Therapeutic Effects Of Mesenchymal Stromal Cells Research Articles

Challenges in Mesenchymal Stromal Cell-based Therapies.

Over 50 years have passed since discovering mesenchymal stromal cells (MSCs). Initially, despite gaps in the knowledge of the identity of these cells, their therapeutic aspects were recognized. Consequently, MSCs became candidates for treating a wide range of diseases. However, the therapeutic effects of MSCs are not stable in the long term, and there are inconsistent data on their clinical efficacy. Even though more than 1000 MSC-based clinical trials have been registered, and the safety of MSCbased cell therapies has been proven, data on the clinical efficacy of MSCs have not been enough to warrant FDA approval for clinical treatment and marketing purposes. The available information on MSCs still contains some controversies, perhaps owing to little progress in understanding their in vivo identity. MSCs have been used for therapeutic purposes despite poor knowledge of their in vivo origin or functions. Hence, perhaps we need to go back to the basics of MSCs and spend more time understanding the biology of these cells. An improved understanding of MSCs' location and function within tissues may improve their therapeutic efficacy and, consequently, their establishment as a cell therapy product.

Understanding the effects of mesenchymal stromal cell therapy for treating osteoarthritis using an in vitro co-culture model.

Osteoarthritis (OA) is a leading cause of chronic pain and disability, for which there is no cure. Mesenchymal stromal cells (MSCs) have been used in clinical trials for treating OA due to their unique ability to generate paracrine anti-inflammatory and trophic signals. Interestingly, these studies have shown mainly short-term effects of MSCs in improving pain and joint function, rather than sustained and consistent benefits. This may reflect a change or loss in the therapeutic effects of MSCs after intra-articular injection. The present study aimed to unravel the reasons behind the variable efficacy of MSC injections for OA using an in vitro co-culture model. Osteoarthritic human synovial fibroblasts (OA-HSFs) were co-cultured with MSCs to investigate their reciprocal effects on cell responses and whether a short-term exposure of OA cells to MSCs was sufficient for reducing their diseased characteristics in a sustained manner. Gene expression and histological analyses were performed. OA-HSFs exposed to MSCs showed short-term downregulation of inflammatory markers. However, the MSCs showed upregulation of inflammatory markers and impaired ability to undergo osteogenesis and chondrogenesis in the presence of OA-HSFs. Moreover, short-term exposure of OA-HSFs to MSCs was found to be insufficient for inducing sustained changes to their diseased behaviour. These findings suggested that MSCs may not provide long-term effects in correcting the OA joint environment due to them adopting the diseased phenotype of the surrounding tissues, which has important implications for the future development of effective stem-cell-based OA treatments with long-term therapeutic efficacy.

Mesenchymal stromal cells alleviate acute respiratory distress syndrome through the cholinergic anti-inflammatory pathway

Mesenchymal stromal cells (MSCs) have been considered a promising alternative for treatment of acute respiratory distress syndrome (ARDS). However, there is significant heterogeneity in their therapeutic efficacy, largely owing to the incomplete understanding of the mechanisms underlying the therapeutic activities of MSCs. Here, we hypothesize that the cholinergic anti-inflammatory pathway (CAP), which is recognized as a neuroimmunological pathway, may be involved in the therapeutic mechanisms by which MSCs mitigate ARDS. Using lipopolysaccharide (LPS) and bacterial lung inflammation models, we found that inflammatory cell infiltration and Evans blue leakage were reduced and that the expression levels of choline acetyltransferase (ChAT) and vesicular acetylcholine transporter (VAChT) in lung tissue were significantly increased 6 hours after MSC infusion. When the vagus nerve was blocked or α7 nicotinic acetylcholine (ACh) receptor (α7nAChR)-knockout mice were used, the therapeutic effects of MSCs were significantly reduced, suggesting that the CAP may play an important role in the effects of MSCs in ARDS treatment. Our results further showed that MSC-derived prostaglandin E2 (PGE2) likely promoted ACh synthesis and release. Additionally, based on the efficacy of nAChR and α7nAChR agonists, we found that lobeline, the nicotinic cholinergic receptor excitation stimulant, may attenuate pulmonary inflammation and alleviate respiratory symptoms of ARDS patients in a clinical study (ChiCTR2100047403). In summary, we reveal a previously unrecognized MSC-mediated mechanism of CAP activation as the means by which MSCs alleviate ARDS-like syndrome, providing insight into the clinical translation of MSCs or CAP-related strategies for the treatment of patients with ARDS.

