Bone marrow‐derived cells can acquire cardiac stem cells properties in damaged heart

Experimental data suggest that cell‐based therapies may be useful for cardiac regeneration following ischaemic heart disease. Bone marrow (BM) cells have been reported to contribute to tissue repair after myocardial infarction (MI) by a variety of humoural and cellular mechanisms. However, there is no direct evidence, so far, that BM cells can generate cardiac stem cells (CSCs). To investigate whether BM cells contribute to repopulate the Kit⁺ CSCs pool, we transplanted BM cells from transgenic mice, expressing green fluorescent protein under the control of Kit regulatory elements, into wild‐type irradiated recipients. Following haematological reconstitution and MI, CSCs were cultured from cardiac explants to generate ‘cardiospheres’, a microtissue normally originating in vitro from CSCs. These were all green fluorescent (i.e. BM derived) and contained cells capable of initiating differentiation into cells expressing the cardiac marker Nkx2.5. These findings indicate that, at least in conditions of local acute cardiac damage, BM cells can home into the heart and give rise to cells that share properties of resident Kit⁺ CSCs.     

基因谱系示踪技术揭示小鼠Tbx18+心脏祖细胞向心系细胞分化的潜能

心脏祖细胞(cardiac progenitor cells,CPCs)的研究对阐明先天性心脏病的机制及治疗心血管疾病具有重要意义.哺乳动物的心脏组织由多种不同CPCs分化形成.转录因子Tbx18在发育中的心外膜中表达,对心脏的发育形成起重要的调节作用.为了在组织及活体细胞水平检测和阐明Tbx18+CPC的分化潜能,应用Cre-LoxP系统建立Tbx18+CPCs基因命运谱系示踪模型:Tbx18-Cre/Rosa26R-EYFP和Tbx18-Cre/Rosa26R-LacZ双杂合基因敲入小鼠.该双杂合基因敲入小鼠通过Cre的表达能有效地示踪Tbx18+细胞在胚胎和成年小鼠中的分化命运.Tbx18-Cre/Rosa26R-EYFP双杂合小鼠心脏能非常容易地利用流式细胞分选系统(FACS)分离出YFP+细胞,也可在倒置共聚焦显微镜下观察.应用X-gal染色分析其表达模式,揭示Tbx18命运谱系参与心房肌、室间隔、心室肌、冠状动脉、瓣膜等的形成.应用免疫荧光技术初步揭示Tbx18+CPCs向心脏肌钙蛋白T(cTNT)阳性心肌细胞和平滑肌肌球蛋白重链11(MYH11)阳性血管平滑肌细胞分化的潜能.心脏是一个由多种肌肉和非肌肉组织细胞构成的复杂器官.推测Tbx18可能在心脏祖细胞向肌源性细胞分化的信号通路中起重要调节作用.在上述研究中应用基因谱系示踪技术,验证Tbx18可作为一类CPCs的标志,为更深入揭示心脏祖细胞向心系细胞的分化潜能打下基础.     

Generation of a tamoxifen inducible Tnnt2MerCreMer knock‐in mouse model for cardiac studies

Tnnt2, encoding thin‐filament sarcomeric protein cardiac troponin T, plays critical roles in heart development and function in mammals. To develop an inducible genetic deletion strategy in myocardial cells, we generated a new Tnnt2:MerCreMer (Tnnt2^MerCreMer/+) knock‐in mouse. Rosa26 reporter lines were used to examine the specificity and efficiency of the inducible Cre recombinase. We found that Cre was specifically and robustly expressed in the cardiomyocytes at embryonic and adult stages following tamoxifen induction. The knock‐in allele on Tnnt2 locus does not impact cardiac function. These results suggest that this new Tnnt2^MerCreMer/+ mouse could be applied towards the temporal genetic deletion of genes of interests in cardiomyocytes with Cre‐LoxP technology. The Tnnt2^MerCreMer/+ mouse model also provides a useful tool to trace myocardial lineage during development and repair after cardiac injury. genesis 53:377–386, 2015. © 2015 Wiley Periodicals, Inc.     

