Analyzing and identifying novel B cell epitopes within Toxoplasma gondii GRA4
BACKGROUND: The identification of specific epitopes targeted by the host antibody response is important for understanding the natural response to infection and for the development of epitope-based marker vaccines and diagnostic tools for toxoplasmosis. In this study, Toxoplasma gondii GRA4 epitopes...
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| Vydáno v: | Parasites & vectors Ročník 7; číslo 1; s. 474 |
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Springer-Verlag
10.10.2014
BioMed Central BioMed Central Ltd Springer Nature B.V BMC |
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| Abstract | BACKGROUND: The identification of specific epitopes targeted by the host antibody response is important for understanding the natural response to infection and for the development of epitope-based marker vaccines and diagnostic tools for toxoplasmosis. In this study, Toxoplasma gondii GRA4 epitopes were identified using software-based prediction and a synthetic peptide technique. METHODS: The complete GRA4 gene sequence was obtained from T. gondii of the Gansu Jingtai strain of tachyzoites. The potential B cell epitopes of GRA4 was predicted using the PROTEAN subroutine in the DNASTAR software package. The peptides with good hydrophilicity, high accessibility, high flexibility and strong antigenicity were chemically synthesized and assessed by ELISA using pig sera from different time points after infection. RESULTS: The potential B cell epitopes of GRA4 predicted by bioinformatics tools focused on six regions of GRA4, 52–77 aa, 93–112 aa, 127–157 aa, 178–201 aa, 223–252 aa and 314–333 aa. Eleven shorter peptides from the six regions were synthesized and assessed by ELISA using pig sera from different time points after infection. Three of the eleven peptides (amino acids 62–77, 233–252 and 314–333) tested were recognized by all sera. CONCLUSIONS: We precisely located the T. gondii GRA4 epitopes using pig sera collected at different time points after infection. The identified epitopes may be useful for additional studies of epitope-based vaccines and diagnostic reagents. |
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| AbstractList | The identification of specific epitopes targeted by the host antibody response is important for understanding the natural response to infection and for the development of epitope-based marker vaccines and diagnostic tools for toxoplasmosis. In this study, Toxoplasma gondii GRA4 epitopes were identified using software-based prediction and a synthetic peptide technique. The complete GRA4 gene sequence was obtained from T. gondii of the Gansu Jingtai strain of tachyzoites. The potential B cell epitopes of GRA4 was predicted using the PROTEAN subroutine in the DNASTAR software package. The peptides with good hydrophilicity, high accessibility, high flexibility and strong antigenicity were chemically synthesized and assessed by ELISA using pig sera from different time points after infection. The potential B cell epitopes of GRA4 predicted by bioinformatics tools focused on six regions of GRA4, 52-77 aa, 93-112 aa, 127-157 aa, 178-201 aa, 223-252 aa and 314-333 aa. Eleven shorter peptides from the six regions were synthesized and assessed by ELISA using pig sera from different time points after infection. Three of the eleven peptides (amino acids 62-77, 233-252 and 314-333) tested were recognized by all sera. We precisely located the T. gondii GRA4 epitopes using pig sera collected at different time points after infection. The identified epitopes may be useful for additional studies of epitope-based vaccines and diagnostic reagents. BACKGROUND: The identification of specific epitopes targeted by the host antibody response is important for understanding the natural response to infection and for the development of epitope-based marker vaccines and diagnostic tools for toxoplasmosis. In this study, Toxoplasma gondii GRA4 epitopes were identified using software-based prediction and a synthetic peptide technique. METHODS: The complete GRA4 gene sequence was obtained from T. gondii of the Gansu Jingtai strain of tachyzoites. The potential B cell epitopes of GRA4 was predicted using the PROTEAN subroutine in the DNASTAR software package. The peptides with good hydrophilicity, high accessibility, high flexibility and strong antigenicity were chemically synthesized and assessed by ELISA using pig sera from different time points after infection. RESULTS: The potential B cell epitopes of GRA4 predicted by