Mesenchymal Stromal Cell-Derived Extracellular Vesicles for Neonatal Lung Disease: Tiny Particles, Major Promise, Rigorous Requirements for Clinical Translation

Extreme preterm birth disrupts late lung development and puts newborns at risk of developing chronic lung disease, known as bronchopulmonary dysplasia (BPD). BPD can be associated with life-long complications, and currently no effective treatment is available. Cell therapies are entering the clinics to curb complications of extreme preterm birth with several clinical trials testing the feasibility, safety and efficacy of mesenchymal stromal cells (MSCs). The therapeutic effect of MSCs is contained in their secretome, and nanosized membranous structures released by the MSCs, known as extracellular vesicles (EVs), have been shown to be the therapeutic vectors. Driven by this discovery, the efficacy of EV-based therapy is currently being explored in models of BPD. EVs derived from MSCs, contain a rich cargo of anti-inflammatory and pro-angiogenic molecules, making them suitable candidates to treat multifactorial diseases such as BPD. Here, we review the state-of-the-art of preclinical studies involving MSC-derived EVs in models of BPD and highlight technical and regulatory challenges that need to be addressed before clinical translation. In addition, we aim at increasing awareness regarding the importance of rigorous reporting of experimental details of EV experiments and to increase the outreach of the current established guidelines amongst researchers in the BPD field.

Immunophenotypic characterization and therapeutics effects of human bone marrow- and umbilical cord-derived mesenchymal stromal cells in an experimental model of sepsis

Sepsis is a complicated multi-system disorder characterized by a dysregulated host response to infection. Despite substantial progress in the understanding of mechanisms of sepsis, translation of these advances into clinically effective therapies remains challenging. Mesenchymal Stromal Cells (MSCs) possess immunomodulatory properties that have shown therapeutic promise in preclinical models of sepsis. The therapeutic effects of MSCs may vary depending on the source and type of these cells. In this comparative study, the gene expression pattern and surface markers of bone marrow-derived MSCs (BM-MSCs) and umbilical cord-derived MSCs (UC-MSCs) as well as their therapeutic effects in a clinically relevant mouse model of polymicrobial sepsis, cecal ligation and puncture (CLP), were investigated. The results showed remarkable differences in gene expression profile, surface markers and therapeutic potency in terms of enhancing survival and pro/anti-inflammatory responses between the two MSC types. BM-MSCs improved survival concomitant with an enhanced systemic bacterial clearance and improved inflammatory profile post CLP surgery. Despite some improvement in the inflammatory profile of the septic animals, treatment with UC-MSCs did not enhance survival or bacterial clearance. Overall, the beneficial therapeutic effects of BM-MSCs over UC-MSCs may likely be attributed to their pro-inflammatory function, and to some extent anti-inflammatory features, reflected in their gene expression pattern enhancing macrophage polarization to M1/M2 phenotypes resulting in a balanced pro- and anti-inflammatory response against polymicrobial sepsis.

Reparative effect of mesenchymal stromal cells on endothelial cells after hypoxic and inflammatory injury

