Andreas Kuhn

Exploiting the Mutanome for Tumor Vaccination

Multiple genetic events and subsequent clonal evolution drive carcinogenesis, making disease elimination with single-targeted drugs difficult. The multiplicity of gene mutations derived from clonal heterogeneity therefore represents an ideal setting for multiepitope tumor vaccination. Here, we used next generation sequencing exome resequencing to identify 962 nonsynonymous somatic point mutations in B16F10 murine melanoma cells, with 563 of those mutations in expressed genes. Potential driver mutations occurred in classical tumor suppressor genes and genes involved in proto-oncogenic signaling pathways that control cell proliferation, adhesion, migration, and apoptosis. Aim1 and Trrap mutations known to be altered in human melanoma were included among those found. The immunogenicity and specificity of 50 validated mutations was determined by immunizing mice with long peptides encoding the mutated epitopes. One-third of these peptides were found to be immunogenic, with 60% in this group eliciting immune responses directed preferentially against the mutated sequence as compared with the wild-type sequence. In tumor transplant models, peptide immunization conferred in vivo tumor control in protective and therapeutic settings, thereby qualifying mutated epitopes that include single amino acid substitutions as effective vaccines. Together, our findings provide a comprehensive picture of the mutanome of B16F10 melanoma which is used widely in immunotherapy studies. In addition, they offer insight into the extent of the immunogenicity of nonsynonymous base substitution mutations. Lastly, they argue that the use of deep sequencing to systematically analyze immunogenicity mutations may pave the way for individualized immunotherapy of cancer patients.

Phosphorothioate cap analogs increase stability and translational efficiency of RNA vaccines in immature dendritic cells and induce superior immune responses in vivo

Vaccination with in vitro transcribed RNA coding for tumor antigens is considered a promising approach for cancer immunotherapy and has already entered human clinical testing. One of the basic objectives for development of RNA as a drug is the optimization of immunobioavailability of the encoded antigen in vivo. By analyzing the effect of different synthetic 5′ mRNA cap analogs on the kinetics of the encoded protein, we found that m27,2′−OGppSpG (β-S-ARCA) phosphorothioate caps, in particular the D1 diastereoisomer, profoundly enhance RNA stability and translational efficiency in immature but not mature dendritic cells. Moreover, in vivo delivery of the antigen as β-S-ARCA(D1)-capped RNA species is superior for protein expression and for efficient priming and expansion of naïve antigen-specific T cells in mice. Our findings establish 5′ mRNA cap analogs as yet another module for tuning immunopharmacological properties of recombinant antigen-encoding RNA for vaccination purposes.

mRNA as a Versatile Tool for Exogenous Protein Expression

Several viral and non-viral vectors have been developed for exogenous protein expression in specific cells. Conventionally, this purpose is achieved through the use of recombinant DNA. But mainly due to the risks associated with permanent genetic alteration of cells, safety and ethical concerns have been raised for the use of DNA-based vectors in human clinical therapy. In the last years, synthetic messenger RNA has emerged as powerful tool to deliver genetic information. RNA vectors exhibit several advantages compared to DNA and are particularly interesting for applications that require transient gene expression. RNA stability and translation efficiency can be increased by cis-acting structural elements in the RNA such as the 5-cap, the poly(A)-tail, untranslated regions and the sequence of the coding region. Here we review recent developments in the optimization of messenger RNA as vector for modulation of protein expression emphasizing on stability, transfection and immunogenicity. In addition, we summarize current pre-clinical and clinical studies using RNA-based vectors for immunotherapy, T cell, stem cell as well as gene therapy.

Determinants of intracellular RNA pharmacokinetics: Implications for RNA-based immunotherapeutics.

RNAs with optimized properties are increasingly investigated as a tool to deliver the genetic information of complete antigens into professional antigen-presenting dendritic cells for HLA haplotype-independent antigen-specific vaccination against cancer. As the dose of the antigen and duration of its presentation are critical factors for generating strong and sustained antigen-specific immune responses, improvement of the immunobioavailability of RNA-based vaccines has been a recurrent subject of research. Substantial increase of the amount of antigen produced from RNA can be achieved by optimizing RNA stability and translational efficiency. Both features are determined by cis-acting elements in the RNA, namely the 5’ cap, the poly(A) tail, and the sequence of the coding and non-coding regions, which interact with corresponding trans-acting factors. This article summarizes recent developments in identifying optimized RNA for expression of foreign proteins in dendritic cells, as well as their implications for immunotherapy based on antigen-encoding RNA.

The synthesis of isopropylidene mRNA cap analogs modified with phosphorothioate moiety and their evaluation as promoters of mRNA translation.

Synthetic mRNA cap analogs are valuable tools in the preparation of modified mRNA transcripts with improved translational activity and increased cellular stability, and have recently attracted more attention because of their great potential in therapeutic applications. We have synthesized and tested isopropylidene dinucleotide cap analogs bearing a phosphorothioate group at the β position of the 5,5-triphosphate bridge (two diastereomers of 2,3-iPr-m(7)GppSpG), as synthetically simpler alternatives to previously obtained phosphorothioate cap analogs. To evaluate the utility of the new compounds in biological systems we determined their affinity to translation initiation factor 4E (eIF4E), and tested their translational properties in rabbit reticulocyte lysates (RRL) and in human immature dendritic cells (hiDCs). In order to explain the properties of isopropylidene analogs we performed (1)H NMR conformational analysis and correlated the absolute configuration at the β-phosphorous atom with previously synthesized m(7)GppSpG.

Generation of TCR-Engineered T Cells and Their Use To Control the Performance of T Cell Assays

The systematic assessment of the human immune system bears huge potential to guide rational development of novel immunotherapies and clinical decision making. Multiple assays to monitor the quantity, phenotype, and function of Ag-specific T cells are commonly used to unravel patients’ immune signatures in various disease settings and during therapeutic interventions. When compared with tests measuring soluble analytes, cellular immune assays have a higher variation, which is a major technical factor limiting their broad adoption in clinical immunology. The key solution may arise from continuous control of assay performance using TCR-engineered reference samples. We developed a simple, stable, robust, and scalable technology to generate reference samples that contain defined numbers of functional Ag-specific T cells. First, we show that RNA-engineered lymphocytes, equipped with selected TCRs, can repetitively deliver functional readouts of a controlled size across multiple assay platforms. We further describe a concept for the application of TCR-engineered reference samples to keep assay performance within or across institutions under tight control. Finally, we provide evidence that these novel control reagents can sensitively detect assay variation resulting from typical sources of error, such as low cell quality, loss of reagent stability, suboptimal hardware settings, or inaccurate gating.