bioinformatics tools focused on six regions of GRA4, 52–77 aa, 93–112 aa, 127–157 aa, 178–201 aa, 223–252 aa and 314–333 aa. Eleven shorter peptides from the six regions were synthesized and assessed by ELISA using pig sera from different time points after infection. Three of the eleven peptides (amino acids 62–77, 233–252 and 314–333) tested were recognized by all sera. CONCLUSIONS: We precisely located the T. gondii GRA4 epitopes using pig sera collected at different time points after infection. The identified epitopes may be useful for additional studies of epitope-based vaccines and diagnostic reagents. Doc number: 474 Abstract Background: The identification of specific epitopes targeted by the host antibody response is important for understanding the natural response to infection and for the development of epitope-based marker vaccines and diagnostic tools for toxoplasmosis. In this study, Toxoplasma gondii GRA4 epitopes were identified using software-based prediction and a synthetic peptide technique. Methods: The complete GRA4 gene sequence was obtained from T. gondii of the Gansu Jingtai strain of tachyzoites. The potential B cell epitopes of GRA4 was predicted using the PROTEAN subroutine in the DNASTAR software package. The peptides with good hydrophilicity, high accessibility, high flexibility and strong antigenicity were chemically synthesized and assessed by ELISA using pig sera from different time points after infection. Results: The potential B cell epitopes of GRA4 predicted by bioinformatics tools focused on six regions of GRA4, 52-77 aa, 93-112 aa, 127-157 aa, 178-201 aa, 223-252 aa and 314-333 aa. Eleven shorter peptides from the six regions were synthesized and assessed by ELISA using pig sera from different time points after infection. Three of the eleven peptides (amino acids 62-77, 233-252 and 314-333) tested were recognized by all sera. Conclusions: We precisely located the T. gondii GRA4 epitopes using pig sera collected at different time points after infection. The identified epitopes may be useful for additional studies of epitope-based vaccines and diagnostic reagents. Background The identification of specific epitopes targeted by the host antibody response is important for understanding the natural response to infection and for the development of epitope-based marker vaccines and diagnostic tools for toxoplasmosis. In this study, Toxoplasma gondii GRA4 epitopes were identified using software-based prediction and a synthetic peptide technique. Methods The complete GRA4 gene sequence was obtained from T. gondii of the Gansu Jingtai strain of tachyzoites. The potential B cell epitopes of GRA4 was predicted using the PROTEAN subroutine in the DNASTAR software package. The peptides with good hydrophilicity, high accessibility, high flexibility and strong antigenicity were chemically synthesized and assessed by ELISA using pig sera from different time points after infection. Results The potential B cell epitopes of GRA4 predicted by bioinformatics tools focused on six regions of GRA4, 52-77 aa, 93-112 aa, 127-157 aa, 178-201 aa, 223-252 aa and 314-333 aa. Eleven shorter peptides from the six regions were synthesized and assessed by ELISA using pig sera from different time points after infection. Three of the eleven peptides (amino acids 62-77, 233-252 and 314-333) tested were recognized by all sera. Conclusions We precisely located the T. gondii GRA4 epitopes using pig sera collected at different time points after infection. The identified epitopes may be useful for additional studies of epitope-based vaccines and diagnostic reagents. Keywords: Toxoplasma gondii, GRA4, Epitope, Pig antibodies Background The identification of specific epitopes targeted by the host antibody response is important for understanding the natural response to infection and for the development of epitope-based marker vaccines and diagnostic tools for toxoplasmosis. In this study, Toxoplasma gondii GRA4 epitopes were identified using software-based prediction and a synthetic peptide technique. Methods The complete GRA4 gene sequence was obtained from T. gondii of the Gansu Jingtai strain of tachyzoites. The potential B cell epitopes of GRA4 was predicted using the PROTEAN subroutine in the DNASTAR software package. The peptides with good hydrophilicity, high accessibility, high flexibility and strong antigenicity were chemically synthesized and assessed by ELISA using pig sera from different time points after infection. Results The potential B cell epitopes of GRA4 predicted by bioinformatics tools focused on six regions of