13 results on '"Naha, Sanchita"'
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2. Context-Aware Recommender System for Maize Cultivation
- Author
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Naha, Sanchita and Marwaha, Sudeep
- Published
- 2020
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3. PredPSP: a novel computational tool to discover pathway-specific photosynthetic proteins in plants
- Author
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Meher, Prabina Kumar, Pradhan, Upendra Kumar, Sethi, Padma Lochan, Naha, Sanchita, Gupta, Ajit, and Parsad, Rajender
- Published
- 2024
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4. ASPTF: A computational tool to predict abiotic stress-responsive transcription factors in plants by employing machine learning algorithms
- Author
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Pradhan, Upendra Kumar, Mahapatra, Anuradha, Naha, Sanchita, Gupta, Ajit, Parsad, Rajender, Gahlaut, Vijay, Rath, Surya Narayan, and Meher, Prabina Kumar
- Published
- 2024
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5. ASmiR: a machine learning framework for prediction of abiotic stress–specific miRNAs in plants
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Pradhan, Upendra Kumar, Meher, Prabina Kumar, Naha, Sanchita, Rao, Atmakuri Ramakrishna, Kumar, Upendra, Pal, Soumen, and Gupta, Ajit
- Published
- 2023
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6. ASLncR: a novel computational tool for prediction of abiotic stress-responsive long non-coding RNAs in plants
- Author
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Pradhan, Upendra Kumar, Meher, Prabina Kumar, Naha, Sanchita, Rao, Atmakuri Ramakrishna, and Gupta, Ajit
- Published
- 2023
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7. DBPMod: a supervised learning model for computational recognition of DNA-binding proteins in model organisms.
- Author
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Pradhan, Upendra K, Meher, Prabina K, Naha, Sanchita, Sharma, Nitesh K, Agarwal, Aarushi, Gupta, Ajit, and Parsad, Rajender
- Subjects
SUPERVISED learning ,DNA-binding proteins ,DEEP learning ,INTERNET servers ,PROTEIN models ,MACHINE learning ,RECEIVER operating characteristic curves - Abstract
DNA-binding proteins (DBPs) play critical roles in many biological processes, including gene expression, DNA replication, recombination and repair. Understanding the molecular mechanisms underlying these processes depends on the precise identification of DBPs. In recent times, several computational methods have been developed to identify DBPs. However, because of the generic nature of the models, these models are unable to identify species-specific DBPs with higher accuracy. Therefore, a species-specific computational model is needed to predict species-specific DBPs. In this paper, we introduce the computational DBPMod method, which makes use of a machine learning approach to identify species-specific DBPs. For prediction, both shallow learning algorithms and deep learning models were used, with shallow learning models achieving higher accuracy. Additionally, the evolutionary features outperformed sequence-derived features in terms of accuracy. Five model organisms, including Caenorhabditis elegans , Drosophila melanogaster , Escherichia coli , Homo sapiens and Mus musculus , were used to assess the performance of DBPMod. Five-fold cross-validation and independent test set analyses were used to evaluate the prediction accuracy in terms of area under receiver operating characteristic curve (auROC) and area under precision-recall curve (auPRC), which was found to be ~89–92% and ~89–95%, respectively. The comparative results demonstrate that the DBPMod outperforms 12 current state-of-the-art computational approaches in identifying the DBPs for all five model organisms. We further developed the web server of DBPMod to make it easier for researchers to detect DBPs and is publicly available at https://iasri-sg.icar.gov.in/dbpmod/. DBPMod is expected to be an invaluable tool for discovering DBPs, supplementing the current experimental and computational methods. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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8. ProkDBP: Toward more precise identification of prokaryotic DNA binding proteins.
- Author
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Pradhan, Upendra Kumar, Meher, Prabina Kumar, Naha, Sanchita, Das, Ritwika, Gupta, Ajit, and Parsad, Rajender
- Abstract
Prokaryotic DNA binding proteins (DBPs) play pivotal roles in governing gene regulation, DNA replication, and various cellular functions. Accurate computational models for predicting prokaryotic DBPs hold immense promise in accelerating the discovery of novel proteins, fostering a deeper understanding of prokaryotic biology, and facilitating the development of therapeutics targeting for potential disease interventions. However, existing generic prediction models often exhibit lower accuracy in predicting prokaryotic DBPs. To address this gap, we introduce ProkDBP, a novel machine learning‐driven computational model for prediction of prokaryotic DBPs. For prediction, a total of nine shallow learning algorithms and five deep learning models were utilized, with the shallow learning models demonstrating higher performance metrics compared to their deep learning counterparts. The light gradient boosting machine (LGBM), coupled with evolutionarily significant features selected via random forest variable importance measure (RF‐VIM) yielded the highest five‐fold cross‐validation accuracy. The model achieved the highest auROC (0.9534) and auPRC (0.9575) among the 14 machine learning models evaluated. Additionally, ProkDBP demonstrated substantial performance with an independent dataset, exhibiting higher values of auROC (0.9332) and auPRC (0.9371). Notably, when benchmarked against several cutting‐edge existing models, ProkDBP showcased superior predictive accuracy. Furthermore, to promote accessibility and usability, ProkDBP (https://iasri-sg.icar.gov.in/prokdbp/) is available as an online prediction tool, enabling free access to interested users. This tool stands as a significant contribution, enhancing the repertoire of resources for accurate and efficient prediction of prokaryotic DBPs. [ABSTRACT FROM AUTHOR]
- Published
- 2024
- Full Text
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9. RBPLight: a computational tool for discovery of plant-specific RNA-binding proteins using light gradient boosting machine and ensemble of evolutionary features.
