The monoamine oxidases play a vital role in the metabolism of biogenic amines in the central nervous system and in peripheral tissues. Using oligonucleotide probes derived from three sequenced peptide fragments, we have isolated cDNA clones that encode the A and B forms of monoamine oxidase and have determined the nucleotide sequences of these cDNAs. Comparison of the deduced amino acid sequences shows that the A and B forms have subunit molecular weights of 59,700 and 58,800, respectively, and have 70% sequence identity. Both sequences contain the pentapeptide Ser-Gly-Gly-Cys-Tyr, in which the obligatory cofactor FAD is covalently bound to cysteine. Based on differences in primary amino acid sequences and RNA gel blot analysis of mRNAs, the A and B forms of monoamine oxidase appear to be derived from separate genes.Monoamine oxidases A and B [MAO A and MAO B, respectively; amine:oxygen oxidoreductase (deaminating) (flavin-containing), EC 1.4.3.4] in the central nervous system and in peripheral tissues catalyze the oxidative deamination of neuroactive and vasoactive amines (1) and the oxidation of xenobiotics, including the parkinsonism-producing neurotoxin 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (2, 3). These enzymes, which are integral proteins of the outer mitochondrial membrane (4), are distinguished by differences in substrate preference (5), inhibitor specificity (6), tissue and cell distribution (7), and immunological properties (8,9). MAO A preferentially oxidizes the biogenic amine serotonin and is inactivated irreversibly by the acetylenic inhibitor clorgyline. MAO B preferentially oxidizes phenylethylamine and benzylamine and is inactivated by the irreversible inhibitors pargyline and deprenyl. The level of MAO activity in almost all human tissues consists of a mixture of both forms of the enzyme, but placental tissue contains predominantly MAO A (10), whereas platelets and lymphocytes express only MAO B (11,12). MAO A and B from several tissue sources and species appear to consist of two subunits with approximate molecular masses of 60 kDa (13,14 (15,19). Peptide maps obtained from proteinase digestion of [3H]pargyline-labeled crude or partially purified MAO A and B suggest that these enzymes differ in their amino acid sequences (17,20). Furthermore, differences in degrees of photo-dependent inactivation of these two enzymes suggest the existence of conformational or structural differences in their active sites (21-23).To clarify the molecular basis of structural and functional differences between these important enzymes, we have isolated and characterized cloned cDNAsI encoding these proteins. The nucleotide and deduced amino acid sequences for human liver MAO A and B show that these two proteins are derived from separate genes. MATERIALS AND METHODSConstruction and Screening of the Human Liver cDNA Library. A Agt1O library was constructed from poly(A)+ mRNA isolated from human liver (24). The phage library contained 2 x 106 individual clones of which 5 x 105 clones were subjected to hy...
Monoamine oxidases A and B [MAOA and MAOB; amine:oxygen oxidoreductase (deaminating) (flavincontaning), EC 1.4.3.4] play important roles in the metabolism of neuroactive, vasoactive amines and the Parkinsonismproducing neurotoxin 1-methyl4-4phenyl-1,2,3,6-tetrahydropyridine (MPTP). Human MAOA and MAOB genes isolated from X chromosome-specific libraries span at least 60 kilobases, consist of 15 exons, and exhibit identical exon-intron organization. Exon 12 codes for the covalent FAD-binding-site and is the most conserved exon; the MAOA and MAOB exon 12 products share 93.9% peptide identity. These results suggest that MAOA and MAOB are derived from duplication of a common ancestral gene and provide insight on the structural/functional relationship of the enzyme products.
Only 10 different V beta gene segments were found when the sequences of 15 variable (V beta) genes of the mouse T-cell receptor were examined. From this analysis we calculate that the total number of expressed V beta gene segments may be 21 or fewer, which makes the expressed germline V beta repertoire much smaller than that of immunoglobulin heavy-chain or light-chain genes. We suggest that beta-chain somatic diversification is concentrated at the V beta-D beta-J beta junctions.
The T-cell receptor is a cell surface heterodimer consisting of an alpha and a beta chain that binds foreign antigen in the context of a cell surface molecule encoded by the major histocompatibility complex (MHC), thus restricting the T-cell response to the surface of antigen presenting cells. The variable (V) domain of the receptor binds antigen and MHC molecules and is composed of distinct regions encoded by separate gene elements--variable (V alpha and V beta), diversity (D beta) and joining (J alpha and J beta)--rearranged and joined during T-cell differentiation to generate contiguous V alpha and V beta genes. T-helper cells, which facilitate T and B cell responses, bind antigen in the context of a class II MHC molecule. The helper T-cell response to cytochrome c in mice is a well-defined model for studying the T-cell response to restricted antigen and MHC determinants. Only mice expressing certain class II molecules can respond to this antigen (Ek alpha Ek beta, Ek alpha Eb beta, Ev alpha Ev beta and Ek alpha Es beta). Most T cells appear to recognize the C-terminal peptide of cytochrome c (residues 81-104 in pigeon cytochrome c). We have raised helper T cells to pigeon cytochrome c or its C-terminal peptide analogues in four different MHC congenic strains of mice encoding each of the four responding class II molecules. We have isolated and sequenced seven V alpha genes and six V beta genes and analysed seven additional helper T cells by Northern blot to compare the structure of the V alpha and V beta gene segments with their antigen and MHC specificities. We have added five examples taken from the literature. These data show that a single V alpha gene segment is responsible for a large part of the response of mice to cytochrome c but there is no simple correlation of MHC restriction with gene segment use.
Monoamine oxidase (MAO) A and B play important roles in the metabolism of biogenic amines. Northern analysis using 32P-labeled subfragments of human liver MAO A and B cDNA clones detected a 5- and a 3-kb transcript, respectively, in most human tissues examined. However, fetal heart and thymus express minute amounts of MAO A transcript, whereas fetal brain, muscle, thymus, spleen, meninges, and placenta express minute amounts of MAO B transcript. Small intestine and placenta express, in addition to the MAO A 5-kb transcript, a 2-kb transcript, which may arise from an alternative polyadenylation site. MAO A and B transcripts are expressed in similar regions of adult human brain. The highest concentrations of these transcripts were located in frontal cortex and locus coeruleus. This study demonstrates the tissue-specific distribution of the MAO genes and will provide insight into the physiological functions of MAO A and B.
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