Abstract
Adipose-derived stem cells (ASCs) are promising candidates for therapy in myocardial infarction (MI). However, the frequency of human ASCs that differentiate towards cardiomyocytes is low. We hypothesized that adherence to extracellular matrix molecules that are upregulated after MI might increase human stem cell differentiation towards cardiomyocytes. We analysed putative ASC differentiation on fibronectin-coated, laminin-coated and uncoated culture plates. Expression of cardiac markers in cells was analysed 1, 3 and 5 weeks after stimulation with 5-aza-2-deoxycytidine. After 1 week, mRNA expression of myosin light chain-2α (MLC-2α), an early marker in cardiomyocyte development, was increased significantly in treated cells, independent of coating. At 5 weeks, however, mRNA expression of the late cardiomyocyte development marker SERCA2α was only significantly increased in 5-aza-2-deoxycytidine-treated cells cultured on laminin. Significantly higher numbers of cells were immunopositive for MLC-2α in cultures of treated cells grown on laminin-coated wells, when compared with cultures of treated cells grown on uncoated wells, both at 1 week and at 5 weeks. Furthermore, after 3 weeks, significantly more α-actinin- and desmin-positive cells were detected after treatment with 5-aza-2-deoxycytidine, but only in uncoated wells. After 5 weeks, however, the number of desmin-positive cells was only significantly increased after treatment of cells with 5-aza-2-deoxycytidine and culture on laminin (61% positive cells). Thus, we have found that a high percentage of human ASCs can be differentiated towards cardiomyocytes; this effect can be improved by laminin, especially during late differentiation.
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Introduction
Cardiovascular diseases are a leading cause of morbidity and mortality in the western world (Wang and Sjoquist 2006), with heart failure resulting from myocardial infarction (MI) being the most common aetiology (Lu et al. 2004). Heart failure is partly caused by the loss of cardiomyocytes and the limited capacity of spontaneous regeneration of the heart. This results in replacement of injured myocardium by scar tissue, which adversely affects cardiac function (Smits et al. 2005; Wang and Sjoquist 2006).
A promising tool for the restoration of contractile function after MI is stem cell therapy. In comparison with current therapies that focus on the restoration of the blood flow, stem cells not only might improve neovascularization, but also might replace lost cardiomyocytes, since they have the capacity to differentiate into cardiomyocytes (Wang and Sjoquist 2006; Orlic et al. 2001; Strauer et al. 2002). However, effectively to restore contractile function of the heart after MI, sufficient stem cells need to attach to the infarcted area and subsequently differentiate into cardiomyocytes, thereby replacing a substantial fraction of the lost cardiomyocytes. Unfortunately, recent studies suggest that only a small portion of stem cells applied to the heart invade the infarcted area and ultimately differentiate into cardiomyocytes (Lee et al. 2007).
Several factors might influence the fate of the stem cells in the heart. One of these is the source of stem cells used. Although various cell sources have been used experimentally for stem cell transplantation after MI, the optimal choice of stem cell source remains controversial (Zhang et al. 2007). A potential source of stem cells for transplantation is adipose tissue. Adipose-tissue-derived stem cells (ASCs) are of mesenchymal origin, can easily be harvested in large quantities, show high proliferation rates in culture and have the capacity to differentiate towards several cell types, including cardiomyocytes (Rangappa et al. 2003; Oedayrajsingh-Varma et al. 2006).
Several studies have shown the differentiation of animal ASCs towards cardiomyocytes after treatment with chemical substances such as 5-azacytidin. Spontaneous differentiation of ASCs towards cardiomyocytes has also been described (Planat-Benard et al. 2004; Rangappa et al. 2003; Bai et al. 2007). Furthermore, in vivo animal studies, in which ASCs have been transplanted after MI, have also shown the differentiation of ASCs towards cardiomyocytes and increased cardiac function (Strem et al. 2005; Zhang et al. 2007). However, studies on human ASCs are limited, and only low percentages (<2%) of spontaneous differentiation have been described (Bai et al. 2007; Song et al. 2007). Only Gaustad et al. (2004) have described a higher differentiation rate (25% desmin-positive cells) of human ASCs in vitro, but only in one donor and only after the cells had been permeabilized and exposed to extracts of rat cardiomyocytes. Before the translation of human ASCs to a clinical setting, we therefore need to show that a significant number of such cells can differentiate into cardiomyocytes.
