{PDOC52011}
{PS52011; PEPTIDASE_M2}
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* Peptidase family M2 domain profile *
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Members of  the  M2  family  of  peptidases,  related to mammalian angiotensin
converting enzyme  (EC  3.4.15.1, ACE, peptidyl-dipeptidase A), play important
roles in  regulating  a  number of physiological processes. ACE is a membrane-
bound, zinc  dependent  dipeptidase  that  catalyzes  the  conversion  of  the
decapeptide angiotensin I to the potent vasopressor octapeptide angiotensin II
by removing the two C-terminal amino acids. Bradykinin, a vasodilator, and the
hemoregulatory peptide  N-acetyl-Ser-Asp-Lys-Pro  (AcSDKP) are also substrates
for mammalian  ACE.  Two  separate  isoforms  have been characterized: somatic
(sACE) and  testicular (germinal) ACE (tACE) are encoded by a single gene from
two alternate   promoters.   The   sACE   polypeptide   forms  two  homologous
catalytically active extracellular domains, the N- and C-domains, each bearing
an HExxH  zinc-binding  motif in the active site whereas the tACE isoform only
forms a single domain that is essentially identical with the C-domain of sACE.
The ACE   homolog,   ACE2   (EC   3.4.17.–),  differs  from  ACE  in  being  a
carboxypeptidase that  preferentially  removes carboxy-terminal hydrophobic or
basic amino  acids;  it  appears to be important in cardiac function. Both ACE
and ACE2  have  catalytic activity that is chloride sensitive and is caused by
the presence of the CL1 and CL2 chloride-binding sites in ACE and the CL1 site
in ACE2.  The  chloride regulation of activity is also substrate dependent. It
has been  proposed  that  chloride  binding  induces  subtle  changes  in  the
conformation of  the  active site, which either facilitate or hinder substrate
binding. ACE  homologs (also known as members of the M2 gluzincin family) have
been found  in  a  wide  variety of species, even in those that neither have a
cardiovascular system  nor  synthesize angiotensin. In vertebrates, the number
of ACE  genes appears to be limited to ACE and ACE2, but in some insects there
has been  a  much greater expansion of this gene family. The function of these
ACE-like proteins is largely unknown [1,2,3,4,5,6,7,8].

The overall  structure  of  the  M2  metallopeptidase  domain is predominantly
helical, consisting  of  twenty-one  alpha-helices, nine 3(10) helices and two
anti-parallel beta-strands  (see  <PDB:5A2R>).  The peptidase family M2 domain
can be  further  divided  into  two  subdomains (I and II), which form the two
sides of  a  long  and  deep cleft. The two catalytic subdomains are connected
only at the floor of the active site cleft. One prominent alpha-helix connects
the two subdomains and forms part of the floor of the canyon. The zinc-binding
site is located near the bottom and on one side of the large active site cleft
(subdomain I side), nearly midway along its length. The zinc is coordinated by
two His residues, one Glu, and one water molecule. These residues at the zinc-
binding site  make up the HEXXH+E motif conserved in the zinc metallopeptidase
clan MA (see <PDOC00129>). Two chloride-binding sites are present in tACE. The
N-domain of  sACE  possesses  a  CL2  site  only,  and so the enzyme has three
chloride-binding sites  in  total.  The  CL2  chloride site is absent in ACE2.
Consequently, ACE2  only  binds  a chloride ion at one CL1 site. The peptidase
family M2  domain  contains three conserved disulfide bonds, C1-C2, C3-C4, and
C5-C6 [8,9,10,11,12].

The profile we developed covers the entire peptidase family M2 domain.

-Sequences known to belong to this class detected by the profile: ALL.
-Other sequence(s) detected in Swiss-Prot: NONE.
-Last update: December 2022 / First entry.

