In Vitro Proliferation and Expansion of Hematopoietic Progenitors Present in Mobilized Peripheral Blood from Normal Subjects and Cancer Patients

Stemness-related genes revealed by single-cell profiling of naïve and stimulated human CD34+ cells from CB and mPB

BACKGROUND

Hematopoietic stem cells (HSCs) from different sources show varied repopulating capacity, and HSCs lose their stemness after long-time ex vivo culture. A deep understanding of these phenomena may provide helpful insights for HSCs.

METHODS

Here, we applied single-cell RNA-seq (scRNA-seq) to analyse the naïve and stimulated human CD34+ cells from cord blood (CB) and mobilised peripheral blood (mPB).

RESULTS

We collected over 16 000 high-quality single-cell data to construct a comprehensive inference map and characterised the HSCs under a quiescent state on the hierarchy top. Then, we compared HSCs in CB with those in mPB and HSCs of naïve samples to those of cultured samples, and identified stemness-related genes (SRGs) associated with cell source (CS-SRGs) and culture time (CT-SRGs), respectively. Interestingly, CS-SRGs and CT-SRGs share genes enriched in the signalling pathways such as mRNA catabolic process, translational initiation, ribonucleoprotein complex biogenesis and cotranslational protein targeting to membrane, suggesting dynamic protein translation and processing may be a common requirement for stemness maintenance. Meanwhile, CT-SRGs are enriched in pathways involved in glucocorticoid and corticosteroid response that affect HSCs homing and engraftment. In contrast, CS-SRGs specifically contain genes related to purine and ATP metabolic process, which is crucial for HSC homeostasis in the stress settings. Particularly, when CT-SRGs are used as reference genes for the construction of the development trajectory of CD34+ cells, lymphoid and myeloid lineages are clearly separated after HSCs/MPPs. Finally, we presented an application through a small-scale drug screening using Connectivity Map (CMap) against CT-SRGs. A small molecule, cucurbitacin I, was found to efficiently expand HSCs ex vivo while maintaining its stemness.

CONCLUSIONS

Our findings provide new perspectives for understanding HSCs, and the strategy to identify candidate molecules through SRGs may be applicable to study other stem cells.

Robust, quantitative tools for modelling ex-vivo expansion of haematopoietic stem cells and progenitors

Despite substantial research activity on bioreactor design and experiments, there are very few reports of modelling tools that can be used to generate predictive models describing how bioreactor parameters affect performance. New developments in mathematics, such as sparse Bayesian feature selection methods and nonlinear model-free modelling regression methods, offer considerable promise for modelling diverse types of data. The utility of these mathematical tools in stem cell biology are demonstrated by analysis of a large set of bioreactor data derived from the literature. In spite of the diversity of the data sources, and the inherent difficulty in representing bioreactor variables, these modelling methods were able to develop robust, quantitative, predictive models. These models relate bioreactor operational parameters to the degree of expansion of haematopoietic stem cells or their progenitors, and also identify the bioreactor variables that are most likely to affect performance across many experiments. These methods show substantial promise in assisting the design and optimisation of stem cell bioreactors.

Augmenting Therapy of Ovarian Cancer Efficacy by Secreting IL-21 Human Umbilical Cord Blood Stem Cells in Nude Mice

In the present study, CD34+ human umbilical cord blood stem cells (UCBSCs) were engineered to express interleukin-21 (IL-21) and then were transplanted into A2780 ovarian cancer xenograft-bearing Balb/c nude mice. The therapeutic efficacy of this procedure on ovarian cancer was evaluated. The findings from the study indicated that UCBSCs did not form gross or histological teratomas until up to 70 days postinjection. The CD34+ UCBSC-IL-21 therapy showed a consistent effect in the ovarian cancer of the treated mice, delaying the tumor appearance, reducing the tumor sizes, and extending life expectancy. The efficacy was attributable to keeping CD34+ UCBSC-IL-21 in the neoplastic tissues for more than 21 days. The secreted IL-21 not only increased the quantity of CD11a+ and CD56+ NK cells but also increased NK cell cytotoxicities to YAC-1 cells and A2780 cells, respectively. The efficacy was also associated with enhancing the levels of IFN-γ, IL-4, and TNF-α in the mice as well as the high expressions of the NKG2D and MIC A/B molecules in the tumor tissues. This study suggested that transferring CD34+ UCBSC-IL-21 into the nude mice was safe and feasible in ovarian cancer therapy, and that the method would be a promising new strategy for clinical treatment of ovarian cancer.