GRA4, 52-77 aa, 93-112 aa, 127-157 aa, 178-201 aa, 223-252 aa and 314-333 aa. Eleven shorter peptides from the six regions were synthesized and assessed by ELISA using pig sera from different time points after infection. Three of the eleven peptides (amino acids 62-77, 233-252 and 314-333) tested were recognized by all sera. Conclusions We precisely located the T. gondii GRA4 epitopes using pig sera collected at different time points after infection. The identified epitopes may be useful for additional studies of epitope-based vaccines and diagnostic reagents. The identification of specific epitopes targeted by the host antibody response is important for understanding the natural response to infection and for the development of epitope-based marker vaccines and diagnostic tools for toxoplasmosis. In this study, Toxoplasma gondii GRA4 epitopes were identified using software-based prediction and a synthetic peptide technique. The complete GRA4 gene sequence was obtained from T. gondii of the Gansu Jingtai strain of tachyzoites. The potential B cell epitopes of GRA4 was predicted using the PROTEAN subroutine in the DNASTAR software package. The peptides with good hydrophilicity, high accessibility, high flexibility and strong antigenicity were chemically synthesized and assessed by ELISA using pig sera from different time points after infection. The potential B cell epitopes of GRA4 predicted by bioinformatics tools focused on six regions of GRA4, 52-77 aa, 93-112 aa, 127-157 aa, 178-201 aa, 223-252 aa and 314-333 aa. Eleven shorter peptides from the six regions were synthesized and assessed by ELISA using pig sera from different time points after infection. Three of the eleven peptides (amino acids 62-77, 233-252 and 314-333) tested were recognized by all sera. We precisely located the T. gondii GRA4 epitopes using pig sera collected at different time points after infection. The identified epitopes may be useful for additional studies of epitope-based vaccines and diagnostic reagents. The identification of specific epitopes targeted by the host antibody response is important for understanding the natural response to infection and for the development of epitope-based marker vaccines and diagnostic tools for toxoplasmosis. In this study, Toxoplasma gondii GRA4 epitopes were identified using software-based prediction and a synthetic peptide technique.BACKGROUNDThe identification of specific epitopes targeted by the host antibody response is important for understanding the natural response to infection and for the development of epitope-based marker vaccines and diagnostic tools for toxoplasmosis. In this study, Toxoplasma gondii GRA4 epitopes were identified using software-based prediction and a synthetic peptide technique.The complete GRA4 gene sequence was obtained from T. gondii of the Gansu Jingtai strain of tachyzoites. The potential B cell epitopes of GRA4 was predicted using the PROTEAN subroutine in the DNASTAR software package. The peptides with good hydrophilicity, high accessibility, high flexibility and strong antigenicity were chemically synthesized and assessed by ELISA using pig sera from different time points after infection.METHODSThe complete GRA4 gene sequence was obtained from T. gondii of the Gansu Jingtai strain of tachyzoites. The potential B cell epitopes of GRA4 was predicted using the PROTEAN subroutine in the DNASTAR software package. The peptides with good hydrophilicity, high accessibility, high flexibility and strong antigenicity were chemically synthesized and assessed by ELISA using pig sera from different time points after infection.The potential B cell epitopes of GRA4 predicted by bioinformatics tools focused on six regions of GRA4, 52-77 aa, 93-112 aa, 127-157 aa, 178-201 aa, 223-252 aa and 314-333 aa. Eleven shorter peptides from the six regions were synthesized and assessed by ELISA using pig sera from different time points after infection. Three of the eleven peptides (amino acids 62-77, 233-252 and 314-333) tested were recognized by all sera.RESULTSThe potential B cell epitopes of GRA4 predicted by bioinformatics tools focused on six regions of GRA4, 52-77 aa, 93-112 aa, 127-157 aa, 178-201 aa, 223-252 aa and 314-333 aa. Eleven shorter peptides from the six regions were synthesized and assessed by ELISA using pig sera from different time points after infection. Three of the eleven peptides (amino acids 62-77, 233-252 and 314-333) tested were recognized by all sera.We precisely located the T. gondii GRA4 epitopes using pig sera collected at different time points after infection. The