BackgroundThe renal endothelium is a prime target for ischemia-reperfusion injury (IRI) during donation and transplantation procedures. Mesenchymal stromal cells (MSC) have been shown to ameliorate kidney function after IRI. However, whether this involves repair of the endothelium is not clear. Therefore, our objective is to study potential regenerative effects of MSC on injured endothelial cells and to identify the molecular mechanisms involved.MethodsHuman umbilical vein endothelial cells (HUVEC) were submitted to hypoxia and reoxygenation and TNF-α treatment. To determine whether physical interaction or soluble factors released by MSC were responsible for the potential regenerative effects of MSC on endothelial cells, dose-response experiments were performed in co-culture and transwell conditions and with secretome-deficient MSC.ResultsMSC showed increased migration and adhesion to injured HUVEC, mediated by CD29 and CD44 on the MSC membrane. MSC decreased membrane injury marker expression, oxidative stress levels, and monolayer permeability of injured HUVEC, which was observed only when allowing both physical and paracrine interaction between MSC and HUVEC. Furthermore, viable MSC in direct contact with injured HUVEC improved wound healing capacity by 45% and completely restored their angiogenic capacity. In addition, MSC exhibited an increased ability to migrate through an injured HUVEC monolayer compared to non-injured HUVEC in vitro.ConclusionsThese results show that MSC have regenerative effects on injured HUVEC via a mechanism which requires both physical and paracrine interaction. The identification of specific effector molecules involved in MSC-HUVEC interaction will allow targeted modification of MSC to apply and enhance the therapeutic effects of MSC in IRI.

Microencapsulation of small extracellular vesicles with nanoporous biomaterials results in a sustained-release preparation to enhance targeting and persistence after intravascular delivery

Background & Aim Mesenchymal stromal cells (MSCs) have shown promise as therapy for treatment of cardiovascular disease. The therapeutic effect of MSCs is predominately paracrine, involving the release of small ( Methods, Results & Conclusion MSC-derived small EVs were collected during 24h of serum-free culture and purified using sequential ultracentrifugation or tangential flow filtration. ZetaView nanoparticle tracking revealed a population of small EVs having a median size of 108±53 nm, positive for the tetraspanin CD63 by Western blot analysis. Pkh26 membrane labelling of small EVs had negligible impact on EV size (median size 102±42 nm). Agarose (2%) or agarose-gelatin (1%-1%) microgels were formed using vortex-emulsion or microfluidic encapsulation, resulting microgels of differing size (34±15 mm and 59±3 mm, respectively). Free EVs, EV-loaded microgels, or empty microgels were plated with human umbilical vein endothelial cells (HUVEC) and time-lapse imaging over 48h demonstrated transfer of EVs from microgels to HUVEC. While by 48h free EVs were readily taken up by HUVECs, encapsulated EVs demonstrated a slower uptake during this period (64% vs 26% cells/FOV), consistent with sustained release kinetics. Biodegradability of microgels was assessed in vivo using the rat monocrotaline (MCT) model of pulmonary arterial hypertension. Three days post MCT empty microgels were delivered by intrajugular injection. Right ventricular systolic pressure was assessed at day 1, 3 and 7. IV delivery of 500,000 agarose-gelatin or agarose microgels had no impact on right ventricular systolic pressure compared to vehicle (saline). Gelatin-agarose microgels demonstrated >2-fold more rapid degradation and clearance from the pulmonary vascular bed from day 1 through to day 7 post compared with agarose microgels. Microencapsulation of small EVs in nanoporous biomaterials produces microgels which are efficiently trapped in the microcirculation with tunable release of EVs depending on biomaterial composition and gel degradation rate.

Mesenchymal stromal cells for the prophylaxis and treatment of graft-versus-host disease\u2014a meta-analysis

