Automated protein-protein structure prediction of the T cell receptor-peptide major histocompatibility complex
The T Cell Receptor (TCR) recognition of a peptide-major histocompatibility complex (pMHC) is a crucial component of the adaptive immune response. The identification of TCR-pMHC pairs is a significant bottleneck in the implementation of TCR immunotherapies and may be augmented by computational metho...
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| creator | Rollins, Zachary Curtis, Matthew George, Steven Faller, Roland |
| description | The T Cell Receptor (TCR) recognition of a peptide-major
histocompatibility complex (pMHC) is a crucial component of the adaptive
immune response. The identification of TCR-pMHC pairs is a significant
bottleneck in the implementation of TCR immunotherapies and may be
augmented by computational methodologies that accelerate the rate of TCR
discovery. The ability to computationally design TCRs to a target pMHC
will require an automated integration of next-generation sequencing,
homology modeling, molecular dynamics (MD), and TCR ranking. We present a
generic pipeline to evaluate patient-specific, sequence-based TCRs to a
target pMHC. The most expressed TCRs from 16 colorectal cancer patients
are homology modeled to target the CEA peptide using Modeller and
ColabFold. Then, these TCR-pMHC structures are compared by performing an
automated molecular dynamics equilibration. We find that Colabfold
generates starting configurations that require, on average, an ~2.5X
reduction in simulation time to equilibrate TCR-pMHC structures compared
to Modeller. In addition, there are differences between equilibrated
structures generated by Modeller and ColabFold. Moreover, we identify TCR
ranking criteria that may be used to prioritize TCRs for evaluation of in
vitro immunogenicity. |
| doi_str_mv | 10.25338/b83s70 |
| format | Dataset |
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histocompatibility complex (pMHC) is a crucial component of the adaptive
immune response. The identification of TCR-pMHC pairs is a significant
bottleneck in the implementation of TCR immunotherapies and may be
augmented by computational methodologies that accelerate the rate of TCR
discovery. The ability to computationally design TCRs to a target pMHC
will require an automated integration of next-generation sequencing,
homology modeling, molecular dynamics (MD), and TCR ranking. We present a
generic pipeline to evaluate patient-specific, sequence-based TCRs to a
target pMHC. The most expressed TCRs from 16 colorectal cancer patients
are homology modeled to target the CEA peptide using Modeller and
ColabFold. Then, these TCR-pMHC structures are compared by performing an
automated molecular dynamics equilibration. We find that Colabfold
generates starting configurations that require, on average, an ~2.5X
reduction in simulation time to equilibrate TCR-pMHC structures compared
to Modeller. In addition, there are differences between equilibrated
structures generated by Modeller and ColabFold. Moreover, we identify TCR
ranking criteria that may be used to prioritize TCRs for evaluation of in
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histocompatibility complex (pMHC) is a crucial component of the adaptive
immune response. The identification of TCR-pMHC pairs is a significant
bottleneck in the implementation of TCR immunotherapies and may be
augmented by computational methodologies that accelerate the rate of TCR
discovery. The ability to computationally design TCRs to a target pMHC
will require an automated integration of next-generation sequencing,
homology modeling, molecular dynamics (MD), and TCR ranking. We present a
generic pipeline to evaluate patient-specific, sequence-based TCRs to a
target pMHC. The most expressed TCRs from 16 colorectal cancer patients
are homology modeled to target the CEA peptide using Modeller and
ColabFold. Then, these TCR-pMHC structures are compared by performing an
automated molecular dynamics equilibration. We find that Colabfold
generates starting configurations that require, on average, an ~2.5X
reduction in simulation time to equilibrate TCR-pMHC structures compared
to Modeller. In addition, there are differences between equilibrated
structures generated by Modeller and ColabFold. Moreover, we identify TCR
ranking criteria that may be used to prioritize TCRs for evaluation of in
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histocompatibility complex (pMHC) is a crucial component of the adaptive
immune response. The identification of TCR-pMHC pairs is a significant
bottleneck in the implementation of TCR immunotherapies and may be
augmented by computational methodologies that accelerate the rate of TCR
discovery. The ability to computationally design TCRs to a target pMHC
will require an automated integration of next-generation sequencing,
homology modeling, molecular dynamics (MD), and TCR ranking. We present a
generic pipeline to evaluate patient-specific, sequence-based TCRs to a
target pMHC. The most expressed TCRs from 16 colorectal cancer patients
are homology modeled to target the CEA peptide using Modeller and
ColabFold. Then, these TCR-pMHC structures are compared by performing an
automated molecular dynamics equilibration. We find that Colabfold
generates starting configurations that require, on average, an ~2.5X
reduction in simulation time to equilibrate TCR-pMHC structures compared
to Modeller. In addition, there are differences between equilibrated
structures generated by Modeller and ColabFold. Moreover, we identify TCR
ranking criteria that may be used to prioritize TCRs for evaluation of in
vitro immunogenicity.</abstract><pub>Dryad</pub><doi>10.25338/b83s70</doi><orcidid>https://orcid.org/0000-0002-1087-5164</orcidid><oa>free_for_read</oa></addata></record> |
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| identifier | DOI: 10.25338/b83s70 |
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| source | DataCite |
| subjects | FOS: Nano-technology |
| title | Automated protein-protein structure prediction of the T cell receptor-peptide major histocompatibility complex |
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