[ 1] Burnham S., Smith J.A., Lee A.J., Isaac R.E., Shirras A.D.
     "The angiotensin-converting enzyme (ACE) gene family of Anopheles
     gambiae."
     BMC Genomics 6:172-172(2005).
     PubMed=16329762; DOI=10.1186/1471-2164-6-172
[ 2] Zhao Y., Xu C.
     "Structure and function of angiotensin converting enzyme and its
     inhibitors."
     Sheng. Wu. Gong. Cheng. Xue. Bao. 24:171-176(2008).
     PubMed=18464595; DOI=10.1016/s1872-2075(08)60007-2
[ 3] Brooks D.R., Appleford P.J., Murray L., Isaac R.E.
     "An essential role in molting and morphogenesis of Caenorhabditis
     elegans for  ACN-1, a novel member of the angiotensin-converting
     enzyme family that lacks a  metallopeptidase active site."
     J. Biol. Chem. 278:52340-52346(2003).
     PubMed=14559923; DOI=10.1074/jbc.M308858200
[ 4] Riviere G., Michaud A., Deloffre L., Vandenbulcke F., Levoye A.,
     Breton C., Corvol P., Salzet M., Vieau D.
     "Characterization of the first non-insect invertebrate functional
     angiotensin-converting enzyme (ACE): leech TtACE resembles the
     N-domain of  mammalian ACE."
     Biochem. J. 382:565-573(2004).
     PubMed=15175004; DOI=10.1042/BJ20040522
[ 5] Lubbe L., Cozier G.E., Oosthuizen D., Acharya K.R., Sturrock E.D.
     "ACE2 and ACE: structure-based insights into mechanism, regulation and
     receptor  recognition by SARS-CoV."
     Clin. Sci. (Lond). 134:2851-2871(2020).
     PubMed=33146371; DOI=10.1042/CS20200899
[ 6] Riordan J.F.
     "Angiotensin-I-converting enzyme and its relatives."
     Genome Biol 4:225-225(2003).
     PubMed=12914653; DOI=10.1186/gb-2003-4-8-225
     PubMed=19021774; DOI=10.1111/j.1742-4658.2008.06733.x
[ 7] Bingham R.J., Dive V., Phillips S.E.V., Shirras A.D., Isaac R.E.
     "Structural diversity of angiotensin-converting enzyme."
     FEBS. J. 273:362-373(2006).
     PubMed=16403023; DOI=10.1111/j.1742-4658.2005.05069.x
[ 8] Rushworth C.A., Guy J.L., Turner A.J.
     "Residues affecting the chloride regulation and substrate selectivity
     of the  angiotensin-converting enzymes (ACE and ACE2) identified by
     site-directed  mutagenesis."
     FEBS. J. 275:6033-6042(2008).
[ 9] Natesh R., Schwager S.L.U., Sturrock E.D., Acharya K.R.
     "Crystal structure of the human angiotensin-converting
     enzyme-lisinopril complex."
     Nature 421:551-554(2003).
     PubMed=12540854; DOI=10.1038/nature01370
[10] Towler P., Staker B., Prasad S.G., Menon S., Tang J., Parsons T.,
     Ryan D., Fisher M., Williams D., Dales N.A., Patane M.A.,
     Pantoliano M.W.
     "ACE2 X-ray structures reveal a large hinge-bending motion important
     for inhibitor  binding and catalysis."
     J. Biol. Chem. 279:17996-18007(2004).
     PubMed=14754895; DOI=10.1074/jbc.M311191200
[11] Corradi H.R., Schwager S.L.U., Nchinda A.T., Sturrock E.D.,
     Acharya K.R.
     "Crystal structure of the N domain of human somatic angiotensin
     I-converting  enzyme provides a structural basis for domain-specific
     inhibitor design."
     J. Mol. Biol. 357:964-974(2006).
     PubMed=16476442; DOI=10.1016/j.jmb.2006.01.048
[12] Harrison C., Acharya K.R.
     "A new high-resolution crystal structure of the Drosophila
     melanogaster  angiotensin converting enzyme homologue, AnCE."
     FEBS. Open. Bio. 5:661-667(2015).
     PubMed=26380810; DOI=10.1016/j.fob.2015.08.004

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