BackgroundGraft-versus-host disease (GvHD) is the main life-threatening complication of allogeneic hematopoietic stem cell transplantation (HSCT). Thirty to 80% of GvHD patients do not respond to first-line treatment and a second-line treatment is not universally established. Based on their immunomodulatory properties, mesenchymal stromal cells (MSC) have been proposed for the prevention and the treatment of GvHD in patients undergoing HSCT. Unfortunately, previous studies reported conflicting results regarding the prophylactic and therapeutic effects of MSC for GvHD. Consequently, we carried out a meta-analysis to clarify whether MSC administration can improve the dismal outcome of these patients.MethodsWe carried out a systematic review and selected studies (2004–2019) reporting data about the administration of allogeneic MSC for the prevention (n = 654 patients) or treatment of acute (n = 943 patients) or chronic (n = 76 patients) GvHD after HSCT. Our primary outcome was overall survival at the last follow-up. The secondary outcomes were the response and development of GvHD. Subgroup analyses included age, MSC dose, first infusion day after HSCT, number of organs and organ-specific involvement, acute GvHD grade (I–IV), and chronic GvHD grade (limited or extensive).ResultsPatients infused with MSC for GvHD prophylaxis showed a 17% increased overall survival (95% CI, 1.02–1.33) and a reduced incidence of acute GvHD grade IV (RR = 0.22; 95% CI, 0.06–0.81) and chronic GvHD (RR = 0.64; 95% CI, 0.47–0.88) compared with controls. Overall survival of acute GvHD patients (0.50; 95% CI, 0.41–0.59) was positively correlated with MSC dose (P = 0.0214). The overall response was achieved in 67% (95% CI, 0.61–0.74) and was complete in 39% (95% CI, 0.31–0.48) of acute patients. Organ-specific response was higher for the skin. Twenty-two percent (95% CI, 0.16–0.29) of acute patients infused with MSC developed chronic GvHD. Sixty-four percent (95% CI, 0.47–0.80) of chronic patients infused with MSC survived; the overall response was 66% (95% CI, 0.55–0.76) and was complete in 23% (95% CI 0.12–0.34) of patients.ConclusionsOur meta-analysis indicates that allogeneic MSC could be instrumental for the prophylaxis and treatment of GvHD. Future trials should investigate the effect of the administration of MSC as an adjuvant therapy for the treatment of patients with GvHD from the onset of the disease.

Mesenchymal Stromal Cells Anno 2019: Dawn of the Therapeutic Era? Concise Review.

Summary2018 was the year of the first marketing authorization of an allogeneic stem cell therapy by the European Medicines Agency. The authorization concerns the use of allogeneic adipose tissue‐derived mesenchymal stromal cells (MSCs) for treatment of complex perianal fistulas in Crohn's disease. This is a breakthrough in the field of MSC therapy. The last few years have, furthermore, seen some breakthroughs in the investigations into the mechanisms of action of MSC therapy. Although the therapeutic effects of MSCs have largely been attributed to their secretion of immunomodulatory and regenerative factors, it has now become clear that some of the effects are mediated through host phagocytic cells that clear administered MSCs and in the process adapt an immunoregulatory and regeneration supporting function. The increased interest in therapeutic use of MSCs and the ongoing elucidation of the mechanisms of action of MSCs are promising indicators that 2019 may be the dawn of the therapeutic era of MSCs and that there will be revived interest in research to more efficient, practical, and sustainable MSC‐based therapies. stem cells translational medicine 2019;8:1126–1134

Improvement of mesenchymal stromal cells and their derivatives for treating acute liver failure.

After the death of large numbers of cells in liver tissue is triggered by various hepatotoxic factors, intimidating and life-threatening acute liver failure (ALF) can develop with high mortality and expensive costs. Although liver transplantation and hepatocyte transplantation have become substitutes for improving liver regeneration, their applications are inhibited by scarce tissue and cell resources. Therefore, the transplantation of mesenchymal stromal cells (MSCs) and their derivatives including hepatocyte-like cells (HLCs), conditioned medium (CM), and exosomes (Ex) can help alleviate liver injury in ALF individuals or animal models via engraftment into liver tissue, hepatogenic differentiation, the promotion of host hepatocyte proliferation, the secretion of anti-inflammatory factors and antioxidants, and the enhancement of liver regeneration in vivo. In addition, biomaterial scaffolds protect MSCs against a harsh microenvironment in vitro and in vivo, in addition to providing physical and directional support for liver regeneration. In this review, we aimed to discuss the underlying mechanisms and therapeutic effects of MSCs and their derivatives on rescuing ALF animal models according to current studies. Further breakthroughs are required to establish safer, more stable, and more effective stem cell-based therapy in regenerative medicine for repairing liver injury, thus reducing the morbidity and mortality of ALF in the near future.

