Your search keyword '"Sungroh Yoon"' showing total 7 results

1. Protein transfer learning improves identification of heat shock protein families.

Author

Seonwoo Min, HyunGi Kim, Byunghan Lee, and Sungroh Yoon

Subjects

Medicine, Science

Abstract

Heat shock proteins (HSPs) play a pivotal role as molecular chaperones against unfavorable conditions. Although HSPs are of great importance, their computational identification remains a significant challenge. Previous studies have two major limitations. First, they relied heavily on amino acid composition features, which inevitably limited their prediction performance. Second, their prediction performance was overestimated because of the independent two-stage evaluations and train-test data redundancy. To overcome these limitations, we introduce two novel deep learning algorithms: (1) time-efficient DeepHSP and (2) high-performance DeeperHSP. We propose a convolutional neural network (CNN)-based DeepHSP that classifies both non-HSPs and six HSP families simultaneously. It outperforms state-of-the-art algorithms, despite taking 14-15 times less time for both training and inference. We further improve the performance of DeepHSP by taking advantage of protein transfer learning. While DeepHSP is trained on raw protein sequences, DeeperHSP is trained on top of pre-trained protein representations. Therefore, DeeperHSP remarkably outperforms state-of-the-art algorithms increasing F1 scores in both cross-validation and independent test experiments by 20% and 10%, respectively. We envision that the proposed algorithms can provide a proteome-wide prediction of HSPs and help in various downstream analyses for pathology and clinical research.

Published

2021

2. DUDE-Seq: Fast, flexible, and robust denoising for targeted amplicon sequencing.

Author

Byunghan Lee, Taesup Moon, Sungroh Yoon, and Tsachy Weissman

Subjects

Medicine, Science

Abstract

We consider the correction of errors from nucleotide sequences produced by next-generation targeted amplicon sequencing. The next-generation sequencing (NGS) platforms can provide a great deal of sequencing data thanks to their high throughput, but the associated error rates often tend to be high. Denoising in high-throughput sequencing has thus become a crucial process for boosting the reliability of downstream analyses. Our methodology, named DUDE-Seq, is derived from a general setting of reconstructing finite-valued source data corrupted by a discrete memoryless channel and effectively corrects substitution and homopolymer indel errors, the two major types of sequencing errors in most high-throughput targeted amplicon sequencing platforms. Our experimental studies with real and simulated datasets suggest that the proposed DUDE-Seq not only outperforms existing alternatives in terms of error-correction capability and time efficiency, but also boosts the reliability of downstream analyses. Further, the flexibility of DUDE-Seq enables its robust application to different sequencing platforms and analysis pipelines by simple updates of the noise model. DUDE-Seq is available at http://data.snu.ac.kr/pub/dude-seq.

Published

2017

3. Development and External Validation of the Korean Prostate Cancer Risk Calculator for High-Grade Prostate Cancer: Comparison with Two Western Risk Calculators in an Asian Cohort.

Author

Jae Young Park, Sungroh Yoon, Man Sik Park, Hoon Choi, Jae Hyun Bae, Du Geon Moon, Sung Kyu Hong, Sang Eun Lee, Chanwang Park, and Seok-Soo Byun

Subjects

Medicine, Science

Abstract

We developed the Korean Prostate Cancer Risk Calculator for High-Grade Prostate Cancer (KPCRC-HG) that predicts the probability of prostate cancer (PC) of Gleason score 7 or higher at the initial prostate biopsy in a Korean cohort (http://acl.snu.ac.kr/PCRC/RISC/). In addition, KPCRC-HG was validated and compared with internet-based Western risk calculators in a validation cohort.Using a logistic regression model, KPCRC-HG was developed based on the data from 602 previously unscreened Korean men who underwent initial prostate biopsies. Using 2,313 cases in a validation cohort, KPCRC-HG was compared with the European Randomized Study of Screening for PC Risk Calculator for high-grade cancer (ERSPCRC-HG) and the Prostate Cancer Prevention Trial Risk Calculator 2.0 for high-grade cancer (PCPTRC-HG). The predictive accuracy was assessed using the area under the receiver operating characteristic curve (AUC) and calibration plots.PC was detected in 172 (28.6%) men, 120 (19.9%) of whom had PC of Gleason score 7 or higher. Independent predictors included prostate-specific antigen levels, digital rectal examination findings, transrectal ultrasound findings, and prostate volume. The AUC of the KPCRC-HG (0.84) was higher than that of the PCPTRC-HG (0.79, p

Published

2017

4. The use of exome genotyping to predict pathological Gleason score upgrade after radical prostatectomy in low-risk prostate cancer patients.