- Author
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Pradhan, Upendra K, Meher, Prabina K, Naha, Sanchita, Pal, Soumen, Gupta, Sagar, Gupta, Ajit, and Parsad, Rajender
- Subjects
RNA-binding proteins ,GENETIC regulation ,RNA splicing ,MACHINE learning ,INTERNET servers ,DEEP learning ,CELLULAR control mechanisms ,PLANT species - Abstract
RNA-binding proteins (RBPs) are essential for post-transcriptional gene regulation in eukaryotes, including splicing control, mRNA transport and decay. Thus, accurate identification of RBPs is important to understand gene expression and regulation of cell state. In order to detect RBPs, a number of computational models have been developed. These methods made use of datasets from several eukaryotic species, specifically from mice and humans. Although some models have been tested on Arabidopsis , these techniques fall short of correctly identifying RBPs for other plant species. Therefore, the development of a powerful computational model for identifying plant-specific RBPs is needed. In this study, we presented a novel computational model for locating RBPs in plants. Five deep learning models and ten shallow learning algorithms were utilized for prediction with 20 sequence-derived and 20 evolutionary feature sets. The highest repeated five-fold cross-validation accuracy, 91.24% AU-ROC and 91.91% AU-PRC, was achieved by light gradient boosting machine. While evaluated using an independent dataset, the developed approach achieved 94.00% AU-ROC and 94.50% AU-PRC. The proposed model achieved significantly higher accuracy for predicting plant-specific RBPs as compared to the currently available state-of-art RBP prediction models. Despite the fact that certain models have already been trained and assessed on the model organism Arabidopsis , this is the first comprehensive computer model for the discovery of plant-specific RBPs. The web server RBPLight was also developed, which is publicly accessible at https://iasri-sg.icar.gov.in/rbplight/ , for the convenience of researchers to identify RBPs in plants. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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10. PlDBPred: a novel computational model for discovery of DNA binding proteins in plants.
- Author
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Pradhan, Upendra Kumar, Meher, Prabina Kumar, Naha, Sanchita, Pal, Soumen, Gupta, Ajit, and Parsad, Rajender
- Subjects
DNA-binding proteins ,MACHINE learning ,PLANT proteins ,RECEIVER operating characteristic curves ,DEEP learning ,GENETIC regulation - Abstract
DNA-binding proteins (DBPs) play crucial roles in numerous cellular processes including nucleotide recognition, transcriptional control and the regulation of gene expression. Majority of the existing computational techniques for identifying DBPs are mainly applicable to human and mouse datasets. Even though some models have been tested on Arabidopsis, they produce poor accuracy when applied to other plant species. Therefore, it is imperative to develop an effective computational model for predicting plant DBPs. In this study, we developed a comprehensive computational model for plant specific DBPs identification. Five shallow learning and six deep learning models were initially used for prediction, where shallow learning methods outperformed deep learning algorithms. In particular, support vector machine achieved highest repeated 5-fold cross-validation accuracy of 94.0% area under receiver operating characteristic curve (AUC-ROC) and 93.5% area under precision recall curve (AUC-PR). With an independent dataset, the developed approach secured 93.8% AUC-ROC and 94.6% AUC-PR. While compared with the state-of-art existing tools by using an independent dataset, the proposed model achieved much higher accuracy. Overall results suggest that the developed computational model is more efficient and reliable as compared to the existing models for the prediction of DBPs in plants. For the convenience of the majority of experimental scientists, the developed prediction server P l DBPred is publicly accessible at https://iasri-sg.icar.gov.in/pldbpred/.The source code is also provided at https://iasri-sg.icar.gov.in/pldbpred/source%5fcode.php for prediction using a large-size dataset. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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11. AScirRNA: A novel computational approach to discover abiotic stress-responsive circular RNAs in plant genome.
