A soluble activator that favors the ex vivo expansion of CD8+CD27+ T cells
Esther I. Matus, Amanda Sparkes, Jean Gariépy
Esther I. Matus, Amanda Sparkes, Jean Gariépy
View: Text | PDF
Resource and Technical Advance Therapeutics

A soluble activator that favors the ex vivo expansion of CD8+CD27+ T cells

Abstract

Adoptive cell therapy involves the infusion of tumor-reactive T cells into patients with cancer to provide antitumor immunity. The ex vivo expansion and differentiation of such T cells are key parameters that affect their therapeutic potential. Human T cells are presently expanded in culture through the use of anti-CD3 and anti-CD28 mAbs immobilized on beads, expressed on cells, or assembled in the context of soluble antibody complexes. Here we report the design of a small, bispecific single-chain variable fragment construct agonizing both CD3 and CD28 pathways. This soluble T cell expansion protein, termed T-CEP, activates, expands, and differentiates human T cells ex vivo at concentrations in the femtomolar range. Importantly, T-CEP promotes the preferential growth of human CD8+ T cells over the course of 12 days in comparison with methods involving immobilized anti-CD3 mAb/soluble anti-CD28 mAb or soluble anti-CD3/CD28 mAb complexes. The differentiation profile of the resulting human T cell population is also singularly affected by T-CEP, favoring the expansion of a preferred CD8+CD27+ T cell phenotype. The activity profile of T-CEP on human T cells ex vivo suggests its use in generating human T cell populations that are more suited for adoptive cell therapy.

Authors

Esther I. Matus, Amanda Sparkes, Jean Gariépy

×

Figure 6

T-CEP favors the ex vivo differentiation of T cells toward a less differentiated human CD8+ T cell phenotype.

Options: View larger image (or click on image) Download as PowerPoint
T-CEP favors the ex vivo differentiation of T cells toward a less differ...
(A) Representative cytometric plots highlighting the expression of CD45RA and CD27 on CD4+ (top row) and CD8+ (bottom row) T cells and of CD8+CD27+ human T cells at day 12 following their activation and expansion using a designated treatment. (B) Surface expression at day 12 of CD45RA and CD27 markers as a percentage of CD4+ populations from 5 donors. In the CD3+CD4+ T cell subset population, T-CEP displayed significantly increased levels of CD45RACD27+ T cells relative to i αCD3 treated cells with or without s αCD28. Additionally, T-CEP–stimulated T cells had the lowest percentage of CD45RACD27 and CD45RA+CD27 phenotype, which were significantly reduced compared with i αCD3–treated T cells (n = 5, 1-way repeated measures ANOVA with a Tukey’s multiple-comparison test). (C) Surface expression at day 12 of CD45RA and CD27 markers as a percentage of CD8+ populations from 5 donors. On average, T-CEP–stimulated T cells displayed the highest percentage of CD45RACD27+ phenotype, with a significant increase relative to i αCD3 and i αCD3 with s αCD28. T-CEP also significantly reduced the CD45RACD27 T cell phenotype relative to i αCD3 with or without s αCD28 (n = 5, 1-way repeated measures ANOVA with a Tukey’s multiple-comparison test). (D) The percentage of viable CD8+CD27+ lymphocytes at day 12 observed in human T cell samples collected from 5 donors. T-CEP–stimulated T cells coexpressing CD8 and CD27 accounted for 62.3% of the total viable lymphocyte population, which was significantly higher compared with cells stimulated with i αCD3 alone, i αCD3 and s αCD28, and TACs (n = 5, 1-way repeated measures ANOVA with a Tukey’s multiple-comparison test). (E) CD27 expression on CD8+ T cells (ΔMFI) at day 12 from each treatment modality. The ΔMFI was calculated by subtracting the MFI value of the appropriate isotype control. The subset of CD8+ T cells expressing CD27 was significantly higher in T cells stimulated with T-CEP relative to i αCD3 or i αCD3 and s αCD28 (n = 5, 1-way repeated measures ANOVA). (F) The expansion of the CD8+CD27+ T cells over 12 days was substantially greater when treated with T-CEP than with the other indicated stimulation methods (n = 5, 1-way repeated measures ANOVA with a Tukey’s multiple-comparison test). TACs, tetrameric antibody complexes; i αCD3, immobilized anti-CD3; s αCD28, soluble anti-CD28. *P < 0.05; **P < 0.01; ***P < 0.001.