{PDOC00018}
{PS00018; EF_HAND_1}
{PS50222; EF_HAND_2}
{BEGIN}
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* EF-hand calcium-binding domain signature and profile *
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Many calcium-binding proteins belong to the same evolutionary family and share
a  type  of calcium-binding domain known as the EF-hand [1 to 5]. This type of
domain  consists  of  a  twelve  residue loop flanked on both side by a twelve
residue  alpha-helical domain (see <PDB:1CLL>). In an EF-hand loop the calcium
ion is coordinated in a pentagonal bipyramidal configuration. The six residues
involved  in the binding are in positions 1, 3, 5, 7, 9 and 12; these residues
are denoted by X, Y, Z, -Y, -X and -Z. The invariant Glu or Asp at position 12
provides   two   oxygens  for  liganding  Ca  (bidentate  ligand).  The  basic
structural/functional  unit  of  EF-hand proteins is usually a pair of EF-hand
motifs  that  together  form a stable four-helix bundle domain. The pairing of
EF-hand enables cooperativity in the binding of Ca2+ ions.

We list below the proteins  which  are  known to contain EF-hand  regions. For
each type of protein we have indicated between parenthesis the total number of
EF-hand regions known or supposed to exist.   This  number  does  not  include
regions which  clearly  have  lost  their  calcium-binding  properties, or the
atypical low-affinity site (which spans thirteen residues) found in the S-100/
ICaBP family of proteins [6].

 - Aequorin and Renilla luciferin binding protein (LBP) (Ca=3).
 - Alpha actinin (Ca=2).
 - Calbindin (Ca=4).
 - Calcineurin B subunit (protein phosphatase 2B regulatory subunit) (Ca=4).
 - Calcium-binding protein from Streptomyces erythraeus (Ca=3?).
 - Calcium-binding protein from Schistosoma mansoni (Ca=2?).
 - Calcium-binding  proteins  TCBP-23 and TCBP-25 from Tetrahymena thermophila
   (Ca=4?).
 - Calcium-dependent protein kinases (CDPK) from plants (Ca=4).
 - Calcium vector protein from amphoxius (Ca=2).
 - Calcyphosin (thyroid protein p24) (Ca=4?).
 - Calmodulin (Ca=4, except in yeast where Ca=3).
 - Calpain small and large chains (Ca=2).
 - Calretinin (Ca=6).
 - Calcyclin (prolactin receptor associated protein) (Ca=2).
 - Caltractin (centrin) (Ca=2 or 4).
 - Cell Division Control protein 31 (gene CDC31) from yeast (Ca=2?).
 - Diacylglycerol kinase (EC 2.7.1.107) (DGK) (Ca=2).
 - FAD-dependent   glycerol-3-phosphate   dehydrogenase   (EC  1.1.99.5)  from
   mammals (Ca=1).
 - Fimbrin (plastin) (Ca=2).
 - Flagellar calcium-binding protein (1f8) from Trypanosoma cruzi (Ca=1 or 2).
 - Guanylate cyclase activating protein (GCAP) (Ca=3).
 - Inositol phospholipid-specific phospholipase C isozymes gamma-1 and delta-1
   (Ca=2) [10].
 - Intestinal calcium-binding protein (ICaBPs) (Ca=2).
 - MIF related proteins 8 (MRP-8 or CFAG) and 14 (MRP-14) (Ca=2).
 - Myosin regulatory light chains (Ca=1).
 - Oncomodulin (Ca=2).
 - Osteonectin  (basement  membrane  protein  BM-40) (SPARC) and proteins that
   contains an  'osteonectin'  domain  (QR1, matrix glycoprotein SC1) (see the
   entry <PDOC00535>) (Ca=1).
 - Parvalbumins alpha and beta (Ca=2).
 - Placental  calcium-binding  protein  (18a2)  (nerve  growth  factor induced
   protein 42a) (p9k) (Ca=2).
 - Recoverins (visinin, hippocalcin, neurocalcin, S-modulin) (Ca=2 to 3).
 - Reticulocalbin (Ca=4).
 - S-100 protein, alpha and beta chains (Ca=2).
 - Sarcoplasmic calcium-binding protein (SCPs) (Ca=2 to 3).
 - Sea urchin proteins Spec 1 (Ca=4), Spec 2 (Ca=4?), Lps-1 (Ca=8).
 - Serine/threonine  specific  protein  phosphatase  rdgc  (EC 3.1.3.16)  from
   Drosophila (Ca=2).
 - Sorcin V19 from hamster (Ca=2).
 - Spectrin alpha chain (Ca=2).
 - Squidulin (optic lobe calcium-binding protein) from squid (Ca=4).
 - Troponins C; from  skeletal muscle (Ca=4), from cardiac muscle (Ca=3), from
   arthropods and molluscs (Ca=2).