identified epitopes may be useful for additional studies of epitope-based vaccines and diagnostic reagents.CONCLUSIONSWe precisely located the T. gondii GRA4 epitopes using pig sera collected at different time points after infection. The identified epitopes may be useful for additional studies of epitope-based vaccines and diagnostic reagents. Abstract Background The identification of specific epitopes targeted by the host antibody response is important for understanding the natural response to infection and for the development of epitope-based marker vaccines and diagnostic tools for toxoplasmosis. In this study, Toxoplasma gondii GRA4 epitopes were identified using software-based prediction and a synthetic peptide technique. Methods The complete GRA4 gene sequence was obtained from T. gondii of the Gansu Jingtai strain of tachyzoites. The potential B cell epitopes of GRA4 was predicted using the PROTEAN subroutine in the DNASTAR software package. The peptides with good hydrophilicity, high accessibility, high flexibility and strong antigenicity were chemically synthesized and assessed by ELISA using pig sera from different time points after infection. Results The potential B cell epitopes of GRA4 predicted by bioinformatics tools focused on six regions of GRA4, 52-77 aa, 93-112 aa, 127-157 aa, 178-201 aa, 223-252 aa and 314-333 aa. Eleven shorter peptides from the six regions were synthesized and assessed by ELISA using pig sera from different time points after infection. Three of the eleven peptides (amino acids 62-77, 233-252 and 314-333) tested were recognized by all sera. Conclusions We precisely located the T. gondii GRA4 epitopes using pig sera collected at different time points after infection. The identified epitopes may be useful for additional studies of epitope-based vaccines and diagnostic reagents. |
| ArticleNumber | 474 |
| Audience | Academic |
| Author | Wang, Guangxiang Yin, Hong Zhang, Delin Wang, Yanhua Ou, Jiangtao |
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| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/25301141$$D View this record in MEDLINE/PubMed |
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| PublicationTitle | Parasites & vectors |
| PublicationTitleAbbrev | Parasites Vectors |
| PublicationTitleAlternate | Parasit Vectors |
| PublicationYear | 2014 |
| Publisher | Springer-Verlag BioMed Central BioMed Central Ltd Springer Nature B.V BMC |
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| Snippet | BACKGROUND: The identification of specific epitopes targeted by the host antibody response is important for understanding the natural response to infection and... Background The identification of specific epitopes targeted by the host antibody response is important for understanding the natural response to infection and... The identification of specific epitopes targeted by the host antibody response is important for understanding the natural response to infection and for the... Background The identification of specific epitopes targeted by the host antibody response is important for understanding the natural response to infection and... Doc number: 474 Abstract Background: The identification of specific epitopes targeted by the host antibody response is important for understanding the natural... Background: The identification of specific epitopes targeted by the host antibody response is important for understanding the natural response to infection and... Abstract Background The identification of specific epitopes targeted by the host antibody response is important for understanding the natural response to... |
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| SubjectTerms | Amino Acid Sequence amino acids Analysis Antibodies Antibody Specificity Antigenic determinants Antigens Antigens, Protozoan bioinformatics Biomedical and Life Sciences Biomedicine China Computational Biology computer software Entomology Enzyme-Linked Immunosorbent Assay Epitope epitopes Epitopes, B-Lymphocyte - chemistry GRA4 Health aspects Hogs hydrophilicity Immune system Infectious Diseases nucleotide sequences Parasitology Peptides Pig antibodies prediction Protozoan Proteins - chemistry Protozoan Proteins - metabolism Software swine tachyzoites Toxoplasma - metabolism Toxoplasma gondii toxoplasmosis Tropical Medicine Vaccines Veterinary Medicine/Veterinary Science Viral antibodies Virology |
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| Title | Analyzing and identifying novel B cell epitopes within Toxoplasma gondii GRA4 |
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