Inducible cardiomyocyte‐specific gene disruption directed by the rat Tnnt2 promoter in the mouse

We developed a conditional and inducible gene knockout methodology that allows effective gene deletion in mouse cardiomyocytes. This transgenic mouse line was generated by coinjection of two transgenes, a “reverse” tetracycline‐controlled transactivator (rtTA) directed by a rat cardiac troponin T (Tnnt2) promoter and a Cre recombinase driven by a tetracycline‐responsive promoter (TetO). Here, Tnnt2‐rtTA activated TetO‐Cre expression takes place in cardiomyocytes following doxycycline treatment. Using two different mouse Cre reporter lines, we demonstrated that expression of Cre recombinase was specifically and robustly induced in the cardiomyocytes of embryonic or adult hearts following doxycycline induction, thus, allowing cardiomyocyte‐specific gene disruption and lineage tracing. We also showed that rtTA expression and doxycycline treatment did not compromise cardiac function. These features make the Tnnt2‐rtTA;TetO‐Cre transgenic line a valuable genetic tool for analysis of spatiotemporal gene function and cardiomyocyte lineage tracing during developmental and postnatal periods. genesis 48:63–72, 2010. © 2009 Wiley‐Liss, Inc.     

The cardiac repair benefits of inflammation do not persist: evidence from mast cell implantation

Multiple mechanisms contribute to progressive cardiac dysfunction after myocardial infarction (MI) and inflammation is an important mediator. Mast cells (MCs) trigger inflammation after MI by releasing bio‐active factors that contribute to healing. c‐Kit‐deficient (Kit^W/W‐v) mice have dysfunctional MCs and develop severe ventricular dilatation post‐MI. We explored the role of MCs in post‐MI repair. Mouse wild‐type (WT) and Kit^W/W‐v MCs were obtained from bone marrow (BM). MC effects on fibroblasts were examined in vitro by proliferation and gel contraction assays. MCs were implanted into infarcted mouse hearts and their effects were evaluated using molecular, cellular and cardiac functional analyses. In contrast to WT, Kit^W/W‐v MC transplantation into Kit^W/W‐v mice did not improve cardiac function or scar size post‐MI. Kit^W/W‐v MCs induced significantly reduced fibroblast proliferation and contraction compared to WT MCs. MC influence on fibroblast proliferation was Basic fibroblast growth factor (bFGF)‐dependent and MC‐induced fibroblast contractility functioned through transforming growth factor (TGF)‐β. WT MCs transiently rescue cardiac function early post‐MI, but the benefits of BM cell implantation lasted longer. MCs induced increased inflammation compared to the BM‐injected mice, with increased neutrophil infiltration and infarct tumour necrosis factor‐α (TNF‐α) concentration. This augmented inflammation was followed by increased angiogenesis and myofibroblast formation and reduced scar size at early time‐points. Similar to the functional data, these beneficial effects were transient, largely vanishing by day 28. Dysfunctional Kit^W/W‐v MCs were unable to rescue cardiac function post‐MI. WT MC implantation transiently enhanced angiogenesis and cardiac function. These data suggest that increased inflammation is beneficial to cardiac repair, but these effects are not persistent.     

EphB4 Forward‐Signaling Regulates Cardiac Progenitor Development in Mouse ES Cells

