Computational Immunology Tools
- EpiMatrix
- ClustiMer
- Conservatrix
- EpiAssembler
- BlastiMer
- Vaccine CAD
In silico Technologies
The Epimatrix System
The original EpiMatrix algorithms and coefficient sets were developed at Brown University’s TB/HIV Research lab. In 1999 the EpiMatrix toolset was exclusively licensed to EpiVax. Since that time the predictive algorithms and coefficient sets that make up the EpiMatrix toolset have been significantly revised and extended. At present we can predict against over 100 different MHC Class I and Class II alleles.Scalable Performance
The EpiMatrix System was designed from the start as a commercial system. The core of the EpiMatrix System is an Oracle database used to store input protein sequences and analytical outputs. By contrast many of the web based predictive services that are available simply deliver result sets to a web browser providing no data management capabilities. By designing the EpiMatrix applications around a shared core database we have developed a high throughput environment where the results of preliminary analyses can easily be passed as input to subsequent analytical and reporting applications.
Searching for Putative T cell Epitopes: EpiMatrix
In a typical EpiMatrix analysis the target protein sequence is parsed into overlapping 9-mer frames where each frame overlaps the last by 8 amino acids. Each of the derived 9-mer frames is then screened for predicted affinity against a panel of MHC Class I and/or Class II alleles. Raw scores are normalized before being reported. The resulting Z-scores fall on a common scale that can be directly compared across HLA alleles. In our experience Z-scores above 1.64 (approximately the top 5% of all 9-mers derived from any given protein) have a significant chance of binding to MHC molecules and scores above 2.32 (approximately the top 1% of all 9-mers derived from any given protein) are highly likely to bind to MHC molecules. The ability to rate putative epitopes on a common scale, an exclusive feature of the EpiMatrix System, greatly simplifies the process of selecting putative epitopes for in-vitro testing.
Finding Epitope Clusters: ClustiMer
We have observed that MHC Class II restricted T cell epitopes tend to co-locate in short well-defined regions within protein sequences. The ClustiMer algorithm reads EpiMatrix results sets and identifies regions (typically 15 to 25 amino acids in length) that contain significantly more predicted T cell epitopes than we would expect to find by chance alone. We refer to these regions as T cell epitope “clusters.” In our experience these clustered regions are highly likely to contain promiscuous T cell epitopes (i.e. epitopes that can bind to more than one HLA allele). Because they can interact with multiple HLA alleles T cell epitope clusters are important drivers of adaptive immune response. In a vaccine context these short amino acid sequences can be used as either priming antigens or as boosting adjuvants. In a deimmunization context T cell epitope clusters are high value targets, areas where a small number of amino acids substitutions can have a large impact on immunogenicity.
Homology Searching: BlastiMer
We have also developed automated Blast tools capable of Blasting protein sequences, cluster sequences or even individual 9-mer peptides against the either the non-redundant protein database at Genbank, the patent database at Genbank, or our own proprietary database of known ligands and T cell epitopes. Stored Blast results can be displayed as alignments or in a summarized form. Identifying homologies can help to focus your design efforts. For example human like peptides may make poor vaccine components since matching T cells are likely to have been either deleted or anergized. In the deimmunization context identifying natural variation may help to identify substitutions that are well tolerated.
Protein Deimmunization: OptiMatrix
Once a T cell epitope cluster has been identified it is necessary to devise a strategy for deimmunization. We start by identifying those individual amino acids that contribute the most to binding affinity across peptide frames and HLA alleles. We believe changes in these “sensitive” amino acids can have a disproportional impact on the immunogenicity of the underlying sequence. Once we have identified a set of target amino acids we develop a set of viable replacements amino acids. We review and consider many inputs when compiling this list. We may look at the Blast Summary report (described above) to identify changes tolerated in other species or variants of the target protein. We may develop a 3d model of the target protein and screen a set of deimmunizing changes for low impact alternatives. We also weigh carefully any input our clients can provide. With a list of targeted amino acids and viable alternatives in hand we can run our protein deimmunization algorithm, PickaMer. The PickaMer algorithm will try every possible alternative sequence and list the best single amino acid changes, the best double changes, the best triple changes, and, if necessary, even more complex changes. The deimmunized sequences suggested by PickaMer can then be validated in-vitro (see below) before being integrated into the target protein and tested for functionality.
Finding Conserved Epitopes: Conservatrix
In developing vaccines against highly variable targets such as HIV or HPV it is important to identify T cell epitopes that are conserved across multiple stains of the target pathogen. High affinity epitopes that occur in just one or a few circulating stains make poor vaccine components. Highly conserved T cell epitopes, on the other hand, are the Achilles heel of the target pathogen, they can expose the target pathogen to a vaccine induced immune response.
VaccineCAD
VaccineCAD (Vaccine Computer-Assisted Design) is a recently developed algorithm that permits in silico vaccine design. The alignment of epitopes in a vaccine construct may result in the development of "nonsenses" epitopes at the junctions between epitopes, or pseudoepitopes. One means of reducing the potential for junctional immunogenicity is to order epitopes so as to diminish the likelihood that an MHC binder will be created from the tail of one epitope and the beginning of another. Another means of reducing junctional immunogenicity is to insert spacer sequences between the epitopes that also reduce the likelihood that a pseudoepitope will be created. VaccineCAD iteratively reorders epitopes so as to maximally reduce junctional immunogenicity and also introduces spacers where necessary.In vitro Technologies
At EpiVax we use MHC binding assays to confirm that the peptides identified by the EpiMatrix System are true HLA ligands. Our binding assays utilize recombinant, soluble MHC molecules and time resolved flourescence for the highest sensitivity and the lowest background available on the market. We can perform HLA binding assays for the most common Class I and Class II alleles.
We are experienced with many cell based assays including several assays based on either ELISA or ELISpot technologies. These assays are particularly usefulfor monitoring T cell activation and proliferation. Cell mediated and antibody directed cytotoxicity assays can be used to assess the function of epitopes, vaccine constructs, and therapeutic proteins.
In vivo Technologies