Bioactive factors secreted from mesenchymal stromal cells protect the intestines from experimental colitis in a three-dimensional culture

Background aimsAlthough mesenchymal stromal cells (MSCs) have shown therapeutic potential in intestinal tissue repair, controversy concerning their short survival and poor biodistribution in recipient tissues still remains. Therefore, we investigated the paracrine role of MSC in three-dimensional culture of colon with experimental colitis. MethodsColitis was induced in mice by oral administration of dextran sulfate sodium (DSS) for 7 days. Inflammatory responses were assessed on the basis of clinical signs, morphological, and histopathological parameters. On days 2 and 5, colonic explants were removed, and a three-dimensional culture was performed. The structural integrity of the intestinal mucosa was tested by treating the cultures with MSC or conditioned medium (CM) for 24 h, and then the colons were analyzed for histology/immunohistochemistry and interleukin (IL)-6 production. ResultsHistological analysis demonstrated that both MSC and CM treatment reduced colon damage in organ culture. An increase in cell proliferation (Ki-67 staining) was observed after CM treatment. Additionally, MSC treatment was able to reduce CD3+ cells. The therapeutic effect of MSC and CM was mediated by the downregulation of IL-6. DiscussionThe intestinal in vitro model has shown to be potentially useful for studying cellular interactions in a three-dimensional cell arrangement. Moreover, our results provide strong evidence that both MSC and CM treatments can alleviate colonic damage in organ culture. Importantly, these results suggest that MSC-secreted factors are able to protect the colon from inflammation caused by DSS-induced colitis independent of cell transplantation.

Hypoxia-Induced Mesenchymal Stromal Cells Exhibit an Enhanced Therapeutic Effect on Radiation-Induced Lung Injury in Mice due to an Increased Proliferation Potential and Enhanced Antioxidant Ability

Background/Aims: Radiation therapy is an important treatment for thoracic cancer; however, side effects accompanied with radiotherapy lead to limited tumor control and a decline in patient quality of life. Among these side effects, radiation-induced lung injury (RILI) is the most serious and common. Hence, an effective remedy for RILI is needed. Mesenchymal stromal cells (MSCs) are multipotent adult stem cells that have been demonstrated to be an effective treatment in some disease caused by tissue damage. However, unlike other injuries, RILI received limited therapeutic effects from implanted MSCs due to local hypoxia and extensive reactive oxygen species (ROS) in irradiated lungs. Since the poor survival of MSCs is primarily due to hypoxia and ROS generation, we hypothesize that persistent and adaptive hypoxia treatment induces enhanced resistance to hypoxic stress in implanted MSC. The aim of this study is to investigate whether persistent and adaptive hypoxia treatment of bmMSCs prior to their transplantation in injured mice enhanced survival and improved curative effects in RILI. Methods: Primary bmMSCs were obtained from the marrow of six-week-old male C57BL6/J mice and were cultured either under normoxic conditions (21% O₂) or hypoxic conditions (2.5% O₂). Mice were injected with normoxia/hypoxia MSCs after thoracic irradiation (20 Gy). The therapeutic effects of MSCs on RILI were assessed by pathological examinations that included H&E staining, Masson staining and α-SMA staining; meanwhile, inflammatory factors were measured using an ELISA. The morphology of MSCs in vitro was recorded using a microscope and identified by flow cytometry, cell viability was measured using the CCK-8 assay, the potential for proliferation was detected by the EdU assay, and ROS levels were measured using a ROS fluorogenic probe. In addition, HIF-1α and several survival pathway proteins (Akt, p-Akt, Caspase-3) were also detected by western blotting. Results: Implanted MSCs alleviated both early radiation-induced pneumonia and late pulmonary fibrosis. However, hypoxia MSCs displayed a more pronounced therapeutic effect compared to normoxia MSCs. Compared to normoxia MSCs, the hypoxia MSCs demonstrated greater cell viability, an enhanced proliferation potential, decreased ROS levels and increased resistance to hypoxia and ROS stress. In addition, hypoxia MSCs achieved higher activation levels of HIF-1α and Akt, and HIF-1α played a critical role in the development of resistance. Conclusion: Hypoxia enhances the therapeutic effect of mesenchymal stromal cells on radiation-induced lung injury by promoting MSC proliferation and improving their antioxidant ability, mediated by HIF-1α.

