Multiple linear regression for reconstruction of gene regulatory networks in solving cascade error problems
Gene regulatory network (GRN) reconstruction is the process of identifying regulatory gene interactions from experimental data through computational analysis. One of the main reasons for the reduced performance of previous GRN methods had been inaccurate prediction of cascade motifs. Cascade error i...
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my.uniten.dspace-234762023-05-29T14:40:51Z Multiple linear regression for reconstruction of gene regulatory networks in solving cascade error problems Salleh F.H.M. Zainudin S. Arif S.M. 26423229000 24479069300 26646287700 Gene regulatory network (GRN) reconstruction is the process of identifying regulatory gene interactions from experimental data through computational analysis. One of the main reasons for the reduced performance of previous GRN methods had been inaccurate prediction of cascade motifs. Cascade error is defined as the wrong prediction of cascade motifs, where an indirect interaction ismisinterpreted as a direct interaction. Despite the active research on various GRN prediction methods, the discussion on specific methods to solve problems related to cascade errors is still lacking. In fact, the experiments conducted by the past studies were not specifically geared towards proving the ability of GRN prediction methods in avoiding the occurrences of cascade errors. Hence, this research aims to propose Multiple Linear Regression (MLR) to infer GRN from gene expression data and to avoid wrongly inferring of an indirect interaction (A ? B ? C) as a direct interaction (A ? C). Since the number of observations of the real experiment datasets was far less than the number of predictors, some predictors were eliminated by extracting the random subnetworks from global interaction networks via an established extraction method. In addition, the experiment was extended to assess the effectiveness of MLR in dealing with cascade error by using a novel experimental procedure that had been proposed in this work. The experiment revealed that the number of cascade errors had been very minimal. Apart from that, the Belsley collinearity test proved that multicollinearity did affect the datasets used in this experiment greatly. All the tested subnetworks obtained satisfactory results, with AUROC values above 0.5. Copyright � 2017 Faridah Hani Mohamed Salleh et al. Final 2023-05-29T06:40:50Z 2023-05-29T06:40:50Z 2017 Article 10.1155/2017/4827171 2-s2.0-85013276084 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85013276084&doi=10.1155%2f2017%2f4827171&partnerID=40&md5=8b92fa890aac007ce5f8b936630f1050 https://irepository.uniten.edu.my/handle/123456789/23476 2017 4827171 All Open Access, Gold, Green Hindawi Publishing Corporation Scopus |
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Gene regulatory network (GRN) reconstruction is the process of identifying regulatory gene interactions from experimental data through computational analysis. One of the main reasons for the reduced performance of previous GRN methods had been inaccurate prediction of cascade motifs. Cascade error is defined as the wrong prediction of cascade motifs, where an indirect interaction ismisinterpreted as a direct interaction. Despite the active research on various GRN prediction methods, the discussion on specific methods to solve problems related to cascade errors is still lacking. In fact, the experiments conducted by the past studies were not specifically geared towards proving the ability of GRN prediction methods in avoiding the occurrences of cascade errors. Hence, this research aims to propose Multiple Linear Regression (MLR) to infer GRN from gene expression data and to avoid wrongly inferring of an indirect interaction (A ? B ? C) as a direct interaction (A ? C). Since the number of observations of the real experiment datasets was far less than the number of predictors, some predictors were eliminated by extracting the random subnetworks from global interaction networks via an established extraction method. In addition, the experiment was extended to assess the effectiveness of MLR in dealing with cascade error by using a novel experimental procedure that had been proposed in this work. The experiment revealed that the number of cascade errors had been very minimal. Apart from that, the Belsley collinearity test proved that multicollinearity did affect the datasets used in this experiment greatly. All the tested subnetworks obtained satisfactory results, with AUROC values above 0.5. Copyright � 2017 Faridah Hani Mohamed Salleh et al. |
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26423229000 |
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26423229000 Salleh F.H.M. Zainudin S. Arif S.M. |
| format |
Article |
| author |
Salleh F.H.M. Zainudin S. Arif S.M. |
| spellingShingle |
Salleh F.H.M. Zainudin S. Arif S.M. Multiple linear regression for reconstruction of gene regulatory networks in solving cascade error problems |
| author_sort |
Salleh F.H.M. |
| title |
Multiple linear regression for reconstruction of gene regulatory networks in solving cascade error problems |
| title_short |
Multiple linear regression for reconstruction of gene regulatory networks in solving cascade error problems |
| title_full |
Multiple linear regression for reconstruction of gene regulatory networks in solving cascade error problems |
| title_fullStr |
Multiple linear regression for reconstruction of gene regulatory networks in solving cascade error problems |
| title_full_unstemmed |
Multiple linear regression for reconstruction of gene regulatory networks in solving cascade error problems |
| title_sort |
multiple linear regression for reconstruction of gene regulatory networks in solving cascade error problems |
| publisher |
Hindawi Publishing Corporation |
| publishDate |
2023 |
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1806428029587554304 |