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Journal of Molecular Evolution
Volumn 65, Issue 5, 2007, Pages 616-625
Evolution of the cytoplasmic and mitochondrial phosphagen kinases unique to annelid groups
Author keywords

Annelid; Creatine kinase; Cytoplasmic; Exon intron organization; Guanidino kinase; Isoform; Mitochondrial; Phosphagen kinase
Indexed keywords

CREATINE KINASE; ENZYME; LOMBRICINE KINASE; PHOSPHAGEN KINASE; TAUROCYAMINE KINASE; UNCLASSIFIED DRUG;
EID: 36148992989     PISSN: 00222844     EISSN: None     Source Type: Journal    
DOI: 10.1007/s00239-007-9046-4     Document Type: Article
Times cited : (27)
References (23)
  • 2
    • 0024355968 scopus 로고
    • Phosphocreatine represents a thermodynamic and functional improvement over other muscle phosphagens
    • Ellington WR (1989) Phosphocreatine represents a thermodynamic and functional improvement over other muscle phosphagens. J Exp Biol 143:177-194
    • (1989) J Exp Biol , vol.143 , pp. 177-194
    • Ellington, W.R.1
  • 3
    • 0035052706 scopus 로고    scopus 로고
    • Evolution and physiological roles of phosphagen systems
    • Ellington WR (2001) Evolution and physiological roles of phosphagen systems. Ann Rev Physiol 63:289-325
    • (2001) Ann Rev Physiol , vol.63 , pp. 289-325
    • Ellington, W.R.1
  • 6
    • 3142600890 scopus 로고    scopus 로고
    • Alternative splicing produces transcripts coding for alpha and beta chains of a hetero-dimeric phosphagen kinase
    • Ellington WR, Yamashita D, Suzuki T (2004) Alternative splicing produces transcripts coding for alpha and beta chains of a hetero-dimeric phosphagen kinase. Gene 334:167-174
    • (2004) Gene , vol.334 , pp. 167-174
    • Ellington, W.R.1    Yamashita, D.2    Suzuki, T.3
  • 7
    • 0026047505 scopus 로고
    • Regulatory element analysis and structural characterization of the human sarcomeric mitochondrial creatine kinase gene
    • Klein SC, Haas RC, Perryman MB, Billadello JJ, Strauss AW (1991) Regulatory element analysis and structural characterization of the human sarcomeric mitochondrial creatine kinase gene. J Biol Chem 266:18058-18065
    • (1991) J Biol Chem , vol.266 , pp. 18058-18065
    • Klein, S.C.1    Haas, R.C.2    Perryman, M.B.3    Billadello, J.J.4    Strauss, A.W.5
  • 9
    • 0035819901 scopus 로고    scopus 로고
    • Organization of the gene for an invertebrate mitochondrial creatine kinase: Comparisons with genes of higher forms and correlation of exon boundaries with functional domains
    • Pineda AO Jr, Ellington WR (2001) Organization of the gene for an invertebrate mitochondrial creatine kinase: comparisons with genes of higher forms and correlation of exon boundaries with functional domains. Gene 265:115-121
    • (2001) Gene , vol.265 , pp. 115-121
    • Pineda Jr., A.O.1    Ellington, W.R.2
  • 10
    • 0031656509 scopus 로고    scopus 로고
    • Molecular characterization of the creatine kinases and some historical perspectives
    • Qin W, Khuchua Z, Cheng J, Boero J, Payne RM, Strauss AW (1998) Molecular characterization of the creatine kinases and some historical perspectives. Mol Cell Biochem 184:153-167
    • (1998) Mol Cell Biochem , vol.184 , pp. 153-167
    • Qin, W.1    Khuchua, Z.2    Cheng, J.3    Boero, J.4    Payne, R.M.5    Strauss, A.W.6
  • 12
    • 1942439849 scopus 로고    scopus 로고
    • Cloning and expression of mitochondrial and protoflagellar creatine kinases from a marine sponge: Implications for the origin of intracellular energy transport systems
    • Sona S, Suzuki T, Ellington RW (2004) Cloning and expression of mitochondrial and protoflagellar creatine kinases from a marine sponge: Implications for the origin of intracellular energy transport systems. Biochim Biophys Res Commun 317:1207-1214
    • (2004) Biochim Biophys Res Commun , vol.317 , pp. 1207-1214
    • Sona, S.1    Suzuki, T.2    Ellington, R.W.3
  • 13
    • 0033564680 scopus 로고    scopus 로고
    • Arginine kinase evolved twice: Evidence that echinoderm arginine kinase originated from creatine kinase
