Ex vivo allogeneic stimulation significantly improves expansion of cytokine-induced killer cells without increasing their alloreactivity across HLA barriers.

Cytokine-induced killer cells (CIKs) are ex vivo expanded T-NK lymphocytes capable of HLA-unrestricted antitumor activity. CIKs are promising candidates for adoptive cancer immunotherapies; they can be generated and infused in autologous settings of cancer patients, or from donors, after allogeneic hematopoietic cell transplant. Ex vivo expansion rates of CIKs are greatly variable among patients, with consequent potential clinical limitations for "poor expanders." We compared the standard expansion protocol with a new one, which included the timed addition of irradiated allogeneic peripheral blood mononuclear cells. Our hypothesis is that allogeneic stimulation might provide CIK cells with a proliferative boost and simultaneously decrease their alloreactivity versus third parties, if HLA-mismatched from the allogeneic stimulators. Allo-stimulated CIKs (AS-CIK) reached significantly higher expansion rates compared with standard controls, regardless if generated form healthy donors (131- vs. 32-fold) or cancer patients (117- vs. 14-fold). The expansion of the CD3CD56 subset was 2243-fold for AS-CIKs compared with 362 for standard CIKs. AS-CIKs efficiently killed osteosarcoma targets in vitro, results were comparable with that of standard CIKs. Standard and AS-CIKs did not show differences in phenotype and telomere length. The alloreactivity of AS-CIKs against third party HLA-mismatched peripheral blood mononuclear cells was reduced compared with standard CIKs (37% vs. 23%). In conclusion, alloreactivity of CIK cells may be exploited enhancing their final ex vivo expansion. In clinical perspective these findings may facilitate the extension of CIK-based immunotherapy to larger numbers of patients and, translated into hematopoietic cell transplant settings, contribute to reduce the risk of graft versus host disease in the hypothesis of infusions across HLA barriers.

Transient proteasome inhibition as a strategy to enhance lentiviral transduction of hematopoietic CD34(+) cells and T lymphocytes: implications for the use of low viral doses and large-size vectors.

The proteasome system restricts lentiviral transduction of stem cells. We exploited proteasome inhibition as a strategy to enhance transduction of both hematopoietic stem cells (HSC) and T lymphocytes with low dose or large-size lentiviral vectors (LV). HSC showed higher transduction efficiency if transiently exposed to proteasome inhibitor MG132 (41.8% vs 10.7%, p<0.0001). Treatment with MG132 (0.5 µM) retained its beneficial effect with 3 different LV of increasing size up to 10.9 Kb (p<0.01). We extended, for the first time, the application of proteasome inhibition to the transduction of T lymphocytes. A transient exposure to MG132 significantly improved lentiviral T-cell transduction. The mean percentage of transduced T cells progressively increased from 13.5% of untreated cells, to 21% (p=0.3), 30% (p=0.03) and 37% (p=0.01) of T lymphocytes that were pre-treated with MG132 at 0.1, 0.5 and 1 µM, respectively. MG132 did not affect viability or functionality of HSC or T cells, nor significantly increased the number of integrated vector copies. Transient proteasome inhibition appears as a new procedure to safely enhance lentiviral transduction of HSC and T lymphocytes with low viral doses. This approach could be useful in settings where the use of large size vectors may impair optimal viral production.

Blood-forming stem cells are nervous: direct and indirect regulation of immature human CD34+ cells by the nervous system.

The nervous system regulates immunity through hormonal and neuronal routes as part of host defense and repair mechanism. Here, we review the emerging evidence for regulation of human hematopoietic stem and progenitor cells (HSPC) by the nervous system both directly and indirectly via their bone marrow (BM) niche-supporting stromal cells. Functional expression of several neurotransmitter receptors was demonstrated on HSPC, mainly on the more primitive CD34(+)/CD38(-/low) fraction. The myeloid cytokines, G-CSF and GM-CSF, dynamically upregulate neuronal receptor expression on human HSPC. This is followed by an increased response to neurotransmitters, leading to enhanced proliferation and motility of human CD34(+) progenitors, repopulation of the murine BM and their egress to the circulation. Importantly, recent observations showed rapid mobilization of human HSPC to high SDF-1 expressing ischemic tissues of stroke individuals followed by neoangiogenesis, neurological and functional recovery. Along with decreased levels of circulating immature CD34(+) cells and SDF-1 blood levels found in patients with early-stage Alzheimer's disease, these findings suggest a possible involvement of human HSPC in brain homeostasis and thus their potential clinical applications in neuropathology.