Antitumor effect of lung cancer vaccine with umbilical blood dendritic cells in reconstituted SCID mice

Dendritic cells (DCs) are important cells in initiating an immune response. A generation of functional DCs has potential clinical use in treating cancer. However, the source of DCs and patient immunodeficiency with cancer have been hindrances in clinical therapy. We generated DCs from human umbilical cord blood mononuclear cells (UBMCs) with recombinant human granulocyte-macrophage colony stimulating factor, recombinant human interleukin-4, and recombinant human tumor necrosis factor-alpha. The mature DC-A549 lung cancer vaccine (AgL-DC) was prepared through loading A549 lysate, treating with lipopolysaccharide (LPS) and positive selecting with CD83 magnetic beads. AgL-DC can secrete interleukin (IL)-12 and IL-1. Further in vitro analysis showed that AgL-DC notably induced human UBMC lymphocyte proliferation (p < 0.01) by 3-(4,5-dimethylthiazol-z-yl)-2,5-diphenyltetrazolium bromide (MTT) assay, increased the cytotoxic T-lymphocyte (CTL) activity of UBMC lymphocytes against A549 cells (p < 0.05, at effector cells:target cells ratios of 50:1 and 100:1) by lactate dehydrogenase (LDH) cytotoxic assay, and improved production of IL-6 and tumor necrosis factor-beta (p < 0.01, p < 0.05) by enzyme-linked immunosorbent assay. Subsequently, the reconstitute immunity model in severe combined immunodeficiencies (SCID) mice has been established using human UBMC transplantation, and similar trends to results of UBMC in vitro experiments have been shown in lymphocyte proliferation, CTL activity, and IL-6 and tumor necrosis factor-beta secretion levels in these models. AgL-DC also significantly (p < 0.01) increased the antitumor effect in vivo. The tumor infiltrating immunocytes were positively expressed human CD83 and CD3 molecules, and they were negatively expressed in tumor tissue treated with control. These results have demonstrated that umbilical cord DCs are a useful source of vaccine cells for augmenting CTL-mediated cytotoxicity and have potential usefulness in cellular therapy for human cancer in a new vaccination strategy.

Neural Network Analysis of Ex-vivo Expansion of Hematopoietic Stem Cells

The shortage of hematopoietic stem cells (HSCs) greatly limits their widespread clinical applications. Few studies however, investigated the relationship between the cellular expansion and the influencing factors although wide variety results of the ex-vivo expansion of HSCs existed in literature. Here, a back-propagation (BP) neural network model was employed to evaluate the ex-vivo expansions of nuclear cells (NCs), CD34(+) cells, and colony-forming units (CFU-Cs), where the output was the cellular expansion folds and the inputs include inoculated density, cytokines, resources, serum, stroma, culture time, and bioreactor types. Around 124, 86, and 90 samples were used to train the neural network for the expansion evaluations of NCs, CD34(+ )cells, and CFU-Cs, respectively, while 17, 14, and 10 samples were applied to predict respectively. The results show that for the training of network, the interval accuracy of the expansion folds for the different cells is 85.5, 86.1, and 86.7%, respectively, while the truth-value accuracy is still up to 59.7, 50.0, and 62.2%, respectively within a relative error (RE) of +/-20%. For the prediction of network, the interval accuracy can be up to 82.4, 71.4, and 70%, respectively, while the truth-value accuracy is only 29.4, 14.3, and 50.0%, respectively (RE = +/-20%). Moreover, six verification experiments were carried out based on our interval predicted values and the results proved that the five group predicted conditions lead to the correct expansion of the HSCs with the accuracy more than 80%. Considering the complexity of HSC expansion and complicated wide range of the experimental data, such relatively high interval accuracy for training and prediction as well as verification are satisfied. Therefore this nonlinear modeling makes it possible to describe quantitatively the effects of the culture conditions on the HSC expansion and to predict the optimal culture conditions for higher ex-vivo expansion of HSCs.