    • Suzuki T, Kamidochi M, Inoue N, Kawamichi H, Yazawa Y, Furukohri T, Ellington RW (1999) Arginine kinase evolved twice: Evidence that echinoderm arginine kinase originated from creatine kinase. Biochem J 340:671-675
    • (1999) Biochem J , vol.340 , pp. 671-675
    • Suzuki, T.1    Kamidochi, M.2    Inoue, N.3    Kawamichi, H.4    Yazawa, Y.5    Furukohri, T.6    Ellington, R.W.7
  • 14
    • 0034331815 scopus 로고    scopus 로고
    • Stichopus japonicus arginine kinase: Gene structure and unique substrate recognition system
    • Suzuki T, Yamamoto Y, Umekawa M (2000) Stichopus japonicus arginine kinase: gene structure and unique substrate recognition system. Biochem J 351:579-585
    • (2000) Biochem J , vol.351 , pp. 579-585
    • Suzuki, T.1    Yamamoto, Y.2    Umekawa, M.3
  • 16
    • 0023738192 scopus 로고
    • Developmental regulation and tissue-specific expression of the human muscle creatine kinase gene
    • Trask RV, Strauss AW, Billadello JJ (1988) Developmental regulation and tissue-specific expression of the human muscle creatine kinase gene. J Biol Chem 263:17142-17149
    • (1988) J Biol Chem , vol.263 , pp. 17142-17149
    • Trask, R.V.1    Strauss, A.W.2    Billadello, J.J.3
  • 17
    • 34250872782 scopus 로고    scopus 로고
    • A novel arginine kinase with substrate specificity toward D-arginine
    • Uda K, Suzuki T (2007) A novel arginine kinase with substrate specificity toward D-arginine. Protein J 26:281-291
    • (2007) Protein J , vol.26 , pp. 281-291
    • Uda, K.1    Suzuki, T.2
  • 18
    • 28844484124 scopus 로고    scopus 로고
    • Hypotaurocyamine kinase evolved from a gene for arginine kinase
    • Uda K, Iwai A, Suzuki T (2005a) Hypotaurocyamine kinase evolved from a gene for arginine kinase. FEBS Lett 579:6756-6762
    • (2005) FEBS Lett , vol.579 , pp. 6756-6762
    • Uda, K.1    Iwai, A.2    Suzuki, T.3
  • 19
    • 22544466687 scopus 로고    scopus 로고
    • Origin and properties of cytoplasmic and mitochondrial isoforms of taurocyamine kinase
    • Uda K, Saishoji N, Ichinari S, Ellington WR, Suzuki T (2005b) Origin and properties of cytoplasmic and mitochondrial isoforms of taurocyamine kinase. FEBS J 272:3521-3530
    • (2005) FEBS J , vol.272 , pp. 3521-3530
    • Uda, K.1    Saishoji, N.2    Ichinari, S.3    Ellington, W.R.4    Suzuki, T.5
  • 20
    • 27544488701 scopus 로고    scopus 로고
    • Phosphagen kinase of the giant tubeworm Riftia pachyptila. Cloning and expression of cytoplasmic and mitochondrial isoforms of taurocyamine kinase
    • Uda K, Tanaka K, Bailly X, Zal F, Suzuki T (2005c) Phosphagen kinase of the giant tubeworm Riftia pachyptila. Cloning and expression of cytoplasmic and mitochondrial isoforms of taurocyamine kinase. Int J Biol Macromol 37:54-60
    • (2005) Int J Biol Macromol , vol.37 , pp. 54-60
    • Uda, K.1    Tanaka, K.2    Bailly, X.3    Zal, F.4    Suzuki, T.5
  • 22
    • 0026698727 scopus 로고
    • Mitochondrial creatine kinase: A key enzyme of aerobic energy metabolism
    • Wyss M, Smeitink J, Wevers RA, Wallimann T (1992) Mitochondrial creatine kinase: a key enzyme of aerobic energy metabolism. Biochim Biophys Acta 1102:119-166
    • (1992) Biochim Biophys Acta , vol.1102 , pp. 119-166
    • Wyss, M.1    Smeitink, J.2    Wevers, R.A.3    Wallimann, T.4
  • 23
    • 0026585611 scopus 로고
    • Intracellular compartmentation, structure and function of creatine kinase isoenzymes in tissues with high and fluctuating energy demands: The 'phosphocreatine circuit' for cellular energy homeostasis
    • Wallimann T, Wyss M, Brdiczka D, Nicolay K, Eppenberger HM (1992) Intracellular compartmentation, structure and function of creatine kinase isoenzymes in tissues with high and fluctuating energy demands: the 'phosphocreatine circuit' for cellular energy homeostasis. Biochem J 281:21-40
    • (1992) Biochem J , vol.281 , pp. 21-40
    • Wallimann, T.1    Wyss, M.2    Brdiczka, D.3    Nicolay, K.4    Eppenberger, H.M.5

* 이 정보는 Elsevier사의 SCOPUS DB에서 KISTI가 분석하여 추출한 것입니다.