human genome, indicating that at least two copies of glycine decarboxylase cDNA exist in the haploid genome, and the patient has the glycine decarboxylase gene deleted at a 5' region.     

Crystal structure of T-protein of the glycine cleavage system. Cofactor binding, insights into H-protein recognition, and molecular basis for understanding nonketotic hyperglycinemia

The glycine cleavage system catalyzes the oxidative decarboxylation of glycine in bacteria and in mitochondria of animals and plants. Its deficiency in human causes nonketotic hyperglycinemia, an inborn error of glycine metabolism. T-protein, one of the four components of the glycine cleavage system,is a tetrahydrofolate dependent aminomethyltransferase. It catalyzes the transfer of the methylene carbon unit to tetrahydrofolate from the methylamine group covalently attached to the lipoamide arm of H-protein. To gain insight into the T-protein function at the molecular level, we have determined the first crystal structure of T-protein from Thermotoga maritima by the multiwavelength anomalous diffraction method of x-ray crystallography and refined four structures: the apoform; the tetrahydrofolate complex; the folinic acid complex; and the lipoic acid complex. The overall fold of T-protein is similar to that of the C-terminal tetrahydrofolate-binding region (residues 421-830) of Arthrobacter globiformis dimethylglycine oxidase. Tetrahydrofolate (or folinic acid) is bound near the center of the tripartite T-protein. Lipoic acid is bound adjacent to the tetrahydrofolate binding pocket, thus defining the interaction surface for H-protein binding. A homology model of the human T-protein provides the structural framework for understanding the molecular mechanisms underlying the development of nonketotic hyperglycinemia due to missense mutations of the human T-protein.     

Restriction map of the 125-kilobase plasmid of Bacillus thuringiensis subsp. israelensis carrying the genes that encode delta-endotoxins active against mosquito larvae.

A large plasmid containing all delta-endotoxin genes was isolated from Bacillus thuringiensis subsp. israelensis; restricted by BamHI, EcoRI, HindIII, KpnI, PstI, SacI, and SalI; and cloned as appropriate libraries in Escherichia coli. The libraries were screened for inserts containing recognition sites for BamHI, SacI, and SalI. Each was labeled with 32P and hybridized to Southern blots of gels with fragments generated by cleaving the plasmid with several restriction endonucleases, to align at least two fragments of the relevant enzymes. All nine BamHI fragments and all eight SacI fragments were mapped in two overlapping linkage groups (with total sizes of about 76 and 56 kb, respectively). The homology observed between some fragments is apparently a consequence of the presence of transposons and repeated insertion sequences. Four delta-endotoxin genes (cryIVB-D and cytA) and two genes for regulatory polypeptides (of 19 and 20 kDa) were localized on a 21-kb stretch of the plasmid; without cytA, they are placed on a single BamHI fragment. This convergence enables subcloning of delta-endotoxin genes (excluding cryIVA, localized on the other linkage group) as an intact natural fragment.     

The impaired expression of glycine decarboxylase in patients with hyperglycinemias

Glycine decarboxylase, a constituent of the glycine cleavage system, in patients with either nonketotic or ketotic hyperglycinemia (NKH and KH) was examined using an anti-chicken glycine decarboxylase antibody. Patients with NKH who have lesion in glycine decarboxylase are differentiated by its expressed level in the liver. One group is cases of the neonatal onset type who have neither activity of the enzyme nor protein reactive to the antibody. The other is a case of the late onset type who shows low but detectable activity of the enzyme and the desirable amount of the immunoreactive material. In the liver of a patient with KH not showing the appreciable activity of H-protein, ubiquitous amount of protein reactive to anti-H-protein IgG is detected and amount of glycine decarboxylase has also been lowered. It is suggested that several mechanisms may be involved in determining the expressed level of glycine decarboxylase in patients with hyperglycinemias.     

Crystal Structure of Aminomethyltransferase in Complex with Dihydrolipoyl-H-Protein of the Glycine Cleavage System: IMPLICATIONS FOR RECOGNITION OF LIPOYL PROTEIN SUBSTRATE,DISEASE-RELATED MUTATIONS,AND REACTION MECHANISM*

Aminomethyltransferase, a component of the glycine cleavage system termed T-protein, reversibly catalyzes the degradation of the aminomethyl moiety of glycine attached to the lipoate cofactor of H-protein, resulting in the production of ammonia, 5,10-methylenetetrahydrofolate, and dihydrolipoate-bearing H-protein in the presence of tetrahydrofolate. Several mutations in the human T-protein gene are known to cause nonketotic hyperglycinemia. Here, we report the crystal structure of Escherichia coli T-protein in complex with dihydrolipoate-bearing H-protein and 5-methyltetrahydrofolate, a complex mimicking the ternary complex in the reverse reaction. The structure of the complex shows a highly interacting intermolecular interface limited to a small area and the protein-bound dihydrolipoyllysine arm inserted into the active site cavity of the T-protein. Invariant Arg²⁹² of the T-protein is essential for complex assembly. The structure also provides novel insights in understanding the disease-causing mutations, in addition to the disease-related impairment in the cofactor-enzyme interactions reported previously. Furthermore, structural and mutational analyses suggest that the reversible transfer of the methylene group between the lipoate and tetrahydrofolate should proceed through the electron relay-assisted iminium intermediate formation.     