Another important factor for stem cell adherence and differentiation is the timepoint of transplantation after MI (Lu et al. 2004). Homing, growth and differentiation of stem cells after MI is known to depend on the environment in the heart, and especially on the adhesion factors at the site of injury, all of which change dramatically after MI (Lu et al. 2004; Malek et al. 2006; Wang and Sjoquist 2006; Chastain et al. 2006; Salasznyk et al. 2004). Therefore, stem cell therapy has to be applied at the moment after infarction when the environment is most favourable for stem cell adhesion and cardiomyocyte formation. Two extracellular matrix (ECM) molecules of human mesenchymal stem cells are important for stem cell survival and differentiation towards other lineages: laminin and fibronectin (Hashimoto et al. 2006; Salasznyk et al. 2004; Wijelath et al. 2004). Both these proteins are expressed in the normal heart and increase after MI (Froen and Larsen 1995; Knowlton et al. 1992; Willems et al. 1996). In vivo, an effect of these ECM molecules on stem cell survival and differentiation can be expected if stem cell therapy is applied once these proteins have accumulated. In a previous study, we have shown that ASCs attach best to fibronectin in comparison with other ECM molecules; we have also demonstrated that fibronectin is increased from 12 h onwards after MI in the human heart (van Dijk et al. 2008). Further, laminin is described to increase from 3 days post-MI (Morishita et al. 1996).
Our ultimate goal is to optimize stem cell transplantation by directing a larger number of stem cells to the infarction site and by stimulating stem cell differentiation in vivo. In this study, we have therefore investigated the effect of fibronectin and laminin on the putative differentiation of human ASCs towards cardiomyocytes.
Materials and methods
Adipose tissue donors
Human subcutaneous adipose tissue samples were obtained as waste material after elective surgery and donated after informed consent of the patients from various clinics in Amsterdam, The Netherlands. This study complied with the principles of the Declaration of Helsinki. Adipose tissue was harvested from the abdomen or hip and thigh region by using either resection or tumescent liposuction. Seven healthy non-obese female donors (age range: 33–51 years) were included in this study.
Isolation of stromal vascular fraction of adipose tissue
Adipose tissue was stored in sterile phosphate-buffered saline (PBS; Braun, Melsungen, USA) at 4°C and processed within 24 h after surgery as described previously (Oedayrajsingh-Varma et al. 2006). In brief, resected material was minced by using a surgical scalpel before being processed. After extensive washes with PBS, the ECM was enzymatically digested with 0.1% collagenase A (Roche Diagnostics, Mannheim, Germany) in PBS containing 1% bovine serum albumin (BSA; Roche Diagnostics) under intermittent shaking for 45 min at 37°C. Then, the material was washed with Dulbecco’s modified Eagle’s medium (DMEM-glucose; BioWhittaker, Cambrex, Verviers, Belgium) containing 10% fetal bovine serum (FBS; HyClone, South Logan, Utah, USA) and centrifuged for 10 min at 600g. The cell pellet was resuspended in PBS and passed through a 200-μm mesh (Braun/Beldico, Marche-en-Famenne, Belgium) to obtain a single-cell suspension. To remove contaminating erythrocytes, the cells were subjected to Ficoll density centrifugation (lymphoprep, ρ=1.077 g/ml, osmolarity 280 ± 15 mOsm; Axis-Shield, Oslo, Norway). The cell-containing interface was harvested and washed with DMEM containing 10% FBS. Cells were frozen under “controlled rate” conditions and stored in liquid nitrogen until needed in experiments.
Cell culture
Cells from the stromal vascular fraction were seeded at 1×105 cells/cm2 and cultured for several passages in DMEM supplemented with 10% FBS, 100 U/ml penicillin, 100 µg/ml streptomycin, 2 mM L-glutamine (all from Gibco, Invitrogen, Calif., USA; normal culture medium), in a humidified atmosphere of 5% CO2 at 37°C. Media were changed twice a week. Once 80%–90% confluency has been reached, cells were detached with 0.5 mM EDTA/0.05% trypsin (Gibco), for 5 min at 37°C, and replated.