- Author
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Pradhan UK, Behera P, Das R, Naha S, Gupta A, Parsad R, Pradhan SK, and Meher PK
- Abstract
In the realm of plant biology, understanding the intricate regulatory mechanisms governing stress responses stands as a pivotal pursuit. Circular RNAs (circRNAs), emerging as critical players in gene regulation, have garnered attention in recent days for their potential roles in abiotic stress adaptation. A comprehensive grasp of circRNAs' functions in stress response offers avenues for breeders to manipulating plants to develop abiotic stress resistant crop cultivars to thrive in challenging climates. This study pioneers a machine learning-based model for predicting abiotic stress-responsive circRNAs. The K-tuple nucleotide composition (KNC) and Pseudo KNC (PKNC) features were utilized to numerically represent circRNAs. Three different feature selection strategies were employed to select relevant and non-redundant features. Eight shallow and four deep learning algorithms were evaluated to build the final predictive model. Following five-fold cross-validation process, XGBoost learning algorithm demonstrated superior performance with LightGBM-chosen 260 KNC features (Accuracy: 74.55 %, auROC: 81.23 %, auPRC: 76.52 %) and 160 PKNC features (Accuracy: 74.32 %, auROC: 81.04 %, auPRC: 76.43 %), over other combinations of learning algorithms and feature selection techniques. Further, the robustness of the developed models were evaluated using an independent test dataset, where the overall accuracy, auROC and auPRC were found to be 73.13 %, 72.34 % and 72.68 % for KNC feature set and 73.52 %, 79.53 % and 73.09 % for PKNC feature set, respectively. This computational approach was also integrated into an online prediction tool, AScirRNA (https://iasri-sg.icar.gov.in/ascirna/) for easy prediction by the users. Both the proposed model and the developed tool are poised to augment ongoing efforts in identifying stress-responsive circRNAs in plants., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier Ltd. All rights reserved.)
- Published
- 2024
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12. ProkDBP: Toward more precise identification of prokaryotic DNA binding proteins.
- Author
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Pradhan UK, Meher PK, Naha S, Das R, Gupta A, and Parsad R
- Subjects
- Algorithms, Computational Biology methods, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Bacterial Proteins genetics, DNA-Binding Proteins chemistry, DNA-Binding Proteins metabolism, Machine Learning
- Abstract
Prokaryotic DNA binding proteins (DBPs) play pivotal roles in governing gene regulation, DNA replication, and various cellular functions. Accurate computational models for predicting prokaryotic DBPs hold immense promise in accelerating the discovery of novel proteins, fostering a deeper understanding of prokaryotic biology, and facilitating the development of therapeutics targeting for potential disease interventions. However, existing generic prediction models often exhibit lower accuracy in predicting prokaryotic DBPs. To address this gap, we introduce ProkDBP, a novel machine learning-driven computational model for prediction of prokaryotic DBPs. For prediction, a total of nine shallow learning algorithms and five deep learning models were utilized, with the shallow learning models demonstrating higher performance metrics compared to their deep learning counterparts. The light gradient boosting machine (LGBM), coupled with evolutionarily significant features selected via random forest variable importance measure (RF-VIM) yielded the highest five-fold cross-validation accuracy. The model achieved the highest auROC (0.9534) and auPRC (0.9575) among the 14 machine learning models evaluated. Additionally, ProkDBP demonstrated substantial performance with an independent dataset, exhibiting higher values of auROC (0.9332) and auPRC (0.9371). Notably, when benchmarked against several cutting-edge existing models, ProkDBP showcased superior predictive accuracy. Furthermore, to promote accessibility and usability, ProkDBP (https://iasri-sg.icar.gov.in/prokdbp/) is available as an online prediction tool, enabling free access to interested users. This tool stands as a significant contribution, enhancing the repertoire of resources for accurate and efficient prediction of prokaryotic DBPs., (© 2024 The Protein Society.)
- Published
- 2024
- Full Text
- View/download PDF
13. RBProkCNN: Deep learning on appropriate contextual evolutionary information for RNA binding protein discovery in prokaryotes.
- Author
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Pradhan UK, Naha S, Das R, Gupta A, Parsad R, and Meher PK
- Abstract
RNA-binding proteins (RBPs) are central to key functions such as post-transcriptional regulation, mRNA stability, and adaptation to varied environmental conditions in prokaryotes. While the majority of research has concentrated on eukaryotic RBPs, recent developments underscore the crucial involvement of prokaryotic RBPs. Although computational methods have emerged in recent years to identify RBPs, they have fallen short in accurately identifying prokaryotic RBPs due to their generic nature. To bridge this gap, we introduce RBProkCNN, a novel machine learning-driven computational model meticulously designed for the accurate prediction of prokaryotic RBPs. The prediction process involves the utilization of eight shallow learning algorithms and four deep learning models, incorporating PSSM-based evolutionary features. By leveraging a convolutional neural network (CNN) and evolutionarily significant features selected through extreme gradient boosting variable importance measure, RBProkCNN achieved the highest accuracy in five-fold cross-validation, yielding 98.04% auROC and 98.19% auPRC. Furthermore, RBProkCNN demonstrated robust performance with an independent dataset, showcasing a commendable 95.77% auROC and 95.78% auPRC. Noteworthy is its superior predictive accuracy when compared to several state-of-the-art existing models. RBProkCNN is available as an online prediction tool (https://iasri-sg.icar.gov.in/rbprokcnn/), offering free access to interested users. This tool represents a substantial contribution, enriching the array of resources available for the accurate and efficient prediction of prokaryotic RBPs., Competing Interests: The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (© 2024 The Authors.)
- Published
- 2024
- Full Text
- View/download PDF
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