Your search keyword '"Xiaobai Zhang"' showing total 3 results

1. TFPP: An SVM-Based Tool for Recognizing Flagellar Proteins in Trypanosoma brucei

Author

Yun Wang, Cizhong Jiang, Yi Tian, Guitao Ding, Bing Li, Xiaobai Zhang, Yuefeng Shen, and Zhenping Liu

Subjects

Support Vector Machine, Proteome, Protozoan Proteins, lcsh:Medicine, Gene Expression, Protozoology, Transcriptomes, Protein sequencing, Gene expression, Molecular Cell Biology, lcsh:Science, Multidisciplinary, biology, Gene Ontologies, Genomics, Cellular Structures, Cell biology, Cell Motility, Infectious Diseases, Flagella, Medicine, Research Article, Neglected Tropical Diseases, Trypanosoma, Trypanosoma brucei brucei, Biophysics, Trypanosoma brucei, Flagellum, Microbiology, African Trypanosomiasis, Host-Parasite Interactions, Genome Analysis Tools, Parasitic Diseases, Animals, Humans, Biology, Parasitic life cycles, Internet, lcsh:R, Computational Biology, Reproducibility of Results, Flagellar Motility, biology.organism_classification, Trypanosomiasis, African, Membrane protein, Subcellular Organelles, Parastic Protozoans, lcsh:Q, Function (biology)

Abstract

Trypanosoma brucei is a unicellular flagellated eukaryotic parasite that causes African trypanosomiasis in human and domestic animals with devastating health and economic consequences. Recent studies have revealed the important roles of the single flagellum of T. brucei in many aspects, especially that the flagellar motility is required for the viability of the bloodstream form T. brucei, suggesting that impairment of the flagellar function may provide a promising cure for African sleeping sickness. Knowing the flagellum proteome is crucial to study the molecular mechanism of the flagellar functions. Here we present a novel computational method for identifying flagellar proteins in T. brucei, called trypanosome flagellar protein predictor (TFPP). TFPP was developed based on a list of selected discriminating features derived from protein sequences, and could predict flagellar proteins with ∼92% specificity at a ∼84% sensitivity rate. Applied to the whole T. brucei proteome, TFPP reveals 811 more flagellar proteins with high confidence, suggesting that the flagellar proteome covers ∼10% of the whole proteome. Comparison of the expression profiles of the whole T. brucei proteome at three typical life cycle stages found that ∼45% of the flagellar proteins were significantly changed in expression levels between the three life cycle stages, indicating life cycle stage-specific regulation of flagellar functions in T. brucei. Overall, our study demonstrated that TFPP is highly effective in identifying flagellar proteins and could provide opportunities to study the trypanosome flagellar proteome systematically. Furthermore, the web server for TFPP can be freely accessed at http:/wukong.tongji.edu.cn/tfpp.

Published

2013

2. TFPP: An SVM-Based Tool for Recognizing Flagellar Proteins in Trypanosoma brucei.

Author

Xiaobai Zhang, Yuefeng Shen, Guitao Ding, Yi Tian, Zhenping Liu, Bing Li, Yun Wang, and Cizhong Jiang

Subjects

*TRYPANOSOMA brucei, *AFRICAN trypanosomiasis, *FLAGELLA (Microbiology), *AMINO acid sequence, *PROTEIN research, *EUKARYOTES

Abstract

Trypanosoma brucei is a unicellular flagellated eukaryotic parasite that causes African trypanosomiasis in human and domestic animals with devastating health and economic consequences. Recent studies have revealed the important roles of the single flagellum of T. brucei in many aspects, especially that the flagellar motility is required for the viability of the bloodstream form T. brucei, suggesting that impairment of the flagellar function may provide a promising cure for African sleeping sickness. Knowing the flagellum proteome is crucial to study the molecular mechanism of the flagellar functions. Here we present a novel computational method for identifying flagellar proteins in T. brucei, called trypanosome flagellar protein predictor (TFPP). TFPP was developed based on a list of selected discriminating features derived from protein sequences, and could predict flagellar proteins with ,92% specificity at a ,84% sensitivity rate. Applied to the whole T. brucei proteome, TFPP reveals 811 more flagellar proteins with high confidence, suggesting that the flagellar proteome covers ,10% of the whole proteome. Comparison of the expression profiles of the whole T. brucei proteome at three typical life cycle stages found that ,45% of the flagellar proteins were significantly changed in expression levels between the three life cycle stages, indicating life cycle stage-specific regulation of flagellar functions in T. brucei. Overall, our study demonstrated that TFPP is highly effective in identifying flagellar proteins and could provide opportunities to study the trypanosome flagellar proteome systematically. Furthermore, the web server for TFPP can be freely accessed at http:/ wukong.tongji.edu.cn/tfpp. [ABSTRACT FROM AUTHOR]

Published

2013

3. SProtP: A Web Server to Recognize Those Short-Lived Proteins Based on Sequence-Derived Features in Human Cells.

Author

Xiaofeng Song, Tao Zhou, Hao Jia, Xuejiang Guo, Xiaobai Zhang, Ping Han, and Jiahao Sha

Subjects

CELL cycle, BIOMOLECULES, CELLS, MICROBIAL genetics, PROTEINS

Abstract

Protein turnover metabolism plays important roles in cell cycle progression, signal transduction, and differentiation. Those proteins with short half-lives are involved in various regulatory processes. To better understand the regulation of cell process, it is important to study the key sequence-derived factors affecting short-lived protein degradation. Until now, most of protein half-lives are still unknown due to the difficulties of traditional experimental methods in measuring protein halflives in human cells. To investigate the molecular determinants that affect short-lived proteins, a computational method was proposed in this work to recognize short-lived proteins based on sequence-derived features in human cells. In this study, we have systematically analyzed many features that perhaps correlated with short-lived protein degradation. It is found that a large fraction of proteins with signal peptides and transmembrane regions in human cells are of short half-lives. We have constructed an SVM-based classifier to recognize short-lived proteins, due to the fact that short-lived proteins play pivotal roles in the control of various cellular processes. By employing the SVM model on human dataset, we achieved 80.8% average sensitivity and 79.8% average specificity, respectively, on ten testing dataset (TE1-TE10). We also obtained 89.9%, 99% and 83.9% of average accuracy on an independent validation datasets iTE1, iTE2 and iTE3 respectively. The approach proposed in this paper provides a valuable alternative for recognizing the short-lived proteins in human cells, and is more accurate than the traditional N-end rule. Furthermore, the web server SProtP (http://reprod.njmu.edu.cn/sprotp) has been developed and is freely available for users. [ABSTRACT FROM AUTHOR]

Published

2011