To assess ASC differentiation towards cardiomyocytes, culture-expanded cells (p3) were plated into 6-well culture dishes at a density of 50,000 cells per well, each well having been coated with 2.5 μg/cm fibronectin (Roche) or 0.12 μg/cm laminin (Roche) or left uncoated, in normal culture medium. The cells were then cultured in DMEM containing 15% FBS and, when 50–60% confluent, stimulated with 5-aza-2-deoxycytidine (9 μM; Fluka, Sigma Aldrich, St. Louis, Mo. USA) for 24 h in DMEM supplemented with 15% FBS, 100 U/ml penicillin, 100 µg/ml streptomycin, 2 mM L-glutamine and 1% ITS + premix (BD Biosciences, Bedford, Mass., USA). This concentration of 5-aza-deoxycytidine has been shown to induce differentiation of rabbit ASCs towards cardiomyocytes on uncoated culture plates (Rangappa et al. 2003). Cells were harvested after 1, 3 and 5 weeks.
Reverse transcription with polymerase chain reaction
Cells were harvested in 750 μl TRIzol reagent (Invitrogen) per well (10 min, room temperature), after 1 and 5 weeks. Total RNA from the cells was isolated by incubating the samples in 150 μl chloroform for 2 min after vigourous shaking. Samples were centrifuged for 15 min at 12,000g and the upper water phase was transferred to a new tube containing 5 μl glycogen (1 μg/μl) and 375 μl isopropyl. After a 10-min incubation at room temperature, the cells were centrifuged for 10 min at 12,000g and the pellet was washed with 1 ml 75% ethanol. The samples were centrifuged again for 5 min at 7500g and, when the RNA-pellet was dried, it was taken up in RNAse-free water.
cDNA synthesis (GeneAmp PCR System9700, PE Applied Biosystems, Calif., USA) was performed by using 0.5–1 mg total RNA in a 20-ml reaction mix containing 5 U Transcriptor Reverse Transcriptase (Roche), 0.08 A260 U random primers (Roche), 1 mM each dNTP (Invitrogen), RNAse inhibitor, and 1× concentrated Transcriptor reverse transcription (RT) reaction buffer. The cDNA was stored at −80°C prior to real-time polymerase chain reaction (PCR).
Real-time PCRs were performed by using the SYBRGreen reaction kit according to the manufacturer’s instructions (Roche) in a LightCycler 480 (Roche). cDNA (∼5 ng) was used in a volume of 20 µl PCR mix (LightCycler DNA Master Fast start plus Kit, Roche) containing a final concentration of 0.5 pmol primers. Relative housekeeping gene expression (18S) and relative target gene expression (cardiac-specific SERCA2α, myosin light chain-2α [MLC-2α], desmin and α-actinin) were determined.
Primers (Invitrogen) used for real-time PCR are listed in Table 1. They were designed by using Clone Manager Suite software program version 6 (Scientific & Educational Software, Cary, N.C., USA). The amplified PCR fragment extended over at least one exon border, based on homology in conserved domains between human, mouse, rat, dog and cow, except for the 18S gene, which is encoded by one exon only.
PCR conditions were as follows: for 18S, a 1-min pre-incubation at 95°C, followed by 30 cycles of amplification at 95°C for 5 s, 56°C for 10 s, 72°C for 15 s, and 82°C for 5 s, followed by melting curve analysis; for MLC-2α, SERCA, desmin and α-actinin, a 10-min pre-incubation at 95°C, followed by 45 cycles of amplification at 95°C for 5 s, 58°C for 5 s, 72°C for 15 s, and 82°C for 5 s followed by melting curve analysis.
Quantification was carried out by normalizing the values of relative target gene expression to relative housekeeping gene (18S) expression. Amplified PCR products were electrophoresed on a 1.6% agarose gel containing 0.5 μg/ml ethidium bromide.