Eph receptor (Eph)‐ephrin signaling plays an important role in organ development and tissue regeneration. Bidirectional signaling of EphB4–ephrinB2 regulates cardiovascular development. To assess the role of EphB4–ephrinB2 signaling in cardiac lineage development, we utilized two GFP reporter systems in embryonic stem (ES) cells, in which the GFP transgenes were expressed in Nkx2.5⁺ cardiac progenitor cells and in α‐MHC⁺ cardiomyocytes, respectively. We found that both EphB4 and ephrinB2 were expressed in Nkx2.5‐GFP⁺ cardiac progenitor cells, but not in α‐MHC‐GFP⁺ cardiomyocytes during cardiac lineage differentiation of ES cells. An antagonist of EphB4, TNYL‐RAW peptides, that block the binding of EphB4 and ephrinB2, impaired cardiac lineage development in ES cells. Inhibition of EphB4–ephrinB2 signaling at different time points during ES cell differentiation demonstrated that the interaction of EphB4 and ephrinB2 was required for the early stage of cardiac lineage development. Forced expression of human full‐length EphB4 or intracellular domain‐truncated EphB4 in EphB4‐null ES cells was established to investigate the role of EphB4‐forward signaling in ES cells. Interestingly, while full‐length EphB4 was able to restore the cardiac lineage development in EphB4‐null ES cells, the truncated EphB4 that lacks the intracellular domain of tyrosine kinase and PDZ motif failed to rescue the defect of cardiomyocyte development, suggesting that EphB4 intracellular domain is essential for the development of cardiomyocytes. Our study provides evidence that receptor‐kinase‐dependent EphB4‐forward signaling plays a crucial role in the development of cardiac progenitor cells. J. Cell. Biochem. 116: 467–475, 2015. © 2014 The Authors. Journal of Cellular Biochemistry published by Wiley Periodicals, Inc.     

Simultaneous color‐coded imaging to distinguish cancer “stem‐like” and non‐stem cells in the same tumor

In this study, we demonstrate that the differential behavior, including malignancy and chemosensitivity, of cancer stem‐like and non‐stem cells can be simultaneously distinguished in the same tumor in real time by color‐coded imaging. CD133⁺ Huh‐7 human hepatocellular carcinoma (HCC) cells were considered as cancer stem‐like cells (CSCs), and CD133^? Huh‐7 cells were considered as non‐stem cancer cells (NSCCs). CD133⁺ cells were isolated by magnetic bead sorting after Huh‐7 cells were genetically labeled with green fluorescent protein (GFP) or red fluorescent protein (RFP). In this scheme, CD133⁺ cells were labeled with GFP and CD133^? cells were labeled with RFP. CSCs had higher proliferative potential compared to NSCCs in vitro. The same number of GFP CSCs and the RFP NSCCs were mixed and injected subcutaneously or in the spleen of nude mice. CSCs were highly tumorigenic and metastatic as well as highly resistant to chemotherapy in vivo compared to NSCCs. The ability to specifically distinguish stem‐like cancer cells in vivo in real time provides a visual target for prevention of metastasis and drug resistance. J. Cell. Biochem. 111: 1035–1041, 2010. © 2010 Wiley‐Liss, Inc.     

OPLA scaffold,collagen I,and horse serum induce a higher degree of myogenic differentiation of adult rat cardiac stem cells

In the last few years, a major goal of cardiac research has been to drive stem cell differentiation to replace damaged myocardium. Several research groups have attempted to differentiate potential cardiac stem cells (CSCs) using bi‐ or three‐dimensional systems supplemented with growth factors or molecules acting as differentiating substances. We hypothesize that these systems failed to induce a complete differentiation because they lacked an architectural space. In the present study, we isolated a pool of small proliferating and fibroblast‐like cells from adult rat myocardium. The phenotype of these cells was assessed and the characterized cells were cultured in a collagen I/OPLA scaffold with horse serum to obtain fine myocardial differentiation. C‐Kit^POS/Sca‐1^POS CSCs fully differentiated in vitro when an environment more similar to the CSC niche was created. These experiments demonstrated an important model for the study of the biology of CSCs and the biochemical pathways that lead to myocardial differentiation. The results pave the way for a new surgical approach. J. Cell. Physiol. 221: 729–739, 2009. © 2009 Wiley‐Liss, Inc.     

