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  <ns1:crib124s1i rdf:about="http://metadb.riken.jp/db/SciNetS_rib124i/crib124s1rib124u3083i">
    <rdfs:label xml:lang="en">S-crystallin</rdfs:label>
    <ns1:prib124u2i rdf:resource="http://metadb.riken.jp/db/SciNetS_rib124i/crib124u1rib124u5i"/>
    <ns1:prib124s6i rdf:resource="http://metadb.riken.jp/db/SciNetS_ria1i/cria1u1ria1u9838i"/>
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    <ns1:prib124u1i xml:lang="en">&lt;p&gt;S-crystallins of cephalopod are the major protein constituent of the lens in cephalopods. Their primary protein sequences show a high degree (41%) of identity with the cephalopod digestive gland sigma-class glutathione transferase (GST). In spite of the sequence similarity, lens S-crystallin shows little if any GST activity. S-crystallins fail to bind to an S-hexylglutathione affinity column (marker for glutathione affinity) and have very little GST activity  in a typical substitution reaction with glutathione and 1-chloro-2,4-dinitrobenzene [&lt;cite idref="PUB00006499"/&gt;]. Nevertheless, pH rate profiles indicate that any               reactions that do take place proceed via the same mechanism as GSTs [&lt;cite idref="PUB00006357"/&gt;]. Sequence analysis suggests that the S-crystallins arose from gene duplication of a cephalopod sigma-class GST [&lt;cite idref="PUB00043616"/&gt;].&lt;/p&gt;&lt;p&gt;The three-dimensional structure of the sigma-class GST from squid has been determined to 2.4A resolution [&lt;cite idref="PUB00006320"/&gt;]. The protein is characterised by two                domains, one of which has a 3-layer(aba) sandwich architecture, the other               being largely helical. The modelled S-crystallin structure has a similar                topology to the squid sigma-class GST, with longer helices 4 and 5,                corresponding to a long insertion. The insertion causes the active centre               to be in a more closed conformation than sigma-class GSTs and may explain               the low affinity for glutathione [&lt;cite idref="PUB00006499"/&gt;].&lt;/p&gt;&lt;p&gt;The function of glutathione S-transferases (GST) is the conjugation of reduced glutathione to a wide number of exogenous and endogenous hydrophobic electrophiles. The isoenzymes appear to play a central role in the parasite detoxification system. Glutathione S-transferases form homodimers, but in eukaryotes can also form heterodimers of the A1 and A2 or YC1 and YC2 subunits. The GST domain is also found in S-crystallins from squid, and proteins with no known GST activity, such as eukaryotic elongation factors 1-gamma and the HSP26 family of stress-related proteins, which include auxin-regulated proteins in plants and stringent starvation proteins in &lt;taxon tax_id="562"&gt;Escherichia coli&lt;/taxon&gt;.&lt;/p&gt;</ns1:prib124u1i>
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    <ns1:prib124s6i rdf:resource="http://metadb.riken.jp/db/SciNetS_ria1i/cria1u1ria1u43836i"/>
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