Immunological staining
Cells were trypsinized after 3 and 5 weeks. Cytospin slides were prepared by spinning 104 ASCs for 5 min at 500 rpm (Shandon cytospin 3, Thermo Scientific, Waltham, Mass., USA). Slides were air-dried overnight, fixed with acetone for 10 min, incubated with mouse antibodies against human desmin (1:75, Sigma), α-actinin (1:300, Sigma), troponin T (1:75, AbD Serotec, Oxford, UK) or MLC-2α (1:100, Synaptic Systems, Göttingen, Germany) in PBS containing 1% BSA (PBS/BSA) for 1.5 h at room temperature, washed with PBS, and incubated with biotin-conjugated rabbit-anti-mouse antibodies (1:300, Dako Cytomation, Glostrup, Denmark) for 30 min. After being washed in PBS, the slides were incubated with streptavidin-biotin complex/horseradish peroxidase (sABC/HRP; 1:200, Dako) for 1 h. Staining was visualized by using 3-amino-9-ethylcarbazole (AEC; Zymed AEC kit, Invitrogen). Finally, the cells were counterstained with hematoxylin and covered. Control slides were incubated with PBS instead of the primary antibody and showed no positive staining. All cytospin slides were scored blindly for the percentage of AEC positive cells; 100 cells were scored per slide.
Statistics
Statistics were performed with the SPSS statistics program (windows version 9.0) and Graphpad Prism (version 4). The Repeated Measures method was used if values were obtained for all samples. Otherwise, an analysis of variance (ANOVA) was used if scores were distributed normally; if not or if n was too small, a Kruskall-Wallis test was used for analysis. A P-value smaller than 0.05 was considered to be statistically significant. Values are given as mean ± SE.
Results
To investigate the effect of ECM proteins on cardiomyocyte differentiation, ASCs were cultured in fibronectin- or laminin-coated wells or in uncoated wells, with or without treatment with 5-aza-2-deoxycytidine. Before stimulation, ASCs displayed a fibroblast morphology, as previously described (Fig. 1a; Rangappa et al. 2003; Gaustad et al. 2004). After stimulation, the morphology of the cells changed. At 2 weeks, cells became larger and more elongated. Further, we found smaller numbers of ASCs in the wells that were treated with5-aza-2-deoxycitidine, suggesting a reduction of proliferation capacity (not shown). From 3 weeks after stimulation, multinucleated cells and ball-like figures were present in the wells containing 5-aza-2-deoxycitidine-stimulated cells, especially in the laminin-coated wells (Fig. 1b). mRNA expression of cardiac markers was studied by using RT-PCR. The control consisted of cells that were cultured on uncoated culture wells and not treated with 5-aza-2-deoxycitidine. In untreated cells, we could not detect any differences in SERCA-2α and MLC-2α mRNA expression between uncoated wells and wells coated with fibronectin or laminin, both after 1 and 5 weeks of culture (not shown). However, 1 week after treatment with 5-aza-2-deoxycitidine, mRNA expression of the early cardiac marker MLC-2α (Kubalak et al. 1994) was increased over 10-fold when compared with untreated cells (Fig. 2a, n = 7, P<0.05). This increase, however, was independent of coating. At 5 weeks after treatment, the expression of MLC-2α mRNA was no longer found to be significantly increased when compared with untreated cells. mRNA expression for α-actinin was not significantly different between the different timepoints (Fig. 2b). Desmin mRNA expression did not differ between 1 and 3 weeks, independent of coating. However, a clear trend was visible showing an increased expression of desmin mRNA expression at 5 weeks in stimulated cells, especially in the cells in coated culture wells (Fig. 2c, P = 0.10 for laminin and fibronectin, compared with untreated cells after 5 weeks, n = 5).
mRNA expression of the late differentiation marker cardiac SERCA2α (Fijnvandraat et al. 2003) was not found to be significantly increased at 1 week after treatment with 5-aza-2-deoxycytidine. After 5 weeks, however, a significant increase of SERCA-2α expression was found in treated cells that were cultured on laminin (Fig. 2d, n = 7, P<0.05). This increase was not found when cells were cultured in uncoated culture wells or on fibronectin.
To exclude that stimulation with 5-aza-2-deoxycitidine also triggered the differentiation of ASC towards other lineages, we also tested our samples for markers for osteogenic and chondrogenic lineages at 5 weeks after treatment, as described previously (Jurgens et al. 2008). No expression of the chondrogenic marker collagen type 2b was found in any of the samples. Some expression of the chondrogenic marker aggrecan was found; however, this amount was too low to quantify. A low expression of the osteogenic markers osteopontin and collagen type 1A were found but no differences were found between untreated and treated cells suggesting that we had not induced differentiation into lineages other than the cardiac lineage by using 5-aza-2-deoxycitidine (not shown).
