• Title/Summary/Keyword: Fur homologue

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Agouti Gene의 Human Homologue의 Molecular Structure와 Chromosomal Mapping

  • Heajoon Y. Kwon;Scott J. Bultman;Christiane Loffler;Chen, Wen-Ji;Paul J. Furdon;John G. Powell;Usala, Anton-Lewis;William Wilkison;Ingo Hansman
    • Proceedings of the Korean Society of Applied Pharmacology
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    • 1996.11a
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    • pp.55-64
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    • 1996
  • mouse chromesome2에 있는 agouti locus는 정상적으로는 털색깔을 조절하는 gene이다. mouse agouti gene은 최근에 cloning 되었고 131 amino acid peptide와 consensus signal peptide를 encode한다고 보고되었다. 이 논문에서 interspecies-DNA hybridization approach를 이용하여 mouse agouti gene의 human homologue를 cloning 하였다. Sequence analysis 결과, 이는 mouse gene에 85% 유사하였고 consensus signal peptide sequence 를 포함하는 132 amino acid를 coding하였다. somatic-cell hybrid mapping pannel과 Fluorescence-in-situ hybridization에 의한 chromosomal mapping을 한 결과, agouti gene은 MODY (maturity onset diabetes of the young), myeloid leukemia locus 등이 위치한 human chromosome 20q 11.2에 mapping 되었다. 성인 tissue로부터 추출한 RNA를 이용한 발현연구에 의하면 human agouti gene은 adipose tissue와 teatis에 발현되었다.

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Isolation of the Regulator Gene Responsible for Overproduction of Catalase A in $H_2O$$_2$-resistant Mutant of Streptomyces coelicolor

  • Hahn, Ji-Sook;Oh, So-Young;Keith F. Chater;Roe, Jung-Hye
    • Journal of Microbiology
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    • v.38 no.1
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    • pp.18-23
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    • 2000
  • Streptomyces coelicolor produces three kinds of catalases to cope with oxidative stress and to allow normal differentiation. Catalase A is the major vegetative catalase which functions in removing hydrogen peroxide generated during the process of aerobic metabolism. To understand the regulatory mechanism of response against oxidative stress, hydrogen peroxide-resistant mutant (HR4O) was isolated from S. coelicolor J1501 following UV mutagenesis. The mutant overproduced catalase A more than 50-fo1d compared with the wild type. The mutation locus catRI was mapped closed to the mthB2 locus by genetic crossings. An ordered cosmid library of S. coelicolor encompassing the mthB2 locus was used to isolate the regulator gene (catR) which represses catalase overproduction when introduced into HR4O. A candidate catR gene was found to encode a Fur-like protein of 138 amino acids (15319 Da).

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Structure function relationships amongst the purple acid phosphatase family of binuclear metal-containing enzymes

  • Hamilton, Susan
    • Proceedings of the Korean Society for Bioinformatics Conference
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    • 2003.10a
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    • pp.5-5
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    • 2003
  • The purple acid phosphatases comprise a family of binuclear metal-containing enzymes. The metal centre contains one ferric ion and one divalent metal ion. Spectroscopic studies of the monomeric, ${\sim}$36 kDa mammalian purple acid phosphatases reveal the presence of an Fe(III)Fe(II) centre in which the metals are weakly antiferromagnetically coupled, whereas the dimeric, ${\sim}$110 000 kDa plant enzymes contain either Fe(III)Zn(II) or Fe(III)Mn(II). The three dimensional structures of the red kidney bean and pig enzymes show very similar arrangements of the metal ligands but some significant differences beyond the immediate vicinity of the metals. In addition to the catalytic domain, the plant enzyme contains a second domain of unknown function. A search of sequence databases was undertaken using a sequence pattern which includes the conserved metal-binding residues in the plant and animal enzymes. The search revealed the presence in plants of a 'mammalian-type' low molecular weight purple acid phosphatase, a high molecular weight form in some fungi, and a homologue in some bacteria. The catalytic mechanism of the enzyme has been investigated with a view to understanding the marked difference in specificity between the Fe-Mn sweet potato enzyme, which exhibits highly efficient catalysis towards both activated and unactivated phosphate esters, and other PAPs, which hydrolyse only activated esters. Comparison of the active site structures of the enzymes reveal some interesting differences between them which may account for the difference. The implications fur understanding the physiological functions of the enzymes will be discussed.

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