MicroRNAs Enable mRNA Therapeutics to Selectively Program Cancer Cells to Self-Destruct.

The advent of therapeutic mRNAs significantly increases the possibilities of protein-based biologics beyond those that can be synthesized by recombinant technologies (eg, monoclonal antibodies, extracellular enzymes, and cytokines). In addition to their application in the areas of vaccine development, immune-oncology, and protein replacement therapies, one exciting possibility is to use therapeutic mRNAs to program undesired, diseased cells to synthesize a toxic intracellular protein, causing cells to self-destruct. For this approach to work, however, methods are needed to limit toxic protein expression to the intended cell type. Here, we show that inclusion of microRNA target sites in therapeutic mRNAs encoding apoptotic proteins, Caspase or PUMA, can prevent their expression in healthy hepatocytes while triggering apoptosis in hepatocellular carcinoma cells.

Conversion potential of marrow cells into lung cells fluctuates with cytokine-induced cell cycle.

Green fluorescent protein (GFP)-labeled marrow cells transplanted into lethally irradiated mice can be detected in the lungs of transplanted mice and have been shown to express lung-specific proteins while lacking the expression of hematopoietic markers. We have studied marrow cells induced to transit the cell cycle by exposure to interleukin-3 (IL-3), IL-6, IL-11, and Steel factor at different times of culture corresponding to different phases of cell cycle. We have found that marrow cells at the G(1)/S interface of the cell cycle have a three-fold increase in cells that assume a nonhematopoietic or pulmonary epithelial cell phenotype and that this increase is no longer seen in late S/G(2). These cells have been characterized as GFP(+) CD45(-) and GFP(+) cytokeratin(+). Thus, marrow cells with the capacity to convert into cells with a lung phenotype after transplantation show a reversible increase with cytokine-induced cell cycle transit. Previous studies have shown that the phenotype of bone marrow stem cells fluctuates reversibly as these cells traverse the cell cycle, leading to a continuum model of stem cell regulation. The present study indicates that marrow stem cell production of nonhematopoietic cells also fluctuates on a continuum.

Alteration of marrow cell gene expression, protein production, and engraftment into lung by lung-derived microvesicles: a novel mechanism for phenotype modulation.

Numerous animal studies have demonstrated that adult marrow-derived cells can contribute to the cellular component of the lung. Lung injury is a major variable in this process; however, the mechanism remains unknown. We hypothesize that injured lung is capable of inducing epigenetic modifications of marrow cells, influencing them to assume phenotypic characteristics of lung cells. We report that under certain conditions, radiation-injured lung induced expression of pulmonary epithelial cell-specific genes and prosurfactant B protein in cocultured whole bone marrow cells separated by a cell-impermeable membrane. Lung-conditioned media had a similar effect on cocultured whole bone marrow cells and was found to contain pulmonary epithelial cell-specific RNA-filled microvesicles that entered whole bone marrow cells in culture. Also, whole bone marrow cells cocultured with lung had a greater propensity to produce type II pneumocytes after transplantation into irradiated mice. These findings demonstrate alterations of marrow cell phenotype by lung-derived microvesicles and suggest a novel mechanism for marrow cell-directed repair of injured tissue.

Bone marrow production of lung cells: the impact of G-CSF, cardiotoxin, graded doses of irradiation, and subpopulation phenotype.

OBJECTIVE: Previous studies have demonstrated the production of various types of lung cells from marrow cells under diverse experimental conditions. Our aim was to identify some of the variables that influence conversion in the lung. METHODS: In separate experiments, mice received various doses of total-body irradiation followed by transplantation with whole bone marrow or various subpopulations of marrow cells (Lin(-/+), c-kit(-/+), Sca-1(-/+)) from GFP(+) (C57BL/6-TgN[ACTbEGFP]1Osb) mice. Some were given intramuscular cardiotoxin and/or mobilized with granulocyte colony-stimulating factor (G-CSF). RESULTS: The production of pulmonary epithelial cells from engrafted bone marrow was established utilizing green fluorescent protein (GFP) antibody labeling to rule out autofluorescence and deconvolution microscopy to establish the colocaliztion of GFP and cytokeratin and the absence of CD45 in lung samples after transplantation. More donor-derived lung cells (GFP(+)/CD45(-)) were seen with increasing doses of radiation (5.43% of all lung cells, 1200 cGy). In the 900-cGy group, 61.43% of GFP(+)/CD45(-) cells were also cytokeratin(+). Mobilization further increased GFP(+)/CD45(-) cells to 7.88% in radiation-injured mice. Up to 1.67% of lung cells were GFP(+)/CD45(-) in radiation-injured mice transplanted with Lin(-), c-kit(+), or Sca-1(+) marrow cells. Lin(+), c-kit(-), and Sca-1(-) subpopulations did not significantly engraft the lung. CONCLUSIONS: We have established that marrow cells are capable of producing pulmonary epithelial cells and identified radiation dose and G-CSF mobilization as variables influencing the production of lung cells from marrow cells. Furthermore, the putative lung cell-producing marrow cell has the phenotype of a hematopoietic stem cell.

