Allogeneic Human Mesenchymal Stem Cells in Patients With Idiopathic Pulmonary Fibrosis via Intravenous Delivery (AETHER): A Phase I Safety Clinical Trial.

BACKGROUND: Despite Food and Drug Administration approval of 2 new drugs for idiopathic pulmonary fibrosis (IPF), curative therapies remain elusive and mortality remains high. Preclinical and clinical data support the safety of human mesenchymal stem cells as a potential novel therapy for this fatal condition. The Allogeneic Human Cells (hMSC) in patients with Idiopathic Pulmonary Fibrosis via Intravenous Delivery (AETHER) trial was the first study designed to evaluate the safety of a single infusion of bone marrow-derived mesenchymal stem cells in patients with idiopathic pulmonary fibrosis. METHODS: Nine patients with mild to moderate IPF were sequentially assigned to 1 of 3 cohorts and dosed with a single IV infusion of 20, 100, or 200 × 106 human bone marrow-derived mesenchymal stem cells per infusion from young, unrelated, men. All baseline patient data were reviewed by a multidisciplinary study team to ensure accurate diagnosis. The primary end point was the incidence (at week 4 postinfusion) of treatment-emergent serious adverse events, defined as the composite of death, nonfatal pulmonary embolism, stroke, hospitalization for worsening dyspnea, and clinically significant laboratory test abnormalities. Safety was assessed until week 60 and additionally 28 days thereafter. Secondary efficacy end points were exploratory and measured disease progression. RESULTS: No treatment-emergent serious adverse events were reported. Two nontreatment-related deaths occurred because of progression of IPF (disease worsening and/or acute exacerbation). By 60 weeks postinfusion, there was a 3.0% mean decline in % predicted FVC and 5.4% mean decline in % predicted diffusing capacity of the lungs for carbon monoxide. CONCLUSIONS: Data from this trial support the safety of a single infusion of human mesenchymal stem cells in patients with mild-moderate IPF. TRIAL REGISTRY: ClinicalTrials.gov; No.: NCT02013700; URL: www.clinicaltrials.gov.

Bone marrow is a reservoir for CD4+CD25+ regulatory T cells that traffic through CXCL12/CXCR4 signals.

CD4(+)CD25(+) regulatory T cells (Tregs) mediate peripheral T-cell homeostasis and contribute to self-tolerance. Their homeostatic and pathologic trafficking is poorly understood. Under homeostatic conditions, we show a relatively high prevalence of functional Tregs in human bone marrow. Bone marrow strongly expresses functional stromal-derived factor (CXCL12), the ligand for CXCR4. Human Tregs traffic to and are retained in bone marrow through CXCR4/CXCL12 signals as shown in chimeric nonobese diabetic/severe combined immunodeficient mice. Granulocyte colony-stimulating factor (G-CSF) reduces human bone marrow CXCL12 expression in vivo, associated with mobilization of marrow Tregs to peripheral blood in human volunteers. These findings show a mechanism for homeostatic Treg trafficking and indicate that bone marrow is a significant reservoir for Tregs. These data also suggest a novel mechanism explaining reduced acute graft-versus-host disease and improvement in autoimmune diseases following G-CSF treatment.

Signal transduction pathways involved in the lineage-differentiation of NSCs: can the knowledge gained from blood be used in the brain?

Neural stem cells (NSC) are capable of differentiating toward neuronal, astrocytic, oligodendrocytic and glial lineages, depending on their spatial location within the central nervous system (CNS). Although, a lot of knowledge has been gained in the understanding of differentiation-specific signaling in hematopoietic (HSC) and mesenchymal (MSC) counterparts, the molecular mechanisms underlying lineage commitment in NSCs are just beginning to be understood. Furthermore, it is not well comprehended as to how the specification of one cell lineage can result in the suppression of parallel pathways in the NSCs. Thus, a thorough understanding of various signal transduction cascades activated via cytokines and growth factors, and the confounding effects of different CNS microenvironments are critically required to determine the full potential of NSCs. Our knowledge on the clonogenic ability, differentiation potential, and the inherent plasticity in both HSCs and MSCs may facilitate the understanding of lineage commitment in the NSCs as well. The information available from the marrow-derived stem cells may be extrapolated toward the similar signaling pathways in the neural precursors. From a number of previous studies, it is apparent that four distinctly different subsets of ligand-receptor superfamilies are involved in determining the fate of NSCs. These include 1) the transforming growth factor type-beta-1 (TGF-beta1) and bone morphogenetic protein (BMP) superfamily; 2) the platelet-derived and epidermal (PDGF/EGF) growth factors; 3) the interleukin-6, leukemia inhibitory factor, and ciliary neurotrophic factor (IL-6/LIF/CNTF) superfamily; and 4) the EGF-like Notch/Delta group of extracellular ligands. Ligand binding to the cell surface receptor activates the receptor's cytosolic catalytic domain and/or the receptor-associated protein-kinases, which in turn activate intracellular second messengers and different sets of transcription factors. Transcription factor oligomerization, nuclear localization, followed by their recognition of DNA elements, leads to the expression of lineage-specific genes. Association between different groups of transcription factors can also regulate their ability to transcriptionally activate different genes. The limited availability of coactivators and cosuppressors, which can sequester the transcription factor complexes toward or away from a specific gene locus, further adds to the complexity in the cross talk between different signaling cascades. Both concerted actions of temporally regulated signals and convergent effects of different signaling cascades can thus ultimately precipitate the phenotypic changes. It is beginning to be realized that in addition to the cytokines and growth factors, cell-to-cell and cell-to-extracellular matrix (ECM) interactions, are also important within the molecular scenario linked to both proliferation and differentiation of the stem cells. The cell surface molecules, which include cell adhesion molecules (CAMs), integrins, selectins, and the immunoglobulins, are well known to regulate HSC and MSC commitment within different tissue microenvironments and may have direct implications in understanding the NSC cell fate determination within different regions of the brain.