Restriction endonuclease mapping of the proviral DNA of the exogenous RIII murine mammary tumor virus

Cellular DNA containing integrated murine mammary tumor virus (MuMTV) was isolated from FeI/C6 feline kidney cells and CCL64 mink lung cells infected with milkborne RIII MuMTV. By using restriction enzyme HpaI, intact RIII MuMTV provirus (length, 8.7 kilobases [kb]) was excised from the cellular DNA. Subsequent restriction endonuclease analysis of this HpaI fragment with KpnI, HindIII, EcoRI, BamHI, BglII, PstI, SstI, SalI, and XhoI enabled us to construct a map of the RIII virus genome. A comparison of this map with the maps of the GR and C3H MuMTV's revealed that there are greater sequence differences between the RIII virus and the GR and C3H MuMTV proviruses than there are between the GR and C3H proviruses. The following are features of the restriction map unique to the RIII provirus: the presence of three BamHI and two EcoRI cleavage sites, a HpaI cleavage site in the terminal 3'-5' repeat unit of the provirus, and the absence of an XhoI cleavage site. Another distinguishing feature of the RIII provirus is that the sizes of some of the restriction fragments produced by cleavage of the RIII provirus with PstI are different from the sizes of the fragments obtained by PstI cleavage of the GR and C3H proviruses. Like the GR proviral DNA, the RIII proviral DNA has three SstI (SacI) cleavage sites, whereas the C3H provirus has only two SstI sites. HpaI digestion of MuMTV-infected mink lung cell DNA revealed only one class of provirus (an 8.7-kb fragment); however, we observed several minor classes of RIII proviral DNA in addition to the major class of provirus DNA in infected cat kidney cells. PstI digestion of the HpaI 8.7-kb fragments from both feline and mink cells generated a 3.7-kb DNA fragment identical in size to a PstI-generated fragment that has been found in GR and C3H milkborne virus-infected cells. Although a fragment similar in size to the milkborne 3.7-kb PstI fragment has been found as an endogenous component in many C3H and GR mouse tissues, we did not observe such an endogenous fragment in the RIII mouse strain. Therefore, the 3.7-kb fragment may be useful as a marker for the milkborne RIII MuMTV provirus in RIII mice.     

Structures of human genes coding for cytokine LD78 and their expression.

LD78 is a member of a newly identified superfamily of small inducible proteins involved in inflammatory responses, wound healing, and tumorigenesis. Southern blot analysis of the EcoRI-digested human genomic DNAs, using previously isolated LD78 cDNA as a probe, showed that in each individual there are 4.2- and 4.8-kilobase-pair (kb) fragments and that some have an additional 6.5-kb fragment. The 4.2-kb fragment contained genomic DNA sequences corresponding to the LD78 cDNA and was named the LD78 alpha gene. The 4.8-kb fragment contained similar sequences, showing 94% homology to the LD78 alpha gene, and was named the LD78 beta gene. The LD78 alpha gene was present in a single or a few copies per haploid genome, whereas the copy number of the LD78 beta gene and of the 6.5-kb fragment hybridizable to LD78 cDNA varied among the samples tested. Treatment of human myeloid cell lines HL-60 and U937 with phorbol 12-myristate 13-acetate (PMA) increased within 2 h cellular levels of the RNA hybridizable to LD78 cDNA. The human glioma cell line U105MG and primary culture of human fibroblasts also expressed the hybridizable RNA in response to PMA. Addition of cycloheximide had no apparent effect on this response in U937 cells and inhibited the response in fibroblasts, whereas it stimulated the response in HL-60 and U105MG cells. mRNA phenotyping experiments revealed that the LD78 alpha and LD78 beta genes were both transcribed in PMA-stimulated U937 cells.     

