{PDOC00409}
{PS00469; NDPK}
{PS51374; NDPK_LIKE}
{BEGIN}
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* Nucleoside diphosphate kinase (NDPK) active site signature and NDPK-like domain profile *
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The Nme (Non-metastatic) protein family, previously known as Non-metastatic 23
(Nm23) or  nucleoside  diphosphate  kinase  (NDPK), consists of evolutionarily
conserved proteins present in all three domains of life (bacteria, archaea and
eukaryotes) and  in  some  viruses.  Some  members of the family, but not all,
exhibit a  Nucleoside  Diphosphate  Kinase (NDPK) activity (EC 2.7.4.6). NDPKs
catalyze the  transfer  of the terminal phosphoryl group of a donor nucleoside
triphosphate (NTP) to an acceptor nucleoside diphosphate (NDP) in the presence
of divalent cations, preferably Mg(2+), by a ping-pong mechanism involving the
formation of  a  phosphohistidine  intermediate.  They  have  broad  substrate
specificity, can  use  both  ribo-  and  deoxyribonucleotides  of  purines  or
pyrimidines, and  are  not  known  to  be  allosterically  regulated.  In  all
organisms, NDPKs  are  considered  as  housekeeping enzymes involved in energy
metabolism and  homeostasis  of  intracellular  NTP pools. NDPKs are therefore
major players  in  the  synthesis  of  macromolecules  since  they provide the
neosynthetized triphosphates  used  for  cell  anabolic processes. They supply
NTPs for   nucleic   acid   synthesis,   CTP  for  lipid  synthesis,  UTP  for
polysaccharide synthesis, and GTP for protein elongation, signal transduction,
and microtubule  polymerization.  Beside this basic function, the Nme proteins
have several   other   biochemical   roles.  They  function  as  transcription
regulators, protein kinases and DNases [1,2,3,4,5,6].

Unicellular organisms  possess  one  Nme  ortholog, whilst vertebrates possess
several. In  vertebrates,  the  Nme  family  of  proteins  is  composed  of 10
isoforms, designated  Nme1-10, which are diverse in their enzymatic activities
and patterns  of  subcellular  localization.  They  display  a  large range of
physiological and  pathological  functions  at  the cellular and organ levels,
including bioenergetics,  cytoskeleton  and membrane dynamics, cell signaling,
DNA repair,  metastasis,  maintenance  of  vascular  and cardiac function, and
development in  general.  Many  Nme  proteins  are multifunctional, i.e., they
present more  than one and often unrelated molecular activities. Each contains
a conserved  domain  of  ~150  amino  acids  associated  with a NDPK function,
although not  all are catalytically active. Basically, the 10 Nme isoforms can
be subdivided  into two groups. The quite conserved and ubiquitously expressed
members Nme1-4  (group  I)  form  hexamers, possess the NDPK active site motif
(NXXHG/ASD) and  are catalytically active with similar kinetic parameters. The
more divergent  members  Nme5-10  (group  II)  probably  lack  both  hexameric
structure and NDPK activity. Some contain NDPK domain duplications and further
domains with  mostly  unknown  function.  Only Nme6 is ubiquitously expressed,
most others   were   reported   in  association  with  ciliary  and  flagellar
structures. Several  of  the  Nme  isoforms  (Nme1, Nme5, Nme7, and Nme8) also
exhibit a 3'-5' exonuclease activity, suggesting roles in DNA proofreading and
repair. Nme1   and   Nme2   have   been   identified  as  potential  canonical
transcription factors  that  regulate  gene  transcription  through their DNA-
binding activities [7,8,9,10].

The sequence  of  the  NDPK-like  domain  has  been  highly  conserved through
evolution. There  is  a  single  histidine  residue  involved in the catalytic
mechanism, conserved  in  all  known active NDPK enzymes. The NDPK-like domain
folds into a compact alpha/beta domain built around an antiparallel beta sheet
with topology  beta4beta1beta3beta2  (see  <PDB:1NUE>).  The  active  site  is
located in a cleft formed by two helices. Active NDPK-like domain possess nine
residues that are most essential for catalysis and stability of a prototypical
NDPK [10,11,12].

