1. External links

2. References

The trefoil knot fold is a protein fold in which the protein backbone is twisted into a trefoil knot shape. "Shallow" knots in which the tail of the polypeptide chain only passes through a loop by a few residues are uncommon, but "deep" knots in which many residues are passed through the loop are extremely rare. Deep trefoil knots have been found in the SPOUT superfamily.{{ref|Tkaczuk}} including methyltransferase proteins involved in posttranscriptional RNA modification in all three Domains of Life, including bacterium Thermus thermophilus {{ref|Nureki1}} and proteins{{ref|Nureki2}}, in archaea{{ref|Zarembinski}} and in eukaryota{{ref|Leulliot}}.

In many cases the trefoil knot is part of the active site or a ligand-binding site and is critical to the activity of the enzyme in which it appears. Before the discovery of the first knotted protein, it was believed that the process of protein folding could not efficiently produce deep knots in protein backbones. Studies of the folding kinetics of a dimeric protein from Haemophilus influenzae have revealed that the folding of trefoil knot proteins may depend on proline isomerization{{ref|Mallam}}. Computational algorithms have been developed to identify knotted protein structures, both to canvas the Protein Data Bank for previously undetected natural knots and to identify knots in protein structure predictions, where they are unlikely to accurately reproduce the native-state structure due to the rarity of knots in known proteins{{ref|Khatib}}. Currently, there is a web server pKNOT{{ref|Lai}} available to detect knots in proteins as well as to provide information on knotted proteins in the Protein Data Bank.

Knottins are small, diverse and stable proteins with important drug design potential. They can be classified in 30 families which cover a wide range of sequences (1621 sequenced), three-dimensional structures (155 solved) and functions (> 10). Inter knottin similarity lies mainly between 20% and 40% sequence identity and 1.5 to 4 A backbone deviations although they all share a tightly knotted disulfide core. This important variability is likely to arise from the highly diverse loops which connect the successive knotted cysteines. The prediction of structural models for all knottin sequences would open new directions for the analysis of interaction sites and to provide a better understanding of the structural and functional organization of proteins sharing this scaffold {{ref|Jerome Gracy}}.

External links

• SCOP alpha/beta knot fold
• [https://web.archive.org/web/20070312154618/http://www.cathdb.info/cgi-bin/cath/GotoCath.pl?cath=3.40.1280 CATH alpha/beta knot topology]
• [https://web.archive.org/web/20110824133833/http://pknot.life.nctu.edu.tw/ pKNOT the web server to detect knots in proteins]

References

1. {{note|Zarembinski}} Zarembinski TI, Kim Y, Peterson K, Christendat D, Dharamsi A, Arrowsmith CH, Edwards AM, Joachimiak A. (2003). Deep trefoil knot implicated in RNA binding found in an archaebacterial protein. Proteins 50(2):177-83.
2. {{note|Nureki1}} Nureki O, Shirouzu M, Hashimoto K, Ishitani R, Terada T, Tamakoshi M, Oshima T, Chijimatsu M, Takio K, Vassylyev DG, Shibata T, Inoue Y, Kuramitsu S, Yokoyama S. (2002). An enzyme with a deep trefoil knot for the active-site architecture. Acta Crystallogr D 58(Pt 7):1129-37.
3. {{note|Nureki2}} Nureki O, Watanabe K, Fukai S, Ishii R, Endo Y, Hori H, Yokoyama S. (2004). Deep knot structure for construction of active site and cofactor binding site of tRNA modification enzyme. Structure 12(4):593-602.
4. {{note|Leulliot}} Leulliot N, Bohnsack MT, Graille M, Tollervey D, Van Tilbeurgh H.(2008). The yeast ribosome synthesis factor Emg1 is a novel member of the superfamily of alpha/beta knot fold methyltransferases. Nucleic Acids Res 36(2):629-39.
5. {{note|Tkaczuk}} Tkaczuk KL, Dunin-Horkawicz S, Purta E, Bujnicki JM. (2007). Structural and evolutionary bioinformatics of the SPOUT superfamily of methyltransferases. BMC Bioinformatics. 8:73.
6. {{note|Mallam}} Mallam AL, Jackson SE. (2006). Probing nature's knots: the folding pathway of a knotted homodimeric protein. J Mol Biol 359(5):1420-36.
7. {{note|Khatib}} Khatib F, Weirauch MT, Rohl CA. (2006). Rapid knot detection and application to protein structure prediction. Bioinformatics 22(14):e252-9.
8. {{note|Lai}} Lai YL, Yen SC, Yu SH, Hwang JK (2007). pKNOT: the protein KNOT web server. Nucleic Acids Research 35:W420-424.
9. {{note|Jerome Gracy}}(Jerome Gracy and Laurent Chiche (2010). Optimizing structural modeling for a specific protein scaffold: knottins or inhibitor cystine knots. BMC Bioinformatics. 11:535).

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