Stem cells and pulmonary metamorphosis: new concepts in repair and regeneration.

Adult stem cells are likely to have much more versatile differentiation capabilities than once believed. Numerous studies have appeared over the past decade demonstrating the ability of adult stem cells to differentiate into a variety of cells from non-hematopoietic organs, including the lung. The goal of this review is to provide an overview of the growth factors which are thought to be involved in lung development and disease, describe the cells within the lung that are believed to replace cells that have been injured, review the studies that have demonstrated the transformation of bone marrow-derived stem cells into lung cells, and describe potential clinical applications with respect to human pulmonary disease.

Stem cell plasticity: an overview.

The capacity of adult bone marrow cells to convert to cells of other tissues, referred to by many as stem cell plasticity, was the focus of the meeting in Providence entitled "Challenges in the Era of Stem Cell Plasticity". The meeting provided a showcase for the many impressive positive results on tissue restoration including the capacity of purified marrow stem cells to restore heart, skin, and liver function in impaired mice or humans. This area of research has become a center of controversy, although it is not clear why. Calls for clonality, robustness, and function have been shown to be erroneous or premature. A call for clonality (which has been shown nicely in one study) is meaningless on a predefined stem cell population which is intrinsically heterogeneous, as they all are. Robustness means nothing; it all depends on the details of the situation. Function on an organ level is, of course, the goal of many investigators and should not be raised as a limiting consideration. Lastly, fusion has been highlighted as undermining studies with adult stem cells. It, of course, does not. Fusion is simply a means to a final goal, which occurs in certain settings of marrow conversions (transdifferentiation) and not in others. We hypothesize that the conversion phenomena may, in fact, be due to one or several marrow stem cells with broad differentiation potential which can be expressed when the cell is placed in an environment with the appropriate inductive signals. Furthermore, initial events may be relatively rare and significant conversion numbers may be obtained with massive or ongoing selection. Fusion appears in an initial mechanism in some cases and not in others. Overall, the therapeutic potential of adult marrow stem cells is very intriguing, and successful use therapeutically will probably depend on definition of the most appropriate transplant model and tissue injury.

Homing and conversion of murine hematopoietic stem cells to lung.

The hematopoietic stem cell population, lineage negative-Sca positive (HSC), displays a homing defect into bone marrow (BM) after 48-h exposure to interleukin (IL)-3, IL-6, IL-11, and steel factor [J. Hematother. Stem Cell Res. 11 (2002) 913]. Cytokine treatment of murine marrow leads to reversible alterations in adhesion protein expression, which may explain the changes in homing. We evaluated 3 h homing to nonhematopoietic organs of marrow cells exposed to cytokines for 0, 18, 24, 40 and 48 h. HSC cells from C57BL/6J mice were cultured and labeled with the cytoplasmic fluorescent dye CFSE. We found homed events from uncultured cells in spleen, liver and lung, but no events were seen in duodenum or anterior tibialis muscle. Culture in cytokines led to decreased homing to marrow at 24 and 48 h with parallel changes in spleen homing. There was little variability of homing to liver, however the number, of homed events in lung was markedly increased when 24-h cultured cells were assessed. This was approximately a 10-fold increase compared to the 0 h time point (flow cytometry). Homing was determined by evaluation of frozen section (8 microm) by fluorescent microscopy for spleen, liver, duodenum, anterior tibialis and lung. Data were confirmed by flow cytometry from each organ including marrow. These data indicate the presence of a lung homing "hotspot" at 24 h of cytokine culture; this is a time when the stem progenitors cells are in mid S-phase. Altogether these data suggest that homing of marrow cell to nonmarrow organs may fluctuate with cell cycle transit and that there is a lung homing hotspot in mid-S.