Differentiation potential of individual olfactory c‐Kit+ progenitors determined via multicolor lineage tracing

Olfactory tissue undergoes lifelong renewal, due to the presence of basal neural stem cells. Multiple categories of globose basal stem cells have been identified, expressing markers such as Lgr5, Ascl1, GBC‐2, and c‐Kit. The differentiation potential of individual globose cells has remained unclear. Here, we utilized Cre/loxP lineage tracing with a multicolor reporter system to define c‐Kit+ cell contributions at clonal resolution. We determined that reporter expression permitted identification of c‐Kit derived progeny with fine cellular detail, and that clones were found to be comprised by neurons only, microvillar cells only, microvillar cells and neurons, or gland/duct cells. Quantification of reporter‐labeled cells indicated that c‐Kit+ cells behave as transit amplifying or immediate precursors, although we also found evidence for longer‐term c‐Kit+ cell contributions. Our results from the application of multicolor fate mapping delineate the clonal contributions of c‐Kit+ cells to olfactory epithelial renewal, and provide novel insight into tissue maintenance of an adult neuroepithelium. © 2015 Wiley Periodicals, Inc. Develop Neurobiol 76: 241–251, 2016     

Characterization of contracting cardiomyocyte colonies in the primary culture of neonatal rat myocardial cells: A model of in vitro cardiomyogenesis

The unmet clinical need for myocardial repair after irreversible ischemic injury requires a better understanding of the biological properties of cardiac stem cells (CSCs). Using a primary culture of neonatal rat myocardial cells, we describe the formation and maturation of contracting cardiomyocyte colonies stemming from c-kit⁺, Sca⁺, or Isl1⁺ CSCs, which occurs in parallel to the hypertrophy of the major cardiac myocyte population. The contracting cardiomyocyte colonies (~1–2 colonies per 1 × 10⁵ of myocardial cells) were identified starting from eighth day of culturing. At first, spontaneous weak, asynchronous, and arrhythmic contractions of the colonies at a rate of 2–3 beats/min were registered. Over time, the contractions of the colonies became more synchronous and frequent, with a contraction rate of 58–60 beats/min by the 30th day of culturing. The colonies were characterized by the CSCs subtype-specific pattern of growth and structure. The cells of the colonies were capable of spontaneous cardiomyogenic differentiation, demonstrating expression of both sarcomeric α-actinin and α-sarcomeric actin as well as the maturation of contractile machinery and typical Ca²⁺ responses to caffeine (5 mМ) and K⁺ (120 mМ). Electromechanical coupling, characterized by cardiac muscle-specific Ca²⁺-induced Ca²⁺ release, was evident at 3 weeks of culturing. Thus, the co-cultivation of CSCs with mature cardiac cells resulted in the formation of contracting cardiomyocyte colonies, resembling the characteristics of in vivo cardiomyogenesis. The proposed model can be used for the investigation of fundamental mechanisms underlying cardiomyogenic differentiation of CSCs as well as for drug testing and/or other applications.     

Effect of Iron Deficiency on c-kit+ Cardiac Stem Cells In Vitro

Aim

Iron deficiency is a common comorbidity in chronic heart failure (CHF) which may exacerbate CHF. The c-kit⁺ cardiac stem cells (CSCs) play a vital role in cardiac function repair. However, much is unknown regarding the role of iron deficiency in regulating c-kit⁺ CSCs function. In this study, we investigated whether iron deficiency regulates c-kit⁺ CSCs proliferation, migration, apoptosis, and differentiation in vitro.

Method

All c-kit⁺ CSCs were isolated from adult C57BL/6 mice. The c-kit⁺ CSCs were cultured with deferoxamine (DFO, an iron chelator), mimosine (MIM, another iron chelator), or a complex of DFO and iron (Fe(III)), respectively. Cell migration was assayed using a 48-well chamber system. Proliferation, cell cycle, and apoptosis of c-kit⁺ CSCs were analyzed with BrdU labeling, population doubling time assay, CCK-8 assay, and flow cytometry. Caspase-3 protein level and activity were examined with Western blotting and spectrophotometric detection. The changes in the expression of cardiac-specific proteins (GATA-4,TNI, and β-MHC) and cell cycle-related proteins (cyclin D1, RB, and pRB) were detected with Western blotting.

