On April 10, 2021 SQZ Biotechnologies (NYSE: SQZ), a cell therapy company developing novel treatments for multiple therapeutic areas, reported preclinical data from its next generation SQZ APCs, enhanced APCs or eAPCs, and the potentially broader applicability of the platform at the American Association for Cancer Research (AACR) (Free AACR Whitepaper) 2021 Annual Meeting (Press release, SQZ Biotech, APR 10, 2021, View Source [SID1234577860]).

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"One of the advantages of the Cell Squeeze technology is the ability to simultaneously engineer multiple functions in cells, the underpinning of our SQZ eAPC program. With this next generation program, we are aiming to achieve the benefits of combination therapies that can drive powerful immune responses within a single multiplexed cell therapy," said Howard Bernstein, MD, PhD, chief scientific officer of SQZ. "Our vision is to incorporate additional functionality and new antigens to the foundation we are establishing with our lead SQZ APC program. The eAPC and KRAS data presented at AACR (Free AACR Whitepaper) provide preclinical examples of how we could potentially extend our impact across indications and help more patients."

SQZ eAPCs build on the power of the SQZ APC platform, which is focused on producing robust and specific CD8 T cell activation through efficient MHC-I antigen presentation. By delivering multiple mRNA into cells in a single squeeze, SQZ eAPCs are designed to further enhance T cell stimulation and boost immune-signaling that would otherwise require combinations with additional immune-oncology agents. In addition, the mRNA-based cargo facilitates presentation of a broader range of tumor epitopes, which could expand the addressable HPV+ patient population. The eAPC platform offers the opportunity for application across oncology and infectious diseases.

Highlights from the SQZ eAPC preclinical data shared at AACR (Free AACR Whitepaper) (Posters 1525 and 2626) include:

Enhancement of the quality and quantity of CD8 T cell activation by SQZ eAPCs through incorporation of CD86, membrane bound IL-2 (mbIL-2), and membrane bound IL-12 (mbIL-12), leveraging multiplexed delivery of mRNAs encoding each component
mbIL-2 and mbIL-12 mRNA delivery via Cell Squeeze led to surface expression of the cytokines in all measured human PBMC subsets (B cells, T cells, NK cells, and monocytes) and resulted in functional IL-2 and IL-12 signaling
CD86, mbIL-2, and mbIL-12 mRNA delivered alone or in combination increased antigen-specific CD8 T cell responses as much as ten-fold
Multiplexing CMVpp65 and influenza M1 mRNA antigens with signal 2/3 mRNAs enhanced the potency of SQZ APCs – inducing stronger antigen-specific CD8 T cell responses for infectious disease
Co-squeezing E6 and E7 mRNAs drove antigen-specific CD8 T cell activation regardless of HLA haplotype, which could significantly broaden the addressable HPV+ patient population and potentially eliminate the need for HLA screening
Cell Squeeze mRNA delivery stimulated memory CD8 T cells across various antigens and HLA haplotypes
SQZ is leveraging the cargo flexibility of its Cell Squeeze technology to pursue additional tumor targets. SQZ APCs have demonstrated the ability to elicit specific KRAS G12D and G12V CD8+ T cell responses in both animal models and in human cells.

Highlights from the SQZ-APC-KRAS preclinical data shared at AACR (Free AACR Whitepaper) (Poster 1524) include:

SQZ APCs engineered with KRas G12D and G12V peptides, both alone and multiplexed, generated specific and robust CD8 T cell responses against the target mutations
KRAS G12D and G12V make up over half of all KRAS mutations, with approximately 100,000 patients per year having KRAS G12D or G12V mutated cancers in the United States