SignificanceEx vivo manipulation of primary cells is critical to the success of this emerging generation of cell-based therapies, such as chimeric antigen receptor T cells for the treatment of cancer and CRISPR for the correction of developmental diseases. However, the limitations of existing delivery approaches may dramatically restrict the impact of genetic engineering to study and treat disease. In this paper, we compared electroporation to a microfluidic membrane deformation technique termed “squeezing” and found that squeezed cells had dramatically fewer side effects than electroporation and gene expression profiles similar to those of unmanipulated cells. The significant differences in outcomes from the two techniques underscores the importance of understanding the impact of intracellular delivery methods on cell function for research and clinical applications.
The extracellular matrix (ECM) of the human intervertebral disc is rich in molecules that interact with cells through integrin-mediated attachments. Porcine nucleus pulposus (NP) cells have been shown to interact with laminin (LM) isoforms LM-111 and LM-511 through select integrins that regulate biosynthesis and cell attachment. Since human NP cells lose many phenotypic characteristics with age, attachment and interaction with the ECM may be altered. Expression of LM-binding integrins was quantified for human NP cells using flow cytometry. The cell-ECM attachment mechanism was determined by quantifying cell attachment to LM-111, LM-511, or type II collagen after functionally blocking specific integrin subunits. Human NP cells express integrins β1, α3, and α5, with over 70% of cells positive for each subunit. Blocking subunit β1 inhibited NP cell attachment to all substrates. Blocking subunits α1, α2, α3 and α5 simultaneously, but not individually, inhibits NP cell attachment to laminins. While integrin α6β1 mediated porcine NP cell attachment to LM-111, we found integrins α3, α5, and β1 instead contributed to human NP cell attachment. These findings identify integrin subunits that may mediate interactions with the ECM for human NP cells and could be used to promote cell attachment, survival and biosynthesis in cell-based therapeutics.
Nucleus pulposus (NP) cells are derived from the notochord and differ from neighboring cells of the intervertebral disc in phenotypic marker expression and morphology. Adult human NP cells lose this phenotype and morphology with age in a pattern that contributes to progressive disc degeneration and pathology. Select laminin-mimetic peptide ligands and substrate stiffnesses were examined for their ability to regulate human NP cell phenotype and biosynthesis through the expression of NP-specific markers aggrecan, N-cadherin, collagen types I and II, and GLUT1. Peptide-conjugated substrates demonstrated an ability to promote expression of healthy NP-specific markers, as well as increased biosynthetic activity. We show an ability to re-express markers of the juvenile NP cell and morphology through control of peptide presentation and stiffness on well-characterized polyacrylamide substrates. NP cells cultured on surfaces conjugated with α3 integrin receptor peptides P4 and P678, and on α2, α5, α6, β1 integrin-recognizing peptide AG10, show increased expression of aggrecan, N-cadherin, and types I and II collagen, suggesting a healthier, more juvenile-like phenotype. Multi-cell cluster formation was also observed to be more prominent on peptide-conjugated substrates. These findings indicate a critical role for cell-matrix interactions with specific ECM-mimetic peptides in supporting and maintaining a healthy NP cell phenotype and bioactivity.
While the ex vivo manipulation of primary cells has signaled a new era in the application of cell-based therapies, common methods to manipulate primary cells have limitations. To overcome the limitations associated with conventional cell delivery and engineering systems, we have developed an approach to delivery where cells are mechanically deformed as they pass through a constriction. This cellular deformation results in the diffusion of material from the surrounding buffer directly into the cytosol. This system has demonstrated efficacy in patient-derived cells, such as stem cells and immune cells, with a variety of target molecules that are difficult to address with alternative methods. Moreover, by eliminating the need for electrical fields or exogenous materials such as viral vectors and plasmids, it minimizes the potential for cell toxicity and off-target effects. Here, we present evidence detailing our ability to deliver functional material to primary human CD34+ cells via cell deformation with little detectable perturbation in baseline gene expression, cell function, and viability. To determine effect of cell deformation on gene expression and to compare to other delivery systems, human CD34+ cells (n = 3 donors) were subjected to cell deformation or electroporation and gene expression changes were compared to unmanipulated control cells using microarray analysis. Differential gene expression with respect to both methods of delivery was assessed by performing t tests on the coefficient of a linear mixed-effects model that treated delivery method as a fixed effect and donor as a random effect. Electroporation produced substantially more changes in gene expression (5,285 genes with FDR q < 0.25) than cell deformation (no genes with FDR q < 0.25) as compared to untreated controls. Subsequently, we designed a series of experiments to manipulate gene expression with the CRISPR-CAS9 system using cell deformation to deliver CAS9 ribonucleoproteins (RNPs; recombinant CAS9 protein complexed with a single-guide RNA) designed to edit a model locus, the C-C chemokine receptor type 5 (CCR5). Here, we show that the delivery of the CRISPR-CAS9 system via cell deformation results in significant CCR5 mutagenesis. Furthermore, CD34+ cells subjected to cell deformation proliferate and differentiate at rates similar to unmanipulated control cells, as determined by the Colony-Forming Cell (CFC) assay. Disruption of the CCR5 locus was observed in individual BFU-E colonies by performing Sanger sequencing. These data suggest that cell deformation is a viable delivery method for genetic engineering of primary human CD34+ cells with little impact on baseline gene expression or the ability of hematopoietic progenitors to proliferate and differentiate. The ability to deliver structurally diverse materials to difficult-to-transfect primary CD34+ cells indicate that this method could potentially enable many novel clinical applications. Disclosures Bridgen: SQZ Biotechnologies: Employment, Equity Ownership. DiTommaso:SQZ Biotechnologies: Employment, Equity Ownership. Buggé:SQZ Biotechnologies: Employment, Equity Ownership. Gilbert:SQZ Biotechnologies: Employment, Equity Ownership. Bernstein:SQZ Biotechnologies: Employment, Equity Ownership. Sharei:SQZ Biotechnologies: Employment, Equity Ownership, Membership on an entity's Board of Directors or advisory committees.
Activation of T cell responses is essential for effective tumor clearance; however, inducing targeted, potent antigen presentation to stimulate T cell responses remains challenging. We generated Activating Antigen Carriers (AACs) by engineering red blood cells (RBCs) to encapsulate relevant tumor antigens and the adjuvant polyinosinic-polycytidylic acid (poly I:C), for use as a tumor-specific cancer vaccine. The processing method and conditions used to create the AACs promote phosphatidylserine exposure on RBCs and thus harness the natural process of aged RBC clearance to enable targeting of the AACs to endogenous professional antigen presenting cells (APCs) without the use of chemicals or viral vectors. AAC uptake, antigen processing, and presentation by APCs drive antigen-specific activation of T cells, both in mouse in vivo and human in vitro systems, promoting polyfunctionality of CD8+ T cells and, in a tumor model, driving high levels of antigen-specific CD8+ T cell infiltration and tumor killing. The efficacy of AAC therapy was further enhanced by combination with the chemotherapeutic agent Cisplatin. In summary, these findings support AACs as a potential vector-free immunotherapy strategy to enable potent antigen presentation and T cell stimulation by endogenous APCs with broad therapeutic potential.
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