Result

DFO and MIM suppressed c-kit⁺ CSCs proliferation and differentiation. They also modulated cell cycle and cardiac-specific protein expression. Iron chelators down-regulated the expression and phosphorylation of cell cycle-related proteins. Iron reversed those suppressive effects of DFO. DFO and MIM didn’t affect c-kit⁺ CSCs migration and apoptosis.

Conclusion

Iron deficiency suppressed proliferation and differentiation of c-kit⁺ CSCs. This may partly explain how iron deficiency affects CHF prognosis.     

Targeted Genomic Integration of a Selectable Floxed Dual Fluorescence Reporter in Human Embryonic Stem Cells

The differentiation of pluripotent stem cells involves transition through a series of specific cell states. To understand these cell fate decisions, the field needs improved genetic tools for the labeling, lineage tracing and selection of specific cell types from heterogeneous differentiating populations, particularly in the human embryonic stem cell (hESC) system. We used zinc finger nuclease technology to stably insert a unique, selectable, floxed dual-fluorescence reporter transgene into the AAVS1 locus of RUES2 hESCs. This “stoplight” transgene, mTmG-2a-Puro, strongly expresses membrane-localized tdTomato red fluorescent protein until Cre-dependent recombination causes a switch to expression of membrane-localized enhanced green fluorescent protein (eGFP) and puromycin resistance. First, to validate this system in undifferentiated cells, we transduced transgenic hESCs with a lentiviral vector driving constitutive expression of Cre and observed the expected phenotypic switch. Next, to demonstrate its utility in lineage-specific selection, we transduced differentiated cultures with a lentiviral vector in which the striated muscle-specific CK7 promoter drives Cre expression. This yielded near-homogenous populations of eGFP⁺ hESC-derived cardiomyocytes. The mTmg-2a-Puro hESC line described here represents a useful new tool for both in vitro fate mapping studies and the selection of useful differentiated cell types.     

Foe turned friend: multiple functional roles attributable to hyper-activating stem cell factor receptor mutant in regeneration of the haematopoietic cell compartment

Objectives: Stem cell factor receptor, c‐kit, is considered to be the master signalling molecule of haematopoietic stem cells. It develops the orchestral pattern of haematopoietic cell lineages, seen by its varying degree of omnipresence in progenitors, lineage committed and mature cells. We have investigated the effect of over‐expressing c‐kit on early recovery of the haematopoietic compartment, in irradiated hosts. Materials and methods: Normal bone marrow cells (BMCs) were transfected with Kit_wt (wild‐type c‐kit) or its variant Kit_mu (asp814tyr) by electroporation. Lethally irradiated mice were transplanted with normal or transfected congeneic BMCs. The effect of ectopic expression of c‐kit on haematopoietic cell recovery was determined by analysing donor‐derived cells. Furthermore, effects of both types of c‐kit over‐expression on progenitor and lineage‐committed cells were examined by flow cytometric analysis of Sca‐1 and lineage‐committed (Lin⁺) cells respectively. Results: Hyper‐activating Kit_mu significantly improved recovery of the haematopoietic system in irradiated hosts. In vivo results showed that the donor‐derived c‐kit⁺ cell population was increased to more than 3‐fold in the case of Kit_mu‐transfected cells compared to normal and Kit_wt over‐expressing BMCs. In general, survival of progenitor and committed cell was improved in the Kit_mu over‐expressing system compared to the other two cohorts. Conclusion: These results suggest that recruitment of the hyper‐activating variant of c‐kit (Kit_mu) lead to early recovery of the bone marrow of lethally irradiated mice.     

Mast Cells Play No Role in the Pathogenesis of Postoperative Ileus Induced by Intestinal Manipulation

Introduction

Intestinal manipulation (IM) during abdominal surgery results in intestinal inflammation leading to hypomotility or ileus. Mast cell activation is thought to play a crucial role in the pathophysiology of postoperative ileus (POI). However, this conclusion was mainly drawn using mast cell-deficient mouse models with abnormal Kit signaling. These mice also lack interstitial cells of Cajal (ICC) resulting in aberrant gastrointestinal motility even prior to surgery, compromising their use as model to study POI. To avoid these experimental weaknesses we took advantage of a newly developed knock-in mouse model, Cpa3^Cre/+, devoid of mast cells but with intact Kit signaling.