These results suggested that fibronectin and laminin had no additional affect on mRNA expression of cardiac markers during early differentiation, whereas the adherence of ASCs to laminin significantly improved late differentiation towards cardiomyocytes.
To exclude a putative effect of a lower concentration of fibronectin on differentiation, we also tested fibronectin at a single dose of 0.12 μg/cm. This did not induce cardiac differentiation (not shown).
After studying mRNA expression, we next examined the protein expression of the cardiac markers MLC-2α, α-actinin, desmin and troponin T at 1, 3 and 5 weeks after treatment. No protein expression could be detected for α-actinin, desmin and troponin in cells at 1 week after treatment (not shown). Notably, when cells were not treated, no differences in the numbers of desmin- and actinin-positive cells were found between uncoated wells and wells coated with fibronectin or laminin (not shown). In Fig. 3, representative examples of immunocytochemical staining of these proteins in cells derived from the same donor are shown; a considerable number of cells stained positively for α-actinin, desmin, troponin T and MLC-2α only in wells containing cells treated with 5-aza-2-deoxycytidine.
We next quantified the immunocytochemical staining. We found that, at 1 week after treatment with 5-aza-2-deoxycitidine, significantly more cells were positive for MLC-2α, when compared with untreated cells, but only in the wells containing treated cells cultured on laminin (Fig. 4a; 20 ± 4% in untreated cells versus 51 ± 9% in laminin-coated wells, P<0.01). The percentage of MLC-2α-positive cells on the laminin-coated wells was also significantly higher when compared with the 5-aza-2-deoxycitidine-treated cells on uncoated culture wells (uncoated 26 ± 7% versus laminin 51 ± 9%, P<0.05). After 3 weeks, no differences were found between the treated cells on the laminin-coated culture wells and on the uncoated culture wells. However, the percentage of MLC-2α-positive cells was significantly lower in treated cells on fibronectin-coated culture wells than on uncoated culture wells (uncoated 52 ± 2% versus 27 ± 2%, P<0.01). After 5 weeks, again only the wells coated with laminin contained a significantly higher number of MLC-2α-positive cells, when compared with untreated cells (untreated 30 ± 4% versus laminin 46 ± 7%, P<0.05). These results suggest a positive effect of laminin coating on MLC-2α expression in ASCs.
We further found that, at 3 weeks after treatment, cytospin slides showed an increased number of treated cells staining positively for the intermediate marker α-actinin when compared with untreated cells (Fig. 4b). However, this number was only significantly increased when ASCs were cultured in uncoated wells (67 ± 12% versus 5 ± 2%, P<0.05). Percentages of positive cells on fibronectin- and laminin-coated culture wells were, respectively, 21 ± 8% and 28 ± 11% (P = 0.16 and P = 0.20, respectively, compared with untreated). After 5 weeks, however, the percentage of α-actinin positive cells in the uncoated culture wells was no longer significantly increased when compared with untreated cells and was similar to the percentage of positive cells in the wells coated with laminin and fibronectin (uncoated: 29 ± 20%, laminin-coated: 28 ± 13%, fibronectin-coated: 26 ± 10%).
Moreover, an increased number of desmin-positive cells (late marker) was found at 3 weeks after treatment (Fig. 4c). However, once again, this increase was only significant when cells were cultured in uncoated wells (74 ± 12% versus 5 ± 1%, P<0.05). Percentage of positive cells in fibronectin- and laminin-coated culture wells were, respectively, 44 ± 15% and 42 ± 16% (P = 0.11 and P = 0.16, respectively). By 5 weeks after treatment, the percentage of desmin-positive cells cultured on uncoated and fibronectin-coated culture wells decreased, but not significantly, when compared with that at 3 weeks (fibronectin-coated: 44 ± 15% to 9 ± 7%, P = 0.07; uncoated: 74 ± 12% to 34 ± 17%, P = 0.17). In contrast, when cells were cultured on laminin, the number of desmin-positive cells increased, but not significantly, compared with that at 3 weeks. More importantly, in these laminin-coated culture wells, the number of desmin-positive cells was significantly increased compared with untreated cells (61 ± 12% versus 3 ± 1%, P<0.05).