Mesenchymal stromal cell secretomes are modulated by suspension time, delivery vehicle, passage through catheter, and exposure to adjuvants

Background aimsExtensive animal data indicate that mesenchymal stromal cells (MSCs) improve outcome in stroke models. Intra-arterial (IA) injection is a promising route of delivery for MSCs. Therapeutic effect of MSCs in stroke is likely based on the broad repertoire of secreted trophic and immunomodulatory cytokines produced by MSCs. We determined the differential effects of exposing MSCs to different types of clinically relevant vehicles, and/or different additives and passage through a catheter relevant to IA injections. MethodsMSCs derived from human bone marrow were tested in the following vehicles: 5% albumin (ALB), 6% Hextend (HEX) and 40% dextran (DEX). Each solution was tested (i) alone, (ii) with low-dose heparin, (iii) with 10% Omnipaque, or (iv) a combination of heparin and Omnipaque. Cells in vehicles were collected directly or passed through an IA catheter, and MSC viability and cytokine release profiles were assessed. ResultsCell viability remained above 90% under all tested conditions with albumin being the highest at 97%. Viability was slightly reduced after catheter passage or exposure to heparin or Omnipaque. Catheter passage had little effect on MSC cytokine secretion. ALB led to increased release of angiogenic factors such as vascular endothelial growth factor compared with other vehicles, while HEX and DEX led to suppression of pro-inflammatory cytokines such as interleukin-6. However, when these three vehicles were subjected to catheter passage and/or exposure to additives, the cytokine release profile varied depending on the combination of conditions to which MSCs were exposed. DiscussionExposure of MSCs to certain types of vehicles or additives changes the profile of cytokine secretion. The activation phenotype of MSCs may therefore be affected by the vehicles used for these cells or the exposure to the adjuvants used in their administration.

Mesenchymal niche: the sensor and effector of leukemogenesis.

Mesenchymal stromal cells (MSCs) are nonhematopoietic adherent cell populations in the bone marrow (BM) that exhibit multilineage differentiation potential towards diverse types of tissues. These MSCs are widely used for cell-therapy applications to stimulate injured tissues regeneration. The therapeutic effects of MSCs are primarily exerted through their paracrine secretion of various factors that can stimulate the regenerative potential of endogenous stem cells, promote angiogenesis, and inhibit apoptosis [1]. While ex-vivo expanded MSCs have been widely used for cell-therapy trials, the in vivo identity of these MSCs has been suggested to be a subset of pericytes, and they were demonstrated to be able to reconstitute both endosteal and the perivascular in heterologous implantation studies [2]. While geographically distinct, the perivascular and endosteal in BM exhibit both distinct and common characteristics in cellular entities and cross-talk molecules, comprising primarily of MSCs, endothelial cells, and some cells with neuronal origin [3]. Moreover, recent studies have further identified complex heterogeneity in the cellular entity of the mesenchymal niche. For example, studies have identified early-stage osteoblastic cells expressing runt-related transcription factor 2 (runx2), subsets of MSCs in perivascular regions expressing nestin and leptin-receptor, and primitive (prx-1+) mesenchymal cells expressing C-X-C motif chemokine 12 (CXCL-12) as key functional cells in the niche. These cells express cross-talk molecules such as Jagged-1, CXCL-12, and angiopoietin-1 in order to interact with hematopoietic stem cells (HSCs). Thus, fine orchestration of this microenvironmental cross-talk exerts a key influence on HSCs, controlling their self-renewal, quiescence, and mobilization. While accumulating studies have established the functional impact of the mesenchymal cell in regulating normal HSCs, emerging interest is now focusing on its significance for leukemia stem cells (LSCs), the malignant counterpart of normal HSCs. The key question being addressed is whether the is affected under conditions and, in turn, whether the executes any functions in the leukemogenic process itself. The possible involvement of the in leukemogenesis was first suggested by the observation that LSCs, when transplanted into mice, engraft in BM and competes with normal HSCs [4]. Moreover, leukemia cells transplanted into mice create an abnormal in BM to usurp the transplanted normal HSCs into a tumor [5], suggesting the functional impact of leukemia cells on the niche. Recently, studies have shown that leukemia cells can alter the condition of the mesenchymal in an animal leukemia model, i.e., a transgenic model of chronic myeloid leukemia exhibits defective homing and retention of HSCs in the because of decreased CXCL12 in BM MSCs [6]. Similarly, studies on bcr-abl-transformed leukemia revealed alterations of MSCs and osteoblastic cells during the leukemogenesis [7]. Thus, it appears that the mesenchymal is certainly influenced, under the leukemogenic conditions, to bring about new concept of the leukemic niche that is established by alteration of the normal mesenchymal niche. On the other hand, several experimental studies also raised the possibility that the mesenchymal itself contributes to the leukemogenic process. For example, a higher incidence of myeloproliferative disease was observed in mice when the BM stroma was disrupted with retinoic acid-γ [8] or retinoblastoma [9]. Although these animal models have not clarified a molecular basis for developing and/or expanding the cells, these observations, at least, present the possibility that the microenvironment could also be a driving force in the leukemogenic process. Of note, while most insight was obtained from a series of animal leukemia models, recent studies by our group and others revealed that clinical models of human leukemia exhibit similar alterations in the mesenchymal [10]. This study shows that the mesenchymal in patients undergoes extensive functional and transcriptomic alteration accompanied by the alteration in cross-talk molecules. The altered had a functional impact on the BM microenvironment, leading to selective expansion of leukemia cells while suppressing normal HSCs. Thus, the emerging insights into the indicate that leukemia cells reprogram the mesenchymal to reinforce their own leukemogenesis, leading to the clonal dominance of cells over the normal hematopoietic process. Interestingly, the study by Kim et al. [10] recently demonstrated that the heterogeneity in microenvironmental remodeling can be a parameter for heterogeneous clinical courses in acute myeloid leukemia patients, suggesting that the stromal patterns in leukemia BM can serve as a predictor of prognosis. Based on these collective insights, it appears that MSCs are the responding cells being targeted under the conditions, but also take up a role as active effectors in the leukemogenic process. Accordingly, the mesenchymal represents an attractive target for therapy against various hematological diseases. Microenvironmentbased therapeutic planning will broaden the horizon for more personalized, biological approaches to efficient leukemia treatment by targeting the specific leukemogenic process in the niche.