Design

The role of mast cells in the development of POI and intestinal inflammation was evaluated assessing gastrointestinal transit and muscularis externa inflammation after IM in two strains of mice lacking mast cells, i.e. Kit^W-sh/W-sh and Cpa3^Cre/+ mice, and by use of the mast cell stabilizer cromolyn.

Results

Kit^W-sh/W-sh mice lack ICC networks and already revealed significantly delayed gastrointestinal transit even before surgery. IM did not further delay intestinal transit, but induced infiltration of myeloperoxidase positive cells, expression of inflammatory cytokines and recruitment of monocytes and neutrophils into the muscularis externa. On the contrary, Cpa3^Cre/+ mice have a normal network of ICC and normal gastrointestinal. Surprisingly, IM in Cpa3^Cre/+ mice caused delay in gut motility and intestinal inflammation as in wild type littermates mice (Cpa3^+/+). Furthermore, treatment with the mast cell inhibitor cromolyn resulted in an inhibition of mast cells without preventing POI.

Conclusions

Here, we confirm that IM induced mast cell degranulation. However, our data demonstrate that mast cells are not required for the pathogenesis of POI in mice. Although there might be species differences between mouse and human, our results argue against mast cell inhibitors as a therapeutic approach to shorten POI.     

Identification and biological characterization of chicken embryonic cardiac progenitor cells

Objectives: Many kinds of cardiac progenitor cell populations have been identified, including c‐kit⁺, Nkx2.5⁺s and GATA4⁺ cells. However, these progenitors have limited ability to differentiate into different cardiac cell types. Recently, a new kind of cardiac progenitor cell named the multipotent Isl1⁺ cardiovascular progenitor (MICPs) has been identified, which also expresses Nkx2.5, GATA4, CD34 and Flk1. Materials and methods: In this study, we have isolated and characterized MICPs from chicken embryonic heart tissues using immunofluorescence and PCR. Results: Results shown that they express markers of cardiac progenitor cells, with high clonality. They have the ability to self‐renew and can give rise to three types of heart cell in vitro. Conclusions: Myocytes, smooth muscle cells and endothelial cells. Our work provides evidence for a developmental paradigm of the heart, that endothelial and muscle lineage diversification arises from multipotent cardiac progenitor cells. Existence of these cells provides a new opportunity for myocardial injury repair.     

An age-dependent proliferation is involved in the postnatal development of interstitial cells of Cajal in the small intestine of mice

This paper aimed at investigating the alterations in interstitial cells of Cajal (ICCs) in the murine small intestine from 0-day to 56-day post-partum (P0–P56) by immunohistochemistry. The Kit⁺ ICCs, which were situated around myenteric nerve plexus (ICC-MY) formed a loose cellular network at P0 which changed into an intact one before P32. The density of ICC-MY increased from P0 to P12, and then decreased until P32. In contrast, the estimated total amount increased more than 15-fold at P32 than that at P0. Some Kit⁺/BrdU⁺ cells were observed at 24 h after one BrdU injection to the different-aged mice, and the number decreased from P2 to P24 and vanished at P32. Actually a few Kit⁺/BrdU⁺ cells can be observed at 1 h after one BrdU injection at P10, and the amount doubled at 24 h along with paired Kit⁺/BrdU⁺ cells. A number of BrdU⁺ ICCs were also labeled with CD34, CD44 and insulin-like growth factor I receptor. About 65% ICCs were BrdU⁺ at P32 after daily BrdU injection from P0. Our results indicate that an age-dependent proliferation is involved in the postnatal development of ICC-MY which increase greatly in cell numbers and proliferative ICCs may originate from ICCs progenitor cells. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. Feng Mei and Jiang Zhu have contributed equally to this work.