There has been a number of attempts [7,8] to develop patterns that pick-up EF-
hand  regions,  but  these  studies were made a few years ago when not so many
different  families  of  calcium-binding  proteins  were  known.  We therefore
developed a new pattern which takes into account all published sequences. This
pattern  includes the complete EF-hand loop as well as the first residue which
follows  the loop and which seem to always be hydrophobic. We also developed a
profile that covers the loop and the two alpha helices.

-Consensus pattern: D-{W}-[DNS]-{ILVFYW}-[DENSTG]-[DNQGHRK]-{GP}-[LIVMC]-
                    [DENQSTAGC]-x(2)-[DE]-[LIVMFYW]
-Sequences known to belong to this class detected by the profile: ALL.
 for a few sequences.
-Other sequence(s) detected in Swiss-Prot: NONE.
 probably not calcium-binding  and  a few proteins for which we have reason to
 believe that  they bind  calcium:  a number  of endoglucanases and a xylanase
 from the  cellulosome complex of Clostridium [9].

-Sequences known to belong to this class detected by the profile: ALL.
-Other sequence(s) detected in Swiss-Prot: NONE.

-Note: Positions 1 (X), 3 (Y) and 12 (-Z) are the most conserved.
-Note: The 6th residue in an EF-hand loop is, in most  cases a  Gly,  but  the
 number of exceptions to this 'rule' has gradually increased and we felt  that
 the pattern should include all the  different  residues which have been shown
 to exist in this position in functional Ca-binding sites.
-Note: The pattern will, in some cases,  miss  one  of  the EF-hand regions in
 some proteins with multiple EF-hand domains.

-Expert(s) to contact by email:
           Cox J.A.; cox@sc2a.unige.ch
           Kretsinger R.H.; rhk5i@virginia.edu

-Last update: April 2006 / Pattern revised.

[ 1] Kawasaki H., Kretsinger R.H.
     "Calcium-binding proteins 1: EF-hands."
     Protein Prof. 2:305-490(1995).
     PubMed=7553064
[ 2] Kretsinger R.H.
     "Calcium coordination and the calmodulin fold: divergent versus
     convergent evolution."
     Cold Spring Harb. Symp. Quant. Biol. 52:499-510(1987).
     PubMed=3454274
[ 3] Moncrief N.D., Kretsinger R.H., Goodman M.
     "Evolution of EF-hand calcium-modulated proteins. I. Relationships
     based on amino acid sequences."
     J. Mol. Evol. 30:522-562(1990).
     PubMed=2115931
[ 4] Nakayama S., Moncrief N.D., Kretsinger R.H.
     "Evolution of EF-hand calcium-modulated proteins. II. Domains of
     several subfamilies have diverse evolutionary histories."
     J. Mol. Evol. 34:416-448(1992).
     PubMed=1602495
[ 5] Heizmann C.W., Hunziker W.
     "Intracellular calcium-binding proteins: more sites than insights."
     Trends Biochem. Sci. 16:98-103(1991).
     PubMed=2058003
[ 6] Kligman D., Hilt D.C.
     "The S100 protein family."
     Trends Biochem. Sci. 13:437-443(1988).
     PubMed=3075365
[ 7] Strynadka N.C.J., James M.N.
     "Crystal structures of the helix-loop-helix calcium-binding
     proteins."
     Annu. Rev. Biochem. 58:951-998(1989).
     PubMed=2673026; DOI=10.1146/annurev.bi.58.070189.004511
[ 8] Haiech J., Sallantin J.
     "Computer search of calcium binding sites in a gene data bank: use of
     learning techniques to build an expert system."
     Biochimie 67:555-560(1985).
     PubMed=3839696
[ 9] Chauvaux S., Beguin P., Aubert J.-P., Bhat K.M., Gow L.A., Wood T.M.,
     Bairoch A.
     "Calcium-binding affinity and calcium-enhanced activity of Clostridium
     thermocellum endoglucanase D."
     Biochem. J. 265:261-265(1990).
     PubMed=2302168
[10] Bairoch A., Cox J.A.
     "EF-hand motifs in inositol phospholipid-specific phospholipase C."
     FEBS Lett. 269:454-456(1990).
     PubMed=2401372

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