Increase of functional diversity by alternative splicing

被引：187

作者：

Kriventseva, EV

Koch, I

Apweiler, R

Vingron, M

Bork, P

Gelfand, MS

Sunyaev, S

机构：

[1] EBI, EMBL, Cambridge CB10 1SD, England

[2] Max Planck Inst Mol Genet, D-14195 Berlin, Germany

[3] Max Delbruck Ctr Mol Med, D-13122 Berlin, Germany

[4] State Sci Ctr GosNllGenet, Moscow 113545, Russia

[5] European Mol Biol Lab, D-69117 Heidelberg, Germany

来源：

TRENDS IN GENETICS | 2003年 / 19卷 / 03期

关键词：

D O I：

10.1016/S0168-9525(03)00023-4

中图分类号：

Q3 [遗传学];

学科分类号：

071007 ; 090102 ;

摘要：

A large-scale analysis of protein isoforms arising from alternative splicing shows that alternative splicing tends to insert or delete complete protein domains more frequently than expected by chance, whereas disruption of domains and other structural modules is less frequent. If domain regions are disrupted, the functional effect, as predicted from 3D structure, is frequently equivalent to removal of the entire domain. Also, short alternative splicing events within domains, which might preserve folded structure, target functional residues more frequently than expected. Thus, it seems that positive selection has had a major role in the evolution of alternative splicing.

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收藏

页码：124 / 128

页数：5

相关论文

共 24 条

[1] The InterPro database, an integrated documentation resource for protein families, domains and functional sites [J].

Apweiler, R ;

Attwood, TK ;

Bairoch, A ;

Bateman, A ;

Birney, E ;

Biswas, M ;

Bucher, P ;

Cerutti, T ;

Corpet, F ;

Croning, MDR ;

Durbin, R ;

Falquet, L ;

Fleischmann, W ;

Gouzy, J ;

Hermjakob, H ;

Hulo, N ;

Jonassen, I ;

Kahn, D ;

Kanapin, A ;

Karavidopoulou, Y ;

Lopez, R ;

Marx, B ;

Mulder, NJ ;

Oinn, TM ;

Pagni, M ;

Servant, F ;

Sigrist, CJA ;

Zdobnov, EM .

NUCLEIC ACIDS RESEARCH, 2001, 29 (01) :37-40

[2] The SWISS-PROT protein sequence database and its supplement TrEMBL in 2000 [J].

Bairoch, A ;

Apweiler, R .

NUCLEIC ACIDS RESEARCH, 2000, 28 (01) :45-48

[3]

Bateman A, 2004, NUCLEIC ACIDS RES, V32, pD138, DOI [10.1093/nar/gkp985, 10.1093/nar/gkh121, 10.1093/nar/gkr1065]

[4] BCL-X, A BCL-2-RELATED GENE THAT FUNCTIONS AS A DOMINANT REGULATOR OF APOPTOTIC CELL-DEATH [J].

BOISE, LH ;

GONZALEZGARCIA, M ;

POSTEMA, CE ;

DING, LY ;

LINDSTEN, T ;

TURKA, LA ;

MAO, XH ;

NUNEZ, G ;

THOMPSON, CB .

CELL, 1993, 74 (04) :597-608

[5] Alternative splicing and genome complexity [J].

Brett, D ;

Pospisil, H ;

Valcárcel, J ;

Reich, J ;

Bork, P .

NATURE GENETICS, 2002, 30 (01) :29-30

[6] EST comparison indicates 38% of human mRNAs contain possible alternative splice forms [J].

Brett, D ;

Hanke, J ;

Lehmann, G ;

Haase, S ;

Delbrück, S ;

Krueger, S ;

Reich, J ;

Bork, P .

FEBS LETTERS, 2000, 474 (01) :83-86

[7] Alternative splicing:: multiple control mechanisms and involvement in human disease [J].

Cáceres, JF ;

Kornblihtt, AR .

TRENDS IN GENETICS, 2002, 18 (04) :186-193

[8] ISIS, the intron information system, reveals the high frequency of alternative splicing in the human genome [J].

Croft, L ;

Schandorff, S ;

Clark, F ;

Burrage, K ;

Arctander, P ;

Mattick, JS .

NATURE GENETICS, 2000, 24 (04) :340-341

[9] The PROSITE database, its status in 2002 [J].

Falquet, L ;

Pagni, M ;

Bucher, P ;

Hulo, N ;

Sigrist, CJA ;

Hofmann, K ;

Bairoch, A .

NUCLEIC ACIDS RESEARCH, 2002, 30 (01) :235-238

[10] Alternative splicing: increasing diversity in the proteomic world [J].

Graveley, BR .

TRENDS IN GENETICS, 2001, 17 (02) :100-107