Cell Cycle Differences in Vitro between Primitive Hematopoietic Cell Populations from Adult and Umbilical Cord Blood

Lineage-negative (Lin(-)) cell populations, obtained by negative selection from umbilical cord blood (UCB) and adult mobilized peripheral blood (aMPB), were cultured in serum-free liquid cultures supplemented with a mixture of seven stimulatory cytokines. On specific days, proliferation potential was assessed and cell cycle status was determined by DNA content. Expression of the cell cycle regulators cyclin D3 (cD3), cyclin-dependent kinase 4 (cdk4), p21(cip1/waf1) (p21), and p27(kip1) (p27) was also determined. As expected, UCB cells showed significantly higher proliferation potentials than aMPB cells, particularly during the first 7 days of culture. During this period of time, higher numbers of cell cycles were observed in UCB cells (7-9 cycles), as compared to aMPB cells (5-6 cycles). Higher levels of cD3, cdk4, and p27 were also detected in UCB cells. Our results confirm that UCB cells possess an intrinsically higher proliferation potential, as compared to aMPB cells, and suggest that such a biological difference is due, at least in part, to differences in cell cycle status. This, in turn, seems to result from the differential expression of cell cycle regulatory molecules.

In vitro functional alterations in the hematopoietic system of adult patients with acute lymphoblastic leukemia

In previous studies, we have demonstrated that progenitor cell-enriched marrow cell populations from patients with myeloid leukemia - including both acute (AML) and chronic (CML) - show severe functional alterations when cultured in stroma-free liquid cultures supplemented with stimulatory cytokines. In trying to expand our characterization of the biology of leukemic cells, in the present study we have used a similar approach and analyzed the in vitro growth of equivalent cell populations from patients with acute lymphoblastic leukemia (ALL). ALL marrow cell populations -enriched for hematopoietic progenitors by means of a negative selection procedure- were assessed for their proliferation and expansion potentials, in liquid cultures supplemented with a mixture of early- and late-acting recombinant stimulatory cytokines, throughout a 25-day culture period. ALL cells, although capable of responding to the stimulatory signals provided by hematopoietic stimulators, showed deficient proliferation potentials (reduced capacity to generate more nucleated cells), as compared with their normal counterparts. The capacity to generate myeloid and erythroid progenitors was also significantly reduced in ALL cultures. Interestingly, the functional alterations observed in ALL cultures (i.e., deficient proliferation and expansion potentials) were more pronounced in those from Ph+ patients than in those from Ph- patients. This study indicates that bone marrow cell populations - enriched for hematopoietic progenitor cells - from ALL patients possess deficient proliferation and expansion potentials in vitro, and that such functional alterations are more severe when cells are derived from Ph+ patients, as compared to their Ph- counterparts.

Growth kinetics of progenitor cell-enriched hematopoietic cell populations in long-term liquid cultures under continuous removal of mature cells

BACKGROUND

During long-term culture of primitive hematopoietic cells large numbers of mature cells are generated that, on the one hand, consume nutrients and cytokines present in the medium and, on the other hand, may produce or elicit the production of soluble factors that limit the growth of primitive cells. Thus it is possible that under standard culture conditions hematopoietic stem and progenitor cells are unable to display their true proliferation and expansion potentials.

METHODS

Hematopoietic cell populations, enriched for CD34+ cells, were obtained from both umbilical cord blood (UCB) and mobilized peripheral blood (MPB), and cultured in cytokine-supplemented liquid culture, under continuous removal of mature cells by means of weekly re-selection of primitive, lineage-negative (Lin-) cells. Proliferation and expansion capacities of such cells were determined weekly for a 42-day culture period.

RESULTS

As expected, based on our previous studies in standard liquid cultures, throughout the culture period there was a continuous decrease in the proportion of progenitor cells; however, after every re-selection on days 7, 14 and 21, there was a significant enrichment for both CD34+ cells and colony-forming cells (CFC). As a result of such an enrichment, the cumulative increase in the numbers of total cells and CFC in cultures with two, three or four selections was significantly higher than the increments observed in standard cultures, in which only a single selection was performed on day 0. Cultures of UCB cells showed consistently higher levels of both total cells and CFC than cultures of MPB cells.

DISCUSSION

Taken together, these results indicate that continuous removal of mature cells from liquid cultures of primitive progenitors results in higher increments in the levels of both total cells and CFC.

