A single mouse alpha-amylase gene specifies two different tissue-specific mRNAs

The alpha-amylase mRNAs which accumulate in two different tissues of the mouse, the salivary gland and the liver, are identical except for their 5' non-translated sequences: the 5' terminal 158 nucleotides of the major liver alpha-amylase mRNA are unrelated to the 5' terminal 47 nucleotides found in its salivary gland counterpart. DNA that specifies the 5'terminal one-quarter of these mRNAs has been isolated through genomic cloning and sequenced. The initial 161 nucleotides of the liver alpha-amylase mRNA are specified by DNA sequences that lie 4.5 kb upstream from those for the common body of the two mRNAs. In contrast, the 5' terminal 50 nucleotides of the salivary gland alpha-amylase mRNA are found 7.5 kb from sequences that the two mRNAs share in the genome. These cloned DNA sequences occur once per haploid genome, indicating that both the salivary gland and liver alpha-amylase mRNAs are transcribed from the same gene (Amy1A). Since no rearrangement of these DNA sequences can be detected among mouse sperm, salivary gland or liver preparations, gross rearrangement does not account for the tissue-specific pattern of expression observed for Amy1A. Rather, these data indicate that the salivary gland and liver alpha-amylase mRNAs are differentially transcribed and/or processed from identical DNA sequences in different tissues.     

Biochemical genetics of α-amylase isozymes of the chicken pancreas

In the chicken population at large, three electrophoretically distinct pancreatic alpha-amylase isozymes were discovered. The isozymes were designated Pa 1, Pa 2, and Pa 3. The local population of chickens, however, possessed only isozymes Pa 2 and Pa 3 present as three phenotypes: Amy-2 B, consisting of isozyme Pa2; Amy2 BC, consisting of isozymes Pa 2 plus Pa 3; and Amy2 C, consisting of isozyme Pa 3. Pancreatic biopsy permitted the establishment of a breeding flock with defined amylase phenotypes. Matings of this flock established that amylases are inherited as codominant alleles at a single genetic locus. Further, there was no evidence of ontogenetic modification of the amylase isozymes. It was observed that amylase isozymes Pa 2 and Pa 3 each generated a family of at least three faster-migrating amylolytic proteins. These post-translationally modified amylases were designated Pa Xa, Pa Xb, and Pa Xc, where X represents the number of the progenitor amylase. Structural analyses of purified amylases demonstrated that all amylase isozymes are nonglycosidated, monomeric molecules of molecular weight 55,000. In addition, the data are consistent with the hypothesis that the faster-migrating amylases are produced by deamidation of asparagine and/or glutamine residues.     

Two Distinct Pancreatic Amylase Genes Are Active in Ybr Mice

The genetic determinants of pancreatic amylase expression in YBR mice differ in two respects from those of other inbred strains. First, there are two nonallelic amylase isozymes present in YBR pancreas, while most mouse strains express a single pancreatic amylase protein. In addition, the in vivo rate of total pancreatic amylase synthesis is 50% of that in other strains. Both these traits are determined by genetic sites in the region of the Amy-2 locus on mouse chromosome 3. To determine the molecular basis for the presence of two isozymes in this strain, we have compared portions of their amino acid sequences. Two differences between isozymes A₁ and B₁ were identified among the 77 residues compared. This result demonstrates that two distinct amylase genes are expressed in YBR pancreas.     

Genetics of hydroxyacid oxidase isozymes in the mouse: localisation of Hao-2 on linkage group XVI.

Electrophoretic variants of individual isozymes of L-alpha-hydroxyacid oxidase (HAOX-B4) and amylase (AMY-A) in an Asian subspecies of mouse, Mus musculus castaneus, have been used to localise the gene encoding the HAOX B subunit. The structural gene loci for these isozymes (Hao-2 and Amy-1) are apparently linked (4.9 +/- 2.4 per cent recombinants) in this organism, which places Hao-2 on linkage group XVI, since previous studies by Eicher and co-workers (1976) have localised Amy-1 on this chromosome.     