Finally, we also quantified troponin T protein expression (Fig. 4d, n = 3). We found that, after 3 and 5 weeks, the percentage of positive cells was low in untreated cells (2% and 1%, respectively). In contrast, all wells containing treated cells showed higher numbers (17%–32%) of troponin-T-positive cells, independent of coating; the highest percentages of positive cells were found in the uncoated wells at 3 and 5 weeks and in the laminin-coated culture wells at 3 weeks. These findings, however, were not statistically significant.
Thus, at the protein level, differentiation towards cardiomyocytes was also only found to be significantly increased in cells treated with 5-aza-2-deoxycytidine and cultured on laminin, especially with regard to late differentiation.
Discussion
We hypothesized that the attachment of ASCs to ECM molecules that are normally present in the healthy heart and that become upregulated after infarction would increase stem cell differentiation towards cardiomyocytes. Therefore, we have studied the effect of laminin and fibronectin on the differentiation of ASCs in vitro. We have found that a high percentage of human ASCs can differentiate towards cardiomyocytes, as shown at the mRNA level (MLC-2α, SERCA) and at the protein level (MLC-2α, α-actinin, desmin, troponin T), and that the ECM molecule laminin, but not fibronectin, plays a role in the differentiation of ASCs towards cardiomyocytes, especially during late differentiation.
Although some studies have previously described the differentiation of human ASCs towards cardiomyocytes (Bai et al. 2007; Song et al. 2007), this is the first time, to the best of our knowledge, that such a large number of human ASCs has been shown to differentiate along this route. Notably, we have demonstrated this effect in cells derived from several donors. Only Gaustad et al. (2004) have described the differentiation of human ASCs at levels comparable with ours; however they only studied ASCs derived from one patient. Our results in cells at 3 weeks after stimulation and grown on uncoated culture plates are similar to the data of Gaustad et al. (2004) who have shown α-actinin expression in 81% (our study 67%) and desmin expression in 25% (our study 74%) of their cells. Furthermore, we have found an additional effect of culturing the cells on laminin, since the percentage of desmin-positive cells in uncoated culture wells decreased again after 5 weeks (35%), whereas the percentage of desmin-positive cells in laminin-coated culture wells increased up to 61%.
A major difference from the study of Gaustad et al. (2004) is that they permeabilized their ASCs and subjected them to rat cardiomyocyt extracts to achieve cardiomyocyte differentiation. Instead, we have used 2-deoxy-5-azacytidin, a demethylating agent that can be employed to prime cells before transplantation in vivo (Zhang et al. 2007; Burlacu 2006) and that is thus possibly more suitable for clinical use. Such a priming of stem cells in vitro before transplantation might be important, since theoretically this would prevent the spontaneous differentiation of stem cells into undesired lineages (Heng et al. 2004).
The positive effect of laminin on late stem cell differentiation might be caused by a real increase of differentiation attributable to laminin, although we cannot exclude that the attachment to laminin prevents the cells from dedifferentiation because, in the uncoated culture wells, both the percentages of α-actinin- and desmin-positive cells decreases between 3 and 5 weeks after treatment. However, since an increase of desmin-positive cells occurs, albeit not significantly, between 3 and 5 weeks in the laminin-coated culture wells, the positive effect of laminin is probably caused not only by the prevention of dedifferentiation, but also by a real increase in the number of cells that have differentiated during this period.
Although previous studies have suggested that the presence of the ECM that is normally present in the heart plays an important role in stem cell differentiation towards cardiomyocytes (Baharvand et al. 2005), this is, to the best of our knowledge, the first time that a positive effect of laminin attachment on stem cell differentiation towards cardiomyocytes has been described. Laminins are heterotrimers of large polypeptides (Kuang et al. 1998). In contrast to many matrix components that are ubiquitous in their distribution in the developing embryo, laminin is localized only in the basement membranes (Foster et al. 1987). This restricted distribution of laminin suggests a specific role for laminin in cell attachment, spreading and differentiation in embryogenesis. Indeed, laminin has been described to attach to myocardial cells as the principle adhesive molecule for the maintenance of architecture and differentiation in the embryo (Kim et al. 1999).