Structural and expression analyses of normal and mutant mRNA encoding glycine decarboxylase: three-base deletion in mRNA causes nonketotic hyperglycinemia

Full-length cDNA clone encoding human glycine decarboxylase (P-protein) was isolated from the human placental lambda gt11 expression library using specific antibodies. This clone was 3,705 bp in length and encoded 1,020 amino acids. We studied the structure of the mutant P-protein mRNA expressed in the liver of a patient with nonketotic hyperglycinemia (NKH) deficient of P-protein. A three-base deletion, which resulted in deletion of Phe756, was found. Cos7 cells in which normal P-protein cDNA was expressed presented an activity of 6.9 +/- 0.41 nmole/milligram of protein/hour, which was almost equivalent to that of human liver. In contrast, Cos7 cells in which the mutant cDNA was expressed showed no activity, indicating that the three-base deletion could cause NKH.     

Isolation of novel non-HLA gene fragments from the hemochromatosis region (6p21.3) by cDNA hybridization selection.

It has previously been shown that cDNA hybridization selection can identify and recover novel genes from large cloned genomic DNA such as cosmids or YACs. In an effort to identify candidate genes for hemochromatosis, this technique was applied to a 320-kb YAC containing the HLA-A gene. A short fragment cDNA library derived from human duodenum was selected with the YAC DNA. Ten novel gene fragments were isolated, characterized, and localized on the physical map of the YAC.     

Cloning of cDNA encoding human H-protein, a constituent of the glycine cleavage system

A cDNA that encodes human H-protein, a constituent protein of the glycine cleavage system, was cloned with anti-rat H-protein antibody as a probe from a human liver cDNA library constructed with an expression vector, lambda gt11. The longest size of cDNA of the isolated clones was about 750 base long (lambda HH15B9). On the other hand, we determined the primary structure of human H-protein from the amino terminal Ser by the 12th Val, including a hexapeptide, -Glu-Lys-His-Glu-Trp-Val-. In addition to the finding that most cDNA inserts cloned hybridized with the synthetic DNA probe composed of the possible sequences for the hexapeptide, we confirmed that lambda HH15B9 encodes the partial primary structure of H-protein in an open reading frame.     

The mitochondrial glycine cleavage system

Summary The glycine cleavage enzyme system is composed of four different proteins tentatively called P-protein, H-protein, T-protein and L-protein, and catalyzes the following reaction reversibly: Glycine + tetrahydrofolate + NAD⁺ 5, 10-methylene-tetrahydrofolate + NH₃ + CO₂ + NADH + H^– Glycine decarboxylase, tentatively called P-protein, is able by itself to catalyze glycine decarboxylation, yielding methylamine as product, but at an extremely low rate. P-Protein alone is also able to catalyze slightly the exchange of carboxyl carbon of glycine with CO₂. However, the rates of the P-protein-catalyzed reactions are greatly increased by the co-existence of aminomethyl carrier protein, a lipoic acid-containing enzyme tentatively called H-protein. Several lines of evidence suggest that H-protein brings about a conformational change of P-protein which may be relevant to the expression of the decarboxylase activity of P-protein and that the functional glycine decarboxylase may be an enzyme complex composed of both P-protein and H-protein. H-Protein seems to play a dual role in the glycine decarboxylation; the one as a regulatory protein of P-protein, and the other as an electron-pulling agent and concomitantly as a carrier of the aminomethyl moiety derived from glycine. The idea that H-protein functions as a modulator of P-protein was further supported by the study of a patient with nonketotic hyperglycinemia. The primary lesion in this patient appeared to consist in structural abnormality in H-protein; the H-protein purified from the liver of this patient was apparently devoid of functional lipoic acid. Nevertheless, H-protein from the patient could stimulate the P-protein-catalyzed exchange of the carboxyl carbon of glycine and CO₂, although only to a limited extent. The observed activity should be independent of the functioning of lipoic acid and would be a reflection of a conformational change in P-protein brought about by H-protein.P-Protein was inactivated when it was incubated with glycine in the presence of II-protein, and the inactivation was completely prevented when bicarbonate was further added so as to allow the glycine-CO₂ exchange to proceed. The inactivation was accompanied by a spectral change of P-protein. The inactivation of P-protein seemed to take place as a side reaction of the glycine decarboxylation and to reflect the formation of a ternary complex of P-protein, H-protein and aminomethyl moiety of glycine through a Schiff base linkage of the H-protein-bound aminomethyl moiety with the pyridoxal phosphate of P-protein.     

Assignment of casein kinase 2 alpha sequences to two different human chromosomes

Summary Human casein kinase 2 alpha gene (CK-2-alpha) sequences have been localized within the human genome by in situ hybridization and somatic cell hybrid analysis using a CK-2 alpha cDNA as a probe. By in situ hybridization, the CK-2 alpha cDNA could be assigned to two different loci, one on 11p15.1-ter and one on 20p13. The existence of two separate chromosomal loci suggests that CK-2 alpha is a member of a gene family. Only the locus on chromosome 11 was confirmed by somatic cell hybrid analysis. The analysis was based on the presence of a CK-2-alpha-specific 20-kb fragment. However, the CK-2 alpha cDNA hybridizes to several additional fragments in total human DNA.     