Alloreactivity and anti-tumor activity segregate within two distinct subsets of cytokine-induced killer (CIK) cells: implications for their infusion across major HLA barriers.

Donor-derived cytokine-induced killer (CIK) can be infused as adoptive immunotherapy after hematopoietic cell transplant (HCT). Promising results were recently reported in HLA-identical HCT, where mild grafts versus host (GVH) events were observed. To extend this strategy across major HLA barriers (e.g. HLA-haploidentical HCT), further studies on CIK cells' alloreactivity are needed. We hypothesized that alloreactivity and anti-tumor activity of CIK cells segregate within two different cell subsets and could consequently be separated according to CD56 and CD3 expression. We tested CIK cells expanded from seven patients who underwent HCT as treatment of metastatic colorectal cancer. We found that CIK cells maintained their alloreactivity across major HLA barriers when tested as bulk population; after CD56-positive selection, anti-tumor activity was restricted to the CD3+/CD56+ cell fraction and alloreactivity versus HLA-mismatched PBMC was restricted to the CD3+/CD56- cell fraction. Bulk CIK cells from engrafted patients did not exhibit alloreactivity in response to host- or donor-derived PBMC, confirming their low potential for GVH across minor HLA barriers. Moreover, we tested if CIK cells expanded from engrafted patients after HCT were as effective as donor-derived ones and could be considered as an alternative option. The expansion rate and tumor cell killing was comparable to that observed in sibling donors. In conclusion, depletion of CD3+/CD56- cells might reduce the risk of GVH without affecting the tumor-killing capacity and could help extending CIK infusions across major HLA barriers. Engrafted patients after HCT could also be considered as an effective alternative option to donor-derived CIK cells.

Sustained long-term engraftment and transgene expression of peripheral blood CD34+ cells transduced with third-generation lentiviral vectors.

As mobilized peripheral blood (MPB) represents an attractive cell source for gene therapy, we investigated the ability of third-generation lentiviral vectors (LVs) to transfer the enhanced green fluorescent protein gene into MPB CD34(+) cells in culture conditions allowing expansion of transplantable human hematopoietic stem cells. To date, few studies have reported transduction of MPB cells with vesicular stomatitis virus G pseudotyped LVs. The critical issue remains whether primitive, hematopoietic repopulating cells have, indeed, been transduced. In vitro (5 weeks' culture in FLT3 ligand + thrombopoietin + stem cell factor + interleukin 6) and in vivo (serial transplantation in NOD/SCID mice) experiments show that MPB CD34(+) cells can be effectively long-term transduced by LV and maintain their proliferation, self-renewal, and multilineage differentiation potentials. We show that expansion following transduction improves the engraftment of transduced MPB CD34(+) (4.6-fold expansion of SCID repopulating cells by limiting dilution studies). We propose ex vivo expansion after transduction as an effective tool to improve gene therapy protocols with MPB. Disclosure of potential conflicts of interest is found at the end of this article.

Vasculogenic potential of long term repopulating cord blood progenitors.

In the adult, involvement of bone marrow-derived circulating endothelial progenitor cells (EPCs) in tissue revascularization (vasculogenesis) and the cooperation of hematopoietic cell subsets in supporting this process have been described in different experimental animal models. However, the effective contribution of such cells in restoring organ vascularization in a clinical setting needs to be clarified. In this study, a mouse transplantation model was engrafted by human cord blood hematopoietic stem and progenitor cells to follow the behavior of donor-derived endothelial and hematopoietic cells in the presence of a localized source of an angiogenic inducer. Human endothelial markers (CD31+/CD45-, VE-cadherin+) were always detectable in the bone marrow of transplanted mice, while they were only randomly detectable in peripheral neovascularization sites. To investigate the ability of human transplanted hematopoietic stem cells to support new vessel formation in response to altered homeostatic conditions, chimeric mice were further treated by systemic injection of human mononuclear cells (MNCs). Our data indicate that MNC administration in transplanted mice enhances vasculogenesis in the newly formed vessels. Taken together these results suggest that human-derived EPCs, long-term engrafting a xenotransplantation model, have hematopoietic and endothelial developmental potential, which can be modulated by altering the physiological conditions of host microenvironment.