Our signature pattern contains the histidine residue involved in the catalytic
mechanism. We also developed a profile that covers the whole NDPK-like domain.

-Consensus pattern: N-x(2)-H-[GA]-S-D-[GSA]-[LIVMPKNE]
                    [H is the active site residue]
-Sequences known to belong to this class detected by the pattern: ALL.
-Other sequence(s) detected in Swiss-Prot: 2.

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

-Last update: December 2023 / Text revised; profile added.

[ 1] Cetkovic H., Perina D., Harcet M., Mikoc A., Herak Bosnar M.
     "Nme family of proteins--clues from simple animals."
     Naunyn. Schmiedebergs. Arch. Pharmacol. 388:133-142(2015).
     PubMed=25042404; DOI=10.1007/s00210-014-1017-x
[ 2] Georgescauld F., Song Y., Dautant A.
     "Structure, Folding and Stability of Nucleoside Diphosphate Kinases."
     Int. J. Mol. Sci. 21:0-0(2020).
     PubMed=32947863; DOI=10.3390/ijms21186779
[ 3] Desvignes T., Pontarotti P., Fauvel C., Bobe J.
     "Nme protein family evolutionary history, a vertebrate perspective."
     BMC Evol. Biol. 9:256-256(2009).
     PubMed=19852809; DOI=10.1186/1471-2148-9-256
[ 4] Dorion S., Rivoal J.
     "Clues to the functions of plant NDPK isoforms."
     Naunyn. Schmiedebergs. Arch. Pharmacol. 388:119-132(2015).
     PubMed=24964975; DOI=10.1007/s00210-014-1009-x
[ 5] Boissan M., Dabernat S., Peuchant E., Schlattner U., Lascu I.,
     Lacombe M.-L.
     "The mammalian Nm23/NDPK family: from metastasis control to cilia
     movement."
     Mol. Cell. Biochem. 329:51-62(2009).
     PubMed=19387795; DOI=10.1007/s11010-009-0120-7
[ 6] Perina D., Bosnar M.H., Mikoc A., Mueller W.E.G., Cetkovic H.
     "Characterization of Nme6-like gene/protein from marine sponge
     Suberites  domuncula."
     Naunyn. Schmiedebergs. Arch. Pharmacol. 384:451-460(2011).
     PubMed=21533994; DOI=10.1007/s00210-011-0635-9
[ 7] Bilitou A., Watson J., Gartner A., Ohnuma S.
     "The NM23 family in development."
     Mol. Cell. Biochem. 329:17-33(2009).
     PubMed=19421718; DOI=10.1007/s11010-009-0121-6
[ 8] Puts G.S., Leonard M.K., Pamidimukkala N.V., Snyder D.E.,
     Kaetzel D.M.
     "Nuclear functions of NME proteins."
     Lab. Invest. 98:211-218(2018).
     PubMed=29058704; DOI=10.1038/labinvest.2017.109
[ 9] Schlattner U.
     "The Complex Functions of the NME Family-A Matter of Location and
     Molecular  Activity."
     Int. J. Mol. Sci. 22:0-0(2021).
     PubMed=34884887; DOI=10.3390/ijms222313083
[10] Lacombe M.-L., Milon L., Munier A., Mehus J.G., Lambeth D.O.
     "The human Nm23/nucleoside diphosphate kinases."
     J. Bioenerg. Biomembr. 32:247-258(2000).
     PubMed=11768308; DOI=10.1023/a:1005584929050
[11] Perina D., Korolija M., Mikoc A., Halasz M., Herak Bosnar M.,
     Cetkovic H.
     "Characterization of Nme5-Like Gene/Protein from the Red Alga Chondrus
     Crispus."
     Mar. Drugs. 18:0-0(2019).
     PubMed=31877804; DOI=10.3390/md18010013
[12] Morera S., Lacombe M.-L., Xu Y., LeBras G., Janin J.
     "X-ray structure of human nucleoside diphosphate kinase B complexed
     with GDP at 2 A resolution."
     Structure 3:1307-1314(1995).
     PubMed=8747457

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