Two coding regions closely linked to the rat apolipoprotein E gene: nucleotide sequences of rat apolipoprotein C-I and ECL cDNA.

Restriction fragments isolated from a 17-kb rat genomic DNA clone containing the gene for apolipoprotein (apo) E were radiolabeled and used to screen a rat liver cDNA library. A cDNA clone hybridizing to a 6-kb genomic DNA fragment was isolated and the nucleotide sequence of the cDNA insert determined. The sequence was homologous to the sequence for human apo C-I and was used to derive the corresponding amino acid sequence. Unlike human apo C-I, mature rat apo C-I contains histidine, lacks valine, and has alanine at the C terminus and aspartate as the N terminus. Screening the rat liver cDNA library with a radiolabeled 1.9-kb restriction fragment from the genomic DNA clone containing the rat apo E gene identified another cDNA clone (ECL cDNA). Nucleotide sequencing yielded a derived 75-amino-acid sequence for the ECL protein with a hydrophobicity profile similar to that of rat apo C-I. Northern analysis demonstrated a 0.50-kb band for ECL mRNA. The tissue-specific expression of the gene is similar to that of rat apo C-I. This study indicates that the rat apo C-I and ECL genes are closely linked, about 4.5 and 12 kb downstream of the apo E gene, respectively.     

Genome size of Eperythrozoon suis and hybridization with 16S rRNA gene

The genome size of Eperythrozoon suis, an unculturable haemotropic mycoplasma, was estimated using pulsed-field gel electrophoresis (PFGE). Gamma irradiation was used to introduce one (on the average) double-strand break in the E. suis Illinois chromosome. Restriction enzymes that cut infrequently were also used to analyze genome size. The size estimate for the full-length genome was 745 kilobases (kb), whereas the size estimates based on the summation of restriction fragments ranged from 730 to 770 kb. The 16S rRNA gene was located on the 120-kb MluI fragment, 128-kb NruI fragment, 25-kb SacII fragment, and 217-kb SalI fragment by Southern blotting.     

The primary structure of human H-protein of the glycine cleavage system deduced by cDNA cloning

A full-length cDNA encoding the human H-protein of the glycine cleavage system has been isolated from a lambda gt11 human fetal liver cDNA library. The cDNA insert was 1091 base pairs with an open reading frame of 519 base pairs which encoded a 125-amino acid mature human H-protein with a 48-amino acid presequence. Human H-protein is 97%, 86%, and 46% identical to the bovine, chicken, and pea H-protein, respectively.     

Structure of P-protein of the glycine cleavage system: implications for nonketotic hyperglycinemia

The crystal structure of the P-protein of the glycine cleavage system from Thermus thermophilus HB8 has been determined. This is the first reported crystal structure of a P-protein, and it reveals that P-proteins do not involve the alpha(2)-type active dimer universally observed in the evolutionarily related pyridoxal 5'-phosphate (PLP)-dependent enzymes. Instead, novel alphabeta-type dimers associate to form an alpha(2)beta(2) tetramer, where the alpha- and beta-subunits are structurally similar and appear to have arisen by gene duplication and subsequent divergence with a loss of one active site. The binding of PLP to the apoenzyme induces large open-closed conformational changes, with residues moving up to 13.5 A. The structure of the complex formed by the holoenzyme bound to an inhibitor, (aminooxy)acetate, suggests residues that may be responsible for substrate recognition. The molecular surface around the lipoamide-binding channel shows conservation of positively charged residues, which are possibly involved in complex formation with the H-protein. These results provide insights into the molecular basis of nonketotic hyperglycinemia.     

Isolation of human DNAs homologous to the BamHI-Z fragment of herpes simplex virus type 1 DNA

Human DNA hybridizes with the BamHI-Z fragment (map coordinates 0.936 to 0.949) of Herpes simplex virus type 1 (HSV-1) DNA. To characterize the BamHI-Z homologue of human DNA, we isolated six independent hybrid phages with a sequence homologous to the BamHI-Z fragment from a human genomic DNA library. Three of the six had a common 1.2-kb BamHI-EcoRI fragment homologous to the BamHI-Z, and this fragment existed as 10-60 copies per human haploid genome. A 0.29-kb MboII segment of the BamHI-Z fragment was found to be responsible for the homology with the 1.2-kb BamHI-EcoRI fragment.