Optimization of the therapeutic efficacy of human umbilical cord blood-mesenchymal stromal cells in a NSG mouse xenograft model of graft-versus-host disease

Although in vitro studies have demonstrated the immunosuppressive capacity of mesenchymal stromal cells (MSCs), most in vivo studies on graft-versus-host disease (GVHD) have focused on prevention, and the therapeutic effect of MSCs is controversial. Moreover, optimal time intervals for infusing MSCs have not been established.

Optimization of the therapeutic efficacy of human umbilical cord blood–mesenchymal stromal cells in an NSG mouse xenograft model of graft-versus-host disease

Background aimsAlthough in vitro studies have demonstrated the immunosuppressive capacity of mesenchymal stromal cells (MSCs), most in vivo studies on graft-versus-host disease (GVHD) have focused on prevention, and the therapeutic effect of MSCs is controversial. Moreover, optimal time intervals for infusing MSCs have not been established. MethodsWe attempted to evaluate whether human umbilical cord blood–MSCs (hUCB-MSCs) could either prevent or treat GVHD in an NSG mouse xenograft model by injection of MSCs before or after in vivo clearance. Mice were infused with either a single dose or multiple doses of 5 × 105 hUCB-MSCs (3- or 7-day intervals) before or after GVHD onset. ResultsBefore onset, hUCB-MSCs significantly improved the survival rate only when repeatedly injected at 3-day intervals. In contrast, single or repeated injections after GVHD onset significantly increased the survival rate and effectively attenuated tissue damage and inflammation. Furthermore, the levels of prostaglandin E2 and transforming growth factor-β1 increased significantly, whereas the level of interferon-γ decreased significantly in all MSC treatment groups. ConclusionsThese data establish the optimal time intervals for preventing GVHD and show that hUCB-MSCs effectively attenuated symptoms and improved survival rate when administered after the onset of GVDH.