Several studies have described an effect of laminin on myogenesis. For example, Foster et al. (1987) have found that a laminin substrate promotes myogenesis in rat skeletal muscle cultures and Hilenski et al. (1992) have reported that laminin influences cytoskeletal and myofibrillar organization in vitro in neonatal rat cardiac myocytes. Further, mutations in the genes coding for the alpha-2 chain of two laminin isoforms have been shown to cause a severe form of congenital muscular dystrophy in humans and mice (Kuang et al. 1998).
Thus, laminin is known to play a role in regulating the differentiated phenotype of cells. Further, a large number of integrins have been described to interact with laminins (Thorsteinsdottir et al. 1999). In addition to their ability to link cells to their extracellular environment, integrins possess cytoplasmic domains that function in cellular signalling via their ability to associate with and activate signal transduction pathways (Kuang et al. 1998; Belkin and Stepp 2000). The interaction between integrins and laminins therefore can lead to many developmentally relevant processes, such as cell differentiation (Thorsteinsdottir et al. 1999).
In this study, we have found an effect of laminin on ASC differentiation, but no significant effect has been seen for fibronectin on ASC differentiation towards cardiomyocytes. However, we have previously reported that fibronectin improves stem cell attachment and proliferation (van Dijk et al. 2008). Other studies have also described the positive effect of laminin and the negative effect of fibronectin on myoblast formation. For example, Vachon et al. (1996) suggest that laminin plays a role in myoblast adhesion and myotube formation, whereas fibronectin stimulates myoblast adhesion and proliferation but does not improve myogenic differentiation. Moreover, Thyberg and Hultgardh-Nilsson (1994) have shown that laminin retains freshly isolated rat aortic smooth muscle cells in a contractile phenotype in primary culture, whereas fibronectin does not have this effect.
In previous studies, we have demonstrated that fibronectin stimulates ASC attachment and now we have shown that laminin promotes ASC differentiation. Since both laminin and fibronectin are upregulated after MI, their described effects might thus enhance ASC differentiation towards cardiomyocytes for MI therapy by stem cells. We therefore suggest that stem cell therapy should be applied when both fibronectin deposition (12 h to 15 days after MI, unpublished data) and laminin deposition (from day 3 after MI; Morishita et al. 1996) are high, i.e. from 3 days after MI.
Several other studies have also investigated the best timeframe after MI for the application of stem cell therapy, both in animal models and with regard to human stem cell transplantation, by examining molecular events and stem cell retention at the site of infarction (Lu et al. 2004; Ma et al. 2005; Bermejo et al. 2006). These investigations suggest that stem cell therapy should be applied neither during the acute inflammation phase (within 1 day after infarction), nor after a period longer than 2 weeks when scar tissue has formed. This is in agreement with our suggestion that stem cell therapy should be applied at least 3 days after MI.
In summmary, we have shown, for the first time, that a high percentage of human ASCs can differentiate towards cardiomyocytes and that the attachment of these cells to laminin improves late ASC differentiation towards cardiomyocytes. To achieve a positive effect of the ECM molecules fibronectin and laminin on the retrieval and differentiation of stem cells for use in the heart after MI, stem cell therapy should be applied when the deposition of these ECM molecules is high in the heart, i.e. at least 3 days after MI.
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This study was supported by the Institute for Cardiovascular Research of the VU Medical Centre in Amsterdam, The Netherlands (ICaR-VU), project 200380.
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Open Access This is an open access article distributed under the terms of the Creative Commons Attribution Noncommercial License (https://creativecommons.org/licenses/by-nc/2.0), which permits any noncommercial use, distribution, and reproduction in any medium, provided the original author(s) and source are credited.
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van Dijk, A., Niessen, H.W.M., Zandieh Doulabi, B. et al. Differentiation of human adipose-derived stem cells towards cardiomyocytes is facilitated by laminin. Cell Tissue Res 334, 457–467 (2008). https://doi.org/10.1007/s00441-008-0713-6
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DOI: https://doi.org/10.1007/s00441-008-0713-6