Extraction of Genic Interactions with the Recursive Logical Theory of an Ontology

Manine, Alain-Pierre; Alphonse, Erick; Bessières, Philippe

doi:10.1007/978-3-642-12116-6_47

Cited by 2 publications

(4 citation statements)

References 19 publications

(25 reference statements)

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“…The semantic annotation scheme was developed by two annotators through a series of independent annotations of the corpus, followed by reconciliation steps, which could involve concerted modifications [ 6 ]. As a third and final stage, the corpus was reviewed and the annotation was simplified to make it more appropriate to the contest.…”

Section: Methodsmentioning

confidence: 99%

“…Typically in the bacteria literature, the genic regulations are more likely expressed by the direct binding of the protein, while in the eukaryote literature, non-genic agents related to environmental conditions are much more frequent. The bacteria Gene Interaction task (GI) is based on [ 6 ], which is a semantic re-annotation of the LLL challenge corpus [ 1 ], for which the description of the GI events in a fine-grained representation includes the distinction between expression, transcription and other action events, as well as different transcription controls (e.g., regulon membership, promoter binding). The entities not only are protein agents and gene targets but also extend to families, complexes and DNA sites (binding sites, promoters) to better capture the complexity of the regulation at a molecular level.…”

Section: Introductionmentioning

confidence: 99%

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BioNLP Shared Task - The Bacteria Track

et al. 2012

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BackgroundWe present the BioNLP 2011 Shared Task Bacteria Track, the first Information Extraction challenge entirely dedicated to bacteria. It includes three tasks that cover different levels of biological knowledge. The Bacteria Gene Renaming supporting task is aimed at extracting gene renaming and gene name synonymy in PubMed abstracts. The Bacteria Gene Interaction is a gene/protein interaction extraction task from individual sentences. The interactions have been categorized into ten different sub-types, thus giving a detailed account of genetic regulations at the molecular level. Finally, the Bacteria Biotopes task focuses on the localization and environment of bacteria mentioned in textbook articles.We describe the process of creation for the three corpora, including document acquisition and manual annotation, as well as the metrics used to evaluate the participants' submissions.ResultsThree teams submitted to the Bacteria Gene Renaming task; the best team achieved an F-score of 87%. For the Bacteria Gene Interaction task, the only participant's score had reached a global F-score of 77%, although the system efficiency varies significantly from one sub-type to another. Three teams submitted to the Bacteria Biotopes task with very different approaches; the best team achieved an F-score of 45%. However, the detailed study of the participating systems efficiency reveals the strengths and weaknesses of each participating system.ConclusionsThe three tasks of the Bacteria Track offer participants a chance to address a wide range of issues in Information Extraction, including entity recognition, semantic typing and coreference resolution. We found commond trends in the most efficient systems: the systematic use of syntactic dependencies and machine learning. Nevertheless, the originality of the Bacteria Biotopes task encouraged the use of interesting novel methods and techniques, such as term compositionality, scopes wider than the sentence.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

BioNLP Shared Task - The Bacteria Track

et al. 2012

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“…Similarly, ATRE has been used in [10] to learn a recursive logical theory of the ontology from a biological text corpus. However these ILP approaches cannot be easily extended for the general task of learning data transformation programs from examples.…”

Section: Related Workmentioning

confidence: 99%

“…However these ILP approaches cannot be easily extended for the general task of learning data transformation programs from examples. Both [2,10] have only been demonstrated on extraction of specific types of information from biological text, and did not attempt more general text transformation tasks of the kinds demonstrated in our paper. Moreover, these approaches were not shown to learn recursive rules from a small number of training examples and also do not support predicate invention.…”

Section: Related Workmentioning

confidence: 99%

Meta-Interpretive Learning of Data Transformation Programs

Cropper

Tamaddoni‐Nezhad

Muggleton

2016

Lecture Notes in Computer Science

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Abstract. Data transformation involves the manual construction of large numbers of special-purpose programs. Although typically small, such programs can be complex, involving problem decomposition, recursion, and recognition of context. Building such programs is common in commercial and academic data analytic projects and can be labour intensive and expensive, making it a suitable candidate for machine learning. In this paper, we use the meta-interpretive learning framework (MIL) to learn recursive data transformation programs from small numbers of examples. MIL is well suited to this task because it supports problem decomposition through predicate invention, learning recursive programs, learning from few examples, and learning from only positive examples. We apply Metagol, a MIL implementation, to both semi-structured and unstructured data. We conduct experiments on three real-world datasets: medical patient records, XML mondial records, and natural language taken from ecological papers. The experimental results suggest that high levels of predictive accuracy can be achieved in these tasks from small numbers of training examples, especially when learning with recursion.

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Extraction of Genic Interactions with the Recursive Logical Theory of an Ontology

Cited by 2 publications

References 19 publications

BioNLP Shared Task - The Bacteria Track

BioNLP Shared Task - The Bacteria Track

Meta-Interpretive Learning of Data Transformation Programs

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