Author

Jong Jin Oh, Seunghyun Park, Sang Eun Lee, Sung Kyu Hong, Sangchul Lee, Gheeyoung Choe, Sungroh Yoon, and Seok-Soo Byun

Subjects

Medicine, Science

Abstract

Active surveillance (AS) is a promising option for patients with low-risk prostate cancer (PCa), however current criteria could not select the patients correctly, many patients who fulfilled recent AS criteria experienced pathological Gleason score upgrade (PGU) after radical prostatectomy (RP). In this study, we aimed to develop an accurate model for predicting PGU among low-risk PCa patients by using exome genotyping.We genotyped 242,221 single nucleotide polymorphisms (SNP)s on a custom HumanExome BeadChip v1.0 (Illuminam Inc.) in blood DNA from 257 low risk PCa patients (PSA

Published

2014

5. Entropy-based analysis and bioinformatics-inspired integration of global economic information transfer.

Author

Jinkyu Kim, Gunn Kim, Sungbae An, Young-Kyun Kwon, and Sungroh Yoon

Subjects

Medicine, Science

Abstract

The assessment of information transfer in the global economic network helps to understand the current environment and the outlook of an economy. Most approaches on global networks extract information transfer based mainly on a single variable. This paper establishes an entirely new bioinformatics-inspired approach to integrating information transfer derived from multiple variables and develops an international economic network accordingly. In the proposed methodology, we first construct the transfer entropies (TEs) between various intra- and inter-country pairs of economic time series variables, test their significances, and then use a weighted sum approach to aggregate information captured in each TE. Through a simulation study, the new method is shown to deliver better information integration compared to existing integration methods in that it can be applied even when intra-country variables are correlated. Empirical investigation with the real world data reveals that Western countries are more influential in the global economic network and that Japan has become less influential following the Asian currency crisis.

Published

2013

6. Protein transfer learning improves identification of heat shock protein families

Author

Sungroh Yoon, Byunghan Lee, Seonwoo Min, and Hyun-Gi Kim

Subjects

Computer science, Inference, Protein Sequencing, computer.software_genre, Biochemistry, 01 natural sciences, Convolutional neural network, Heat Shock Response, Machine Learning, Heat-Shock Proteins, Cellular Stress Responses, 0303 health sciences, Multidisciplinary, Applied Mathematics, Simulation and Modeling, Protein transfer, Protein Transport, Identification (information), Amino acid composition, Cell Processes, Physical Sciences, Medicine, Algorithms, Research Article, Computer and Information Sciences, Science, Research and Analysis Methods, Machine learning, Machine Learning Algorithms, 03 medical and health sciences, Deep Learning, Artificial Intelligence, Support Vector Machines, Heat shock protein, Humans, Amino Acid Sequence, Molecular Biology Techniques, Sequencing Techniques, Molecular Biology, 030304 developmental biology, business.industry, Deep learning, 010401 analytical chemistry, Biology and Life Sciences, Proteins, Computational Biology, Cell Biology, Chaperone Proteins, 0104 chemical sciences, Data redundancy, Neural Networks, Computer, Artificial intelligence, business, computer, Mathematics, Molecular Chaperones

Abstract

Heat shock proteins (HSPs) play a pivotal role as molecular chaperones against unfavorable conditions. Although HSPs are of great importance, their computational identification remains a significant challenge. Previous studies have two major limitations. First, they relied heavily on amino acid composition features, which inevitably limited their prediction performance. Second, their prediction performance was overestimated because of the independent two-stage evaluations and train-test data redundancy. To overcome these limitations, we introduce two novel deep learning algorithms: (1) time-efficient DeepHSP and (2) high-performance DeeperHSP. We propose a convolutional neural network (CNN)-based DeepHSP that classifies both non-HSPs and six HSP families simultaneously. It outperforms state-of-the-art algorithms, despite taking 14–15 times less time for both training and inference. We further improve the performance of DeepHSP by taking advantage of protein transfer learning. While DeepHSP is trained on raw protein sequences, DeeperHSP is trained on top of pre-trained protein representations. Therefore, DeeperHSP remarkably outperforms state-of-the-art algorithms increasing F1 scores in both cross-validation and independent test experiments by 20% and 10%, respectively. We envision that the proposed algorithms can provide a proteome-wide prediction of HSPs and help in various downstream analyses for pathology and clinical research.

Published

2021

7. Entropy-based analysis and bioinformatics-inspired integration of global economic information transfer

Author

Sungroh Yoon, Young-Kyun Kwon, Jinkyu Kim, Sungbae An, and Gunn Kim

Subjects

Information transfer, Economics, Economic Models, Spatial Economic Analysis, lcsh:Medicine, Economic Geography, Social and Behavioral Sciences, Bioinformatics, Engineering, Germany, Global network, Data Mining, Entropy (information theory), Computer Simulation, Time series, lcsh:Science, Physics, Models, Statistical, Multidisciplinary, Data collection, Geography, Data Collection, Statistics, lcsh:R, Information processing, Computational Biology, Currency crisis, Models, Economic, Italy, Data Interpretation, Statistical, Computer Science, Signal Processing, Earth Sciences, lcsh:Q, Economic Development, Information Technology, Algorithms, Mathematics, Research Article, Information integration

Abstract

The assessment of information transfer in the global economic network helps to understand the current environment and the outlook of an economy. Most approaches on global networks extract information transfer based mainly on a single variable. This paper establishes an entirely new bioinformatics-inspired approach to integrating information transfer derived from multiple variables and develops an international economic network accordingly. In the proposed methodology, we first construct the transfer entropies (TEs) between various intra- and inter-country pairs of economic time series variables, test their significances, and then use a weighted sum approach to aggregate information captured in each TE. Through a simulation study, the new method is shown to deliver better information integration compared to existing integration methods in that it can be applied even when intra-country variables are correlated. Empirical investigation with the real world data reveals that Western countries are more influential in the global economic network and that Japan has become less influential following the Asian currency crisis.

Published

2013