Effects of amifostine on clonogenic mesenchymal progenitors and hematopoietic progenitors exposed to radiation.

PURPOSE: To determine the radiation sensitivities of mesenchymal progenitors and hematopoietic progenitors, and to determine the in vitro effects of amifostine on hematopoietic and mesenchymal progenitors exposed to radiation. METHODS: Radiosensitivity of mesenchymal progenitor cells was determined by exposing marrow low-density cells to radiation at doses of 100 to 800 cGy. Mesenchymal cell colonies were established by plating 2.5 x 10(5) marrow low-density cells in long-term marrow culture medium (LTCM). The size, frequency, and cellular composition of the mesenchymal progenitor cells were scored after 14 days of incubation. Mesenchymal progenitor cells were subdivided into progenitors forming fibroblast and adipocyte mixed colonies (CFU-FA), and pure fibroblast colonies (CFU-F). Hematopoietic progenitors were assessed by methylcellulose-based assay. RESULTS: Radiation at 100 cGy caused a mild decrease in CFU-F and CFU-FA derived colonies by 12% and 13%, respectively; 200 cGy decreased CFU-F by 36% and CFU-FA by 52%; 400 cGy decreased CFU-F by 50% and CFU-FA by 86%; and 600 cGy decreased CFU-F by 24%, with total absence of CFU-FA. Pretreatment with amifostine protected 100% of CFU-F at 100 and 200 cGy, 84% at 400 cGy, 46% at 600 cGy, and 14% at 800 cGy. With CFU-FA colonies amifostine pretreatment provided only minimal radioprotection. For hematopoietic progenitors radiation at 100 cGy reduced CFU-GM by 74% but had no significant effect on CFU-GEMM and BFU-E. Radiation at 200 cGy decreased CFU-GEMM by 72%, BFU-E by 54%, and CFU-GM by 84%; 400 cGy further decreased CFU-GEMM by 83%, BFU-E by 81%, and CFU-GM by 93%. Pretreatment with amifostine resulted in twofold stimulation of CFU-GEMM and BFU-E colonies. All BFU-E colonies were protected up to 200 cGy. For CFU-GEMM amifostine pretreatment resulting in 68% at 200 cGy and 31% at 400 cGy. For CFU-GM colonies it was 54% at 100 cGy, 32% at 200 cGy, and 12% at 400 cGy. CONCLUSIONS: Mesenchymal progenitor cell subpopulations are differentially sensitive to radiation. Amifostine protects both mesenchymal and hematopoietic progenitors against radiation injury, though the level of protection appears to be dependent upon the sensitivities of these progenitor cells to radiation. Amifostine is a potent stimulant of BFU-E and CFU-GEMM progenitor colonies.

Vascular follicle system of the sea cucumber, Stichopus moebii.

Sea cucumbers, Stichopus moebii, have a unique specialization of their blood vascular system: The vascular follicle network is composed of numerous small chambers (follicles) interconnected by minute vessels. The fine structure of the follicle system was studied in detail. The follicles are composed of several layers: an external ciliated epithelium, neuromuscular layer and basement membrane, connective tissue, and a fenestrated endothelial lining. The follicle lumen is filled with coelomocytes and necrotic cells surrounding particles of iron. The follicle may function in coelomocyte production and destruction.

Blood vascular system of the sea cucumber, Stichopus moebii.

Stichopus moebii, a sea cucumber, has a closed circulatory system which is unique in its degree of development for the phylum Echinodermata. The gross anatomy, histology and fine structure of the system were studied. Blood vessels consist of a coelomic surface of ciliated epithelium, a layer of muscle and nerve cells, followed by connective tissue and luminal lining of endothelium. Basically the blood vascular system consists of two major vessels running parallel to the gut: the dorsal vessel pumps colorless blood via the vessels within the walls of the intestine into the ventral vessel. There are two specialized areas of the circulation: (1) At the upper small intestine 120 to 150 muscular single-chambered hearts pump blood from the dorsal vessel into a series of intestinal plates. (2) At the lower region of the small intestine the vasculature is associated with the left respiratory tree. Blood passing from the dorsal pulmonary vessel can take two routes to the gut, it either passes through myriads of minute respiratory shunt vessels entangled with the respiratory tree or it passes through a unique follicle network consisting of tiny channels periodically dilated into chambers filled with iron deposits, necrotic cells and developing coelomocytes.