Content | |
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Description | database expansion and significantly improved reduction of false-positive predictions from consensus sequences. |
Contact | |
Laboratory | Sanguthevar Rajasekaran and Martin R. Schiller |
Authors | Mi, Tian; Merlin Jerlin Camilus, Deverasetty Sandeep, Gryk Michael R, Bill Travis J, Brooks Andrew W, Lee Logan Y, Rathnayake Viraj, Ross Christian A, Sargeant David P, Strong Christy L, Watts Paula, Rajasekaran Sanguthevar, Schiller Martin R |
Primary citation | Mi, Tian; Merlin Jerlin Camilus, Deverasetty Sandeep, Gryk Michael R, Bill Travis J, Brooks Andrew W, Lee Logan Y, Rathnayake Viraj, Ross Christian A, Sargeant David P, Strong Christy L, Watts Paula, Rajasekaran Sanguthevar, Schiller Martin R (2012)[1] |
Release date | 2011 |
Access | |
Website | http://mnm.engr.uconn.edu http://minimotifminer.org |
Minimotif Miner is a program and database designed to identify minimotifs in any protein.[2][3][4] Minimotifs are short, contiguous peptide sequences that are known to have a function in at least one protein. Minimotifs are also called sequence motifs or short linear motifs or SLiMs. These are generally restricted to one secondary structure element and are less than 15 amino acids in length.
Description
Functions can be binding motifs that bind another macromolecule or small compound, that induce a covalent modification of minimotif, or are involved in the protein trafficking of the protein containing the minimotif. The basic premise of Minimotif Miner is that is a short peptide sequence is known to have a function in one protein, may have a similar function in another query protein. The current release of the MnM 3.0 database has ~300,000 minimotifs and can be searched at the website.
There are two workflows that are of interest to scientists that use Minimotif Miner 1) Entering any query protein into Minimotif Miner returns a table with a list of minimotif sequence and functions that have a sequence pattern match with the protein query sequence. These provide potential new functions in the protein query. 2) By using the view single nucleotide polymorphism (SNP) function, SNPs from dbSNP are mapped in the sequence window. A user can select any set of the SNPs and then identify any minimotif that is introduced or eliminated by the SNP or mutation. This helps to identify minimotifs involved in generating organism diversity or those that may be associated with a disease.
Typical results of MnM predict more than 50 new minimotifs for a protein query. A major limitation in this type of analysis is that the low sequence complexity of short minimotifs produces false positive predictions where the sequence occurs in a protein by random chance and not because it contains the predicted function. MnM 3.0 introduces a library of advanced heuristics and filters, which enable vast reduction of false positive predictions. These filters use minimotif complexity, protein surface location, molecular processes, cellular processes, protein-protein interactions, and genetic interactions. We recently combined all of these heuristics into a single, compound filter which makes significant progress toward solving this problem with high accuracy of minimotif prediction as measured by a performance benchmarking study which evaluated both sensitivity and specificity.
See also
References
- ↑ Mi, Tian; Merlin Jerlin Camilus; Deverasetty Sandeep; Gryk Michael R; Bill Travis J; Brooks Andrew W; Lee Logan Y; Rathnayake Viraj; Ross Christian A; Sargeant David P; Strong Christy L; Watts Paula; Rajasekaran Sanguthevar; Schiller Martin R (Jan 2012). "Minimotif Miner 3.0: database expansion and significantly improved reduction of false-positive predictions from consensus sequences". Nucleic Acids Res. England. 40 (1): D252–60. doi:10.1093/nar/gkr1189. PMC 3245078. PMID 22146221.
- ↑ Schiller, Martin R. (2007). "Minimotif Miner: A Computational Tool to Investigate Protein Function, Disease, and Genetic Diversity". Current Protocols in Protein Science. 48: 2.12.1–2.12.14. doi:10.1002/0471140864.ps0212s48. ISBN 978-0-471-14086-3. PMID 18429315. S2CID 10406520.
- ↑ Rajasekaran, Sanguthevar; Balla, Sudha; Gradie, Patrick; Gryk, Michael R.; Kadaveru, Krishna; Kundeti, Vamsi; MacIejewski, Mark W.; Mi, Tian; et al. (2009). "Minimotif miner 2nd release: a database and web system for motif search". Nucleic Acids Research. 37 (Database issue): D185–90. doi:10.1093/nar/gkn865. PMC 2686579. PMID 18978024.
- ↑ Balla, Sudha; Thapar, Vishal; Verma, Snigda; Luong, ThaiBinh; Faghri, Tanaz; Huang, Chun-Hsi; Rajasekaran, Sanguthevar; del Campo, Jacob J; Shinn, Jessica H; Mohler, William A; Maciejewski, Mark W; Gryk, Michael R; Piccirillo, Bryan; Schiller, Stanley R; Schiller, Martin R (2006). "Minimotif Miner, a tool for investigating protein function". Nature Methods. 3 (3): 175–177. doi:10.1038/nmeth856. PMID 16489333. S2CID 15571142.
Further reading
- Vyas, Jay; Nowling, Ronald J.; MacIejewski, Mark W.; Rajasekaran, Sanguthevar; Gryk, Michael R.; Schiller, Martin R. (2009). "A proposed syntax for Minimotif Semantics, version 1". BMC Genomics. 10: 360. doi:10.1186/1471-2164-10-360. PMC 2733157. PMID 19656396.
- Vyas, Jay; Nowling, Ronald J.; Meusburger, Thomas; Sargeant, David; Kadaveru, Krishna; Gryk, Michael R.; Kundeti, Vamsi; Rajasekaran, Sanguthevar; Schiller, Martin R. (2010). "MimoSA: a system for minimotif annotation". BMC Bioinformatics. 11: 328. doi:10.1186/1471-2105-11-328. PMC 2905367. PMID 20565705.
- Kadaveru, Krishna; Vyas, Jay; Schiller, Martin R. (2008). "Viral infection and human disease - insights from minimotifs". Frontiers in Bioscience. 13 (13): 6455–71. doi:10.2741/3166. PMC 2628544. PMID 18508672.