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Polymorphisms in the α-amy1 gene of wild and cultivated barley revealed by the polymerase chain reaction

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Abstract

α-Amylases are the key enzymes involved in the hydrolysis of starch in plants. The polymerase chain reaction (PCR) was used to detect polymorphisms in the length of amplified sequences between the annealing sites of two primers derived from published α-amy1 gene sequences in barley. These two primers (Bsw1 and Bsw7), flanking the promoter region and the first exon, amplified two PCR fragments in barley. One of the amplified products, with the expected length of 820 bp, appeared together with another shorter PCR band of around 750 bp. This 750-bp fragment seems to be derived from an α-amylase gene not reported previously. Both of the PCR products could be amplified from the two-rowed barley varieties tested, including cv Himalaya from which the sequence information was obtained. Five of the six-rowed barley varieties also have the two PCR fragments whereas another two have only the long fragment. These two fragments seem to be unique to barley, neither of them could be amplified from other cereals; for example, wheat, rye or sorghum. These two α-amylase fragments were mapped to the long arm of 6H, the location of the α-amy1 genes, using wheat-barley addition lines. Amplification of genomic DNA from wild barley accessions with primers Bsw1 and Bsw7 indicated that both of the fragments could be present, or the long and short fragments could be present alone. The results also demonstrated that the genes specifying these two fragments could be independent from each other in barley. The conserved banding pattern of these two fragments in the two-rowed barley varieties implies that artificial selection from these genes may have played an important role in the evolution of cultivated barley from wild barley.

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References

  • Ahokas H, Naskali L (1990) Variation of α-amylase, β-amylase, β-glucanase, pullulanase, proteinase and chintinase activities in germinated samples of the wild progennitor of barley. J Inst Brew 96:27–31

    Google Scholar 

  • Baulcombe DC, Huttly AK, Martienssen RA, Barker RF, Jarvis MG (1987) A novel wheat α-amylase gene (α-Amy3). Mol Gen Genet 209:33–40

    Google Scholar 

  • Brown AHD (1992) Genetic variation and resources in cultivated barley and wild Hordeum. 6th International barley genetic symposium. Barley genetics 6: Vol II (in press)

  • Brown AHD, Jacobson J (1982) Genetic basis and natural variation of α-amylase isozymes in barley. Genet Res 40:315–324

    Google Scholar 

  • Chandler PM, Zwar JA, Jacobsen JV, Higgins TJV, Inglis AS (1984) The effects of gibberellic acid and abscisic acid on α-amylase mRNA levels in barley aleurone layers studies using an α-amylase cDNA clone. Plant Mol Biol 3:407–418

    Google Scholar 

  • D'Ovidio R, Tanzarella OA, Porceddu E (1990) Rapid and efficient detection of genetic polymorphism in wheat through amplification by polymerase chain reaction. Plant Mol Biol 15:169–171

    Google Scholar 

  • Fincher GB (1989) Molecular and cellular biology associated with endosperm mobilization in germinating cereal grains. Annu Rev Plant Phsiol Plant Mol Biol 40: 305–346

    Google Scholar 

  • Henry R (1989) Rapid separation of α-amylases from barley by ionexchange high-performance liquid chromatography on non-porous columns. J Chrom 481:397–402

    Google Scholar 

  • Holwerda BC, Jana S, Crosby WL, Rogers JC (1993) Large differences in genetic variation of multigene families in barley. J Hered 84:29–33

    Google Scholar 

  • Huttly AK, Martienssen RA, Baulcombe DC (1988) Sequence heterogeneity and differential expression of the α-Amy2 gene family in wheat. Mol Gen Genet 214:232–240

    Google Scholar 

  • Islam AKMS, Shepherd KW, Sparrow DHB (1981) Isolation and characterization of euplasmic wheat-barley chromosome addition lines. Heredity 46:161–174

    Google Scholar 

  • Jacobsen JV, Close TJ (1991) Control of transient expression of chimaeric genes by gibberellic acid and abscisic acid in protoplasts prepared from mature barley aleurone layers. Plant Mol Biol 16:713–724

    Google Scholar 

  • Khursheed B, Rogers JC (1988) Barley α-amylase genes: quantitative comparison of steady-state m-RNA levels from individual members of the two different families expressed in aleurone cells. J Biol Chem 263:18953–18960

    Google Scholar 

  • Knox CAP, Sonthayanon B, Chandra GR, Muthukrishnan S (1987) Structure and organization of two divergent α-amylase genes from barley. Plant Mol Biol 9:3–17

    Google Scholar 

  • Lazarus CM, Baucombe DC, Martienssen RA (1985) α-amylase genes of wheat are two multigene families which are differentially expressed. Plant Mol Biol 5:13–24

    Google Scholar 

  • Macgregor AW, Morgan JE (1992) Determination of specific activities of malt α-amylases. J Cereal Sci 16:267–277

    Google Scholar 

  • Martienssen RA (1986) The molecular genetics of α-amylase families in wheat (Triticum aestivum). PhD thesis, Cambridge University, UK

    Google Scholar 

  • Martin JM, Blake TK, Hockett EA (1991) Diversity among North American spring barley cutivars based on coefficients of parentage. Crop Sci 31:1131–1137

    Google Scholar 

  • Mullis KB, Faloona F (1987) Specific synthesis of DNA in vitro via a polymerase-catalysed chain reaction. Methods Enzymol 155:335–350

    Google Scholar 

  • Muthukrishnan S, Gill BS, Swegle M, Chandra GR (1984) Structural genes for α-amylase are located on barley chromosomes 1 and 6. J Biol Chem 259:13637–13639

    Google Scholar 

  • Nevo E (1992) Origin, evolution, population genetics and resources for breeding of wild barley, Hordeum spontaneum, in the fertile crescent. In: Shewry P (ed) Barley: genetics, biochemistry, molecular biology and biotechnology. Wallingford, UK: CAB Int; pp 19–43

    Google Scholar 

  • Rogers JC (1985) Two barley α-amylase gene families are regulated differently in aleurone cells. J Biol Chem 260: 3731–3738

    Google Scholar 

  • Sogaard M, Olsen FL, Svensson B (1991) C-terminal processing of barley α-amylase 1 in malt, aleurone protoplasts, and yeast. Proc Natl Acad Sci USA 88:8140–8144

    Google Scholar 

  • Weining S, Langridge P (1991) Identification and mapping polymorphism in cereals based on polymerase chain reaction. Theor Appl Genetics 82:209–216

    Google Scholar 

  • Weining S, Henry RJ, Brown AHD (1993) Molecular analysis of Hordeum spontaneum. In: Imrie BC, Hacker JB (eds) Focused plant breeding: towards responsible and sustainable agriculture. Tenth Australian plant breeding conference, pp 26–29

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  1. Queensland Agricultural Biotechnology Centre, Gehrmann Laboratories, University of Queensland, 4072, Qld, Australia

    S. Weining, L. Ko & R. J. Henry

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  1. S. Weining
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  2. L. Ko
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  3. R. J. Henry
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Communicated by G. Wenzel

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Weining, S., Ko, L. & Henry, R.J. Polymorphisms in the α-amy1 gene of wild and cultivated barley revealed by the polymerase chain reaction. Theoret. Appl. Genetics 89, 509–513 (1994). https://doi.org/10.1007/BF00225388

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  • DOI: https://doi.org/10.1007/BF00225388

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