MLL rearrangements are induced by low doses of etoposide in human fetal hematopoietic stem cells

During fetal development, the liver serves as the primary hematopoietic organ in which hematopoietic stem cells (HSC) comprise a large proportion of hepatic cell populations. Because HSC are capable of initiating long-term hematopoiesis, injury to these cells during pregnancy may play a role in the development of hematopoietic disorders manifested after birth. Of interest is the role of genetic injury to fetal HSC in the etiology of the infant acute leukemias, which are characterized by chromosomal rearrangements in the 11q23 region involving the mixed lineage leukemia (MLL) gene. These gene fusions also occur in leukemias in adults following chemotherapy with etoposide and other inhibitors of DNA topoisomerase II. We used etoposide as a model compound to determine the sensitivity of human fetal HSC to DNA damage and to determine whether we could induce MLL rearrangements in cultured human fetal HSC. Exposure of HSC to etoposide resulted in a dose-dependent loss of viability, with effects observed at low nanomolar concentrations. DNA strand breaks were observed on exposure to 140 nM etoposide, and higher etoposide concentrations stimulated an increase in early lymphoid populations and elicited G2/M cell cycle arrest. Immunophenotyping of MLL translocations revealed a significant increase in positive flow cytometry events at low etoposide concentrations and were consistent with MLL recombination. MLL translocations were confirmed using fluorescent in situ hybridization. In vitro inhibition of DNA topoisomerase II was observed at >or=25 microM etoposide, but was not evident at lower etoposide concentrations associated with DNA damage. Our data indicate that low acute doses of etoposide can cause DNA strand breaks and chromosomal rearrangements involving MLL in human fetal HSC. Ultimately, such injury may have ramifications with regards to transplacental exposures to environmental chemicals linked to the etiology of infant acute leukemias.

Cancer is a functional repair tissue

When a wound occurs, growth and repair genes (GR genes, such as oncogenes, proto-oncogenes, etc.) in surrounding cells are activated and secretion of growth and repair factors (GR factors, such as growth, stem cell, and stimulating factors, etc.) is induced to heal the wound. However, if the wound is persistent due to chronic physical (radiation, electromagnetic field, trauma, particles, etc.), chemical (carcinogens, toxic chemicals, heavy metals etc.) or biological (aging, free radicals, inflammation, nutrient deficiency, bacteria and virus infections, stress, etc.) damage, amplification of GR gene activation in surrounding cells may lead to a clinical cancer. Based on the commonalities between cancer and wound healing, a new hypothesis of cancer is presented: malignancies are not passive mutated useless masses; rather, they are functional tissues produced by GR gene activation to secrete GR factors in an effort to heal persistent wounds in the body. Based on the hypothesis, current cancer treatments aimed at killing cancer cells only may be misguided. The logical extension of the hypothesis is that cancer treatment focused on wound healing by limiting causes of persistent wounds, providing repair cells, GR factors, and substrates required by repair cells may yield more fruitful results than treatments focused on killing cancer cells alone. Spontaneous regressions of cancer, although rare, may be successful examples of serendipitous spontaneous wound healing. Standard therapies aimed at killing cancer cells, should be limited to adjuvant status for limiting symptoms or buying time for completion of the wound healing process. Attempts to destroy cancer cells without healing underlying persistent wounds will allow for eventual recurrence.

Ex vivo expansion of neutrophil precursor cells from mobilized peripheral blood cells: similar results in cancer patients and normal donors

BACKGROUND

Infusion of ex vivo differentiated myeloid progenitors may reduce or abrogate severe neutropenia following mobilized peripheral blood transplantation. We compared the ex vivo expansion of myeloid progenitor cells starting from cancer patients (CP) and from normal donors (ND) and evaluated the influence of the CD34(+) cell mobilization on the capacities of cells to be expanded.

METHODS

The ex vivo-expanded cells were evaluated for their phenotype, the presence of primary and secondary granules and their functional capacities (oxidative burst activity and phagocytosis).

RESULTS

We did not observe significant differences between ND and CP for the total leukocyte and CD34(+) cell expansions nor for the myeloid progenitor production. In CP as well as in ND, the expanded cells were functionally competent.

DISCUSSION

This suggests that the capacities of CD34(+) cells to proliferate and differentiate ex vivo are not impaired by prior chemotherapy and/or disease status. On the other hand, we did not observe any significant correlation between the number of mobilized CD34(+) cells before apheresis and the cell expansion. In conclusion, the ex vivo expansion of CP and ND cells is comparable and achievable even with a low CD34(+) cell number in mobilized peripheral blood.