Gene Semantic Similarity Measure

A Gene Semantic Similarity Measure is a Semantic Similarity Measure that determines the semantic distance between genes.

• AKA: Genes Functional Similarity Measure.
• Example(s):
  • a GO-based Semantic Similarity Measure such as:
    • SimGIC Semantic Similarity Measure (e.g. Pesquita et al., 2008),
    • SimUI Semantic Similarity Measure (e.g. Genteman,2009, Guo et al., 2006),
    • GOGO Semantic Similarity Measure (Zhao & Wang, 2018),
    • SUM Match Semantic Similarity Measure (Lei & Dai , 2006),
    • G-SESAME (Wang et al., 2007)
  • a Gene Semantic Similarity Score,
  • …
• Counter-Example(s):
  • Disease Phenotype Similarity Measure,
  • Semantic Word Similarity Measure,
  • Protein Proximity Measure.
• See: Semantic Similarity Score, GO Ontology, Protein-Protein Interaction Dataset, Protein-Protein Interaction Network, Word Relatedness Measure.

References

2018

• (Zhao & Wang, 2018) ⇒ Chenguang Zhao, and Zheng Wang (2018)."GOGO: An Improved Algorithm to Measure the Semantic Similarity between Gene Ontology Terms". In: Scientific Reports volume 8, Article number: 15107.
  • QUOTE: Measuring the semantic similarity between Gene Ontology (GO) terms is an essential step in functional bioinformatics research. We implemented a software named GOGO for calculating the semantic similarity between GO terms. GOGO has the advantages of both information-content-based and hybrid methods, such as Resnik’s and Wang’s methods. Moreover, GOGO is relatively fast and does not need to calculate information content (IC) from a large gene annotation corpus but still has the advantage of using IC. This is achieved by considering the number of children nodes in the GO directed acyclic graphs when calculating the semantic contribution of an ancestor node giving to its descendent nodes. GOGO can calculate functional similarities between genes and then cluster genes based on their functional similarities. Evaluations performed on multiple pathways retrieved from the saccharomyces genome database (SGD) show that GOGO can accurately and robustly cluster genes based on functional similarities.

2011

• (Jiang et al., 2011) ⇒ Rui Jiang, Mingxin Gan, and Peng He (2011). "Constructing a Gene Semantic Similarity Network for the Inference of Disease Genes". In: BMC Systems Biology, 5(S-2). DOI:10.1186/1752-0509-5-S2-S2.
  • QUOTE: We use the length of the shortest path between two proteins in the HPRD network to measure their proximity, and we draw box plots to demonstrate the relationship between gene semantic similarity scores and protein network proximity scores in Figure 2.

2009a

• (Pesquita et al., 2009 ) ⇒ Catia Pesquita, Daniel Faria, Andre O. Falcao, Phillip Lord, and Francisco M. Couto (2009). "Semantic Similarity in Biomedical Ontologies". In: PLoS Computational Biology 5(7): e1000443.
  • QUOTE: However, based on the few comparative studies that exist, we can identify the most successful measures so far in the three main applications of GO-based semantic similarity: function prediction/validation, protein–protein interaction prediction/validation, and cellular location prediction (see Table 6).

2009b

• (Gentleman, 2009) ⇒ R. Gentleman (2009). "Visualizing and Distances Using GO".
  • QUOTE: The relationships between different GO terms, within a specific ontology are represented in the form of a directed acyclic graph. The leaves of this graph represent the most specific terms and their are edges from a specific term (child) to all less specific terms (each is a parent). The induced GO graph is the graph that obtains from taking a set of GO terms and finding all parents of those terms, and so on until the root node has been obtained.

2008a

• (Pesquita et al., 2008) &rArr Catia Pesquita, Daniel Faria, Hugo Bastos, Antonio EN Ferreira, Andre O Falcao, and Francisco M Couto (2008). "Metrics for GO based protein semantic similarity: a systematic evaluation". In: BMC Bioinformatics volume 9, Article number: S4.

2008b

• (Xu et al., 2008) ⇒ Tao Xu, LinFang Du, and Yan Zhou (2008)."Evaluation of GO-based functional similarity measures using S. cerevisiae protein interaction and expression profile data". In: BMC Bioinformatics. 2008;9.

2007

• (Wang et al., 2007a) ⇒ James Z. Wang, Zhidian Du, Rapeeporn Payattakool, Philip S. Yu, and Chin-Fu Chen (2007). "A new method to measure the semantic similarity of GO terms"In: Bioinformatics 23 (10).

2006a

• (Guo et al., 2006) ⇒ Xiang Guo, Rongxiang Liu, Craig D. Shriver, Hai Hu, and Michael N. Liebman (2006). "Assessing Semantic Similarity Measures For The Characterization Of Human Regulatory Pathways". In: Bioinformatics, Volume 22, Issue 8.

2006b

• (Lei & Dai, 2006) ⇒ Zhengdeng Lei, and Yang Dai (2006)."Assessing protein similarity with Gene Ontology and its use in subnuclear localization prediction". In: BMC Bioinformatics. 2006;7.