Primer extension studies on α-amylase mRNAs in barley aleurone. I. Characterization and quantification of the transcripts

Primer extension was used to characterize alpha-amylase mRNAs from aleurone tissue of barley (Hordeum vulgare L. cv. Himalaya) grains. Two synthetic oligonucleotides, specific for the low-pI and high-pI alpha-amylase groups, were used as primers for synthesis of cDNA from total RNA preparations. Between them, these two oligonucleotides appear to account for all major alpha-amylase mRNAs as judged by hybrid-arrested translation of alpha-amylase mRNAs in a cell-free system. Reconstruction experiments indicated that the levels of extended primers (determined by scintillation counting) were directly proportional to the level of input mRNA over a wide range. This indicates that the technique is suitable for quantification of relative levels of individual alpha-amylase from approximately 2% to 100% of maximal levels. The nucleotide sequences of extended primers defined two different alpha-amylase mRNAs in each of the low-pI and high-pI groups, and possibly a third mRNA in the high-pI group.     

Genetic variants found in plasma alpha-amylase and erythrocyte carbonic anhydrase in the musk shrew (Suncus murinus)

Genetic variants of plasma alpha-amylase and erythrocyte carbonic anhydrase in the musk shrew (Suncus murinus) were found by electrophoreses using cellulose acetate plates. It was demonstrated that phenotypic differences of alpha-amylase are controlled by two codominant alleles (Amy-1a and Amy-1b) at a single autosomal locus (Amy-1). The segregation data of the carbonic anhydrase phenotypes in the progeny supported the genetic theory of two codominant alleles (Car-1a and Car-1b) at a single autosomal locus (Car-1). The data suggested that there was no close linkage between the two loci, Amy-1 and Car-1. The Car-1 locus was fixed with one of the two alleles in each of the four lines, i.e. Nag, Oki , Tar and Jak originating from wild animals captured in Nagasaki and Naha and Tarama Island, Okinawa, Japan, and in Jakarta, Indonesia, respectively. Oki and Tar lines still showed segregation of the two alleles at the Amy-1 locus.     

Simultaneous expression of salivary and pancreatic amylase genes in cultured mouse hepatoma cells.

The tissue-specific expression of two types of mouse amylase genes does not overlap in vivo; the Amy-1 locus is transcribed in the parotid gland and the liver, while expression of Amy-2 is limited to the pancreas. We identified a mouse hepatoma cell line, Hepa 1-6, in which both amylase genes can be simultaneously expressed. Amy-1 is constitutively active in these cells and is inducible by dexamethasone at the level of mRNA. We demonstrated that the liver-specific promoter of Amy-1 is utilized by the dexamethasone-treated hepatoma cells, and that glucocorticoid consensus sequences are present upstream of this promoter. Amy-2 is not detectable constitutively, but can be activated if the cells are cultured in serum-free medium containing dexamethasone. Expression of Amy-2 in a nonpancreatic cell type has not previously been observed. We speculate that induction of Amy-1 and activation of Amy-2 may involve different regulatory mechanisms. Hepa 1-6 cells provide an experimental system for molecular analysis of these events.     

Location of β-amylase sequences in wheat and its relatives

Summary A -amylase cDNA clone isolated from barley has been used to locate -amylase encoding sequences on wheat, rye, and Aegilops umbellulata chromosomes by hybridisation to restriction endonuclease digested DNA obtained from wheat aneuploid and wheat-alien addition lines. Structural genes were identified on homoeologous group 4 and 5 chromosomes, confirming the results of isozyme studies. In addition, a further set of structural genes was found on homoeologous group 2 chromosomes. It is proposed that there are two homoeoallelic series, -Amy-1 on group 4 or 5 chromosomes, and -Amy-2 on group 2 chromosomes. Evidence is presented that each locus contains one or two -amylase structural genes, and it is suggested that the large number of isozymes seen upon IEF are due to post-translational modifications.     

Molecular Cloning of α-Amylase Genes from DROSOPHILA MELANOGASTER. I. Clone Isolation by Use of a Mouse Probe

A cloned alpha-amylase cDNA sequence from the mouse is homologous to a small set of DNA sequences from Drosophila melanogaster under appropriate conditions of hybridization. A number of recombinant lambda phage that carry homologous Drosophila genomic DNA sequences were isolated using the mouse clone as a hybridization probe. Putative amylase clones hybridized in situ to one or the other of two distinct sites in polytene chromosome 2R and were assigned to one of two classes, A and B. Clone lambda Dm32, representing class A, hybridizes within chromosome section 53CD. Clone lambda Dm65 of class B hybridizes within section 54A1-B1. Clone lambda Dm65 is homologous to a 1450- to 1500-nucleotide RNA species, which is sufficiently long to code for alpha-amylase. No RNA homologous to lambda Dm32 was detected. We suggest that the class B clone, lambda Dm65, contains the functional Amy structural gene(s) and that class A clones contain an amylase pseudogene.