Global transcriptional analysis delineates the differential inflammatory response interleukin-15 elicits from cultured human T cells.

OBJECTIVE: Interleukin 15 (IL)-15 controls proliferation and survival of T cells, but its effects and the underlying cellular regulation are not well understood. Previous studies have focused on its effects on short-term T-cell cultures. In view of the potential problems associated with using IL-2 alone in adoptive immunotherapy protocols, we investigated the impact of IL-15 on T-cell cultures and the global transcriptional effects it elicits in such cultures. MATERIALS AND METHODS: DNA microarrays and flow cytometry were used to examine the differential effect of 20 ng/mL IL-15 on primary serum-free T-cell cultures activated and cultured in the presence of IL-2. Quantitative reverse transcriptase polymerase chain reaction confirmed select microarray data. RESULTS: IL-15 significantly increased ex vivo expansion of primary human T cells over the entire 11-day expansions without affecting viability. The 1133 genes were consistently differentially expressed among three donor samples. Ontological analysis demonstrated that IL-15 increases expression of genes involved in inflammatory response (e.g., tumor necrosis factor [TNF]-alpha, Oncostatin M, CD40L, and CD33) and apoptosis (e.g., TNF-related apoptosis-inducing ligand). IL-15 also induced expression of four suppressors of cytokine signaling (SOCS) family genes (SOCS1-3, cytokine-inducible SH2-containing protein), which are classical negative regulators of cytokine signaling. IL-15 strongly suppressed the expression of inhibitory natural killer cell receptor genes, including three C-type lectins (KLRB1, KLRC1, and KLRD1), as well as IL-7Ra and Granzyme H. Finally, IL-15 induced differential expression of TNF receptor superfamily members (CD27 and CD30). CONCLUSION: These findings suggest that exogenous IL-15 may have a potential role in adoptive immunotherapy by both enhancing proliferation and modulating functionality during ex vivo T-cell expansion.

Molecular insights into the pleiotropic effects of plasma on ex vivo-expanded T cells using DNA-microarray analysis.

OBJECTIVE: Immunotherapy with ex vivo-expanded T cells depends on a large supply of biologically active cells. Understanding the effects of culture parameters is essential for improving cell expansion and efficacy. We used DNA-microarray and flow-cytometric analysis coupled with functional assays to investigate mechanistic aspects of plasma supplementation in ex vivo T-cell expansion. METHODS: The effect of plasma supplementation on 18 primary T-cell cultures over a 15-day expansion was investigated. Transcriptional analysis of 5 samples was done with time points every 2 to 3 days throughout the 15-day expansion. Quantitative RT-PCR analysis was used to confirm selected microarray data. The expression of granzyme A and vimentin were analyzed using intracellular flow cytometry. T-cell functionality was assessed using a mixed leukocyte reaction (MLR). RESULTS: We show that the increased expansion of plasma-supplemented cultures of primary human T cells is mostly due to increased cell survival. T cells from plasma-supplemented cultures show higher expression of immunoglobulin genes, integrins, and genes of cytotoxic granules, suggesting a possible enhanced immune function. This was confirmed using a mixed leukocyte reaction and intracellular granzyme-A measurements. A distinct gene expression pattern was correlated to viability differences between plasma-supplemented and serum-free cultures. Ontological analysis of genes in this pattern suggests that the decreased viability of serum-free cultures correlates with higher expression of actin-cytoskeleton and lipid-metabolism genes. Vimentin was found to be expressed higher in serum-free cultures. CONCLUSIONS: These results indicate that the observed decreased cytotoxicity of T cells cultured in serum-free media may be due to increased oxidative stress and cytoskeleton degradation.

Molecular understanding of oxygen-tension and patient-variability effects on ex vivo expanded T cells.

Immunotherapy with ex vivo cultured T cells depends on a large supply of biologically active cells. Understanding the effects of culture parameters is essential for improving the proliferation and efficacy of the expanded cells. Low oxygen tension (5% pO(2)) was previously reported to improve T-cell expansion and alter cellular phenotypic characteristics compared to T cells cultured at 20% pO(2). Here we report the use of DNA-array based transcriptional analysis coupled with protein-level analysis to provide molecular insights into pO(2) and patient-variability effects on expanded primary human T cells. Analysis of seven blood samples showed that reduced pO(2) results in higher expression of genes important in lymphocyte biology, immune function, and cell-cycle progression. 20% pO(2) resulted in higher expression of genes involved in stress response, cell death, and cellular repair. Expression of granzyme A (gzmA) was found to be significantly regulated by oxygen tension with cells at 5% pO(2) having greater gzmA expression than at 20% pO(2). Protein-level analysis of gzmA was consistent with transcriptional analysis. Granzyme K (gzmK) was coexpressed with gzmA, whereas Granzyme B (gzmB) expression was found to precede the expression of both gzmA and gzmK in 15-day cultures. Temporal gene expression patterns for seven blood samples demonstrate that most genes are expressed by all patient samples in similar temporal patterns. However, several patient-specific gene clusters were identified, and one cluster was found to correlate well with cell proliferation and may potentially be used to predict patient-specific T-cell expansion.