Adult cardiac muscle cells in long-term serum-free culture: myofibrillar organization and expression of myosin heavy chain isoforms

Isolation, Culture and Transduction of Adult Mouse Cardiomyocytes

Cultured cardiomyocytes can be used to study cardiomyocyte biology using techniques that are complementary to in vivo systems. For example, the purity and accessibility of in vitro culture enables fine control over biochemical analyses, live imaging, and electrophysiology. Long-term culture of cardiomyocytes offers access to additional experimental approaches that cannot be completed in short term cultures. For example, the in vitro investigation of dedifferentiation, cell cycle re-entry, and cell division has thus far largely been restricted to rat cardiomyocytes, which appear to be more robust in long-term culture. However, the availability of a rich toolset of transgenic mouse lines and well-developed disease models make mouse systems attractive for cardiac research. Although several reports exist of adult mouse cardiomyocyte isolation, few studies demonstrate their long-term culture. Presented here, is a step-by-step method for the isolation and long-term culture of adult mouse cardiomyocytes. First, retrograde Langendorff perfusion is used to efficiently digest the heart with proteases, followed by gravity sedimentation purification. After a period of dedifferentiation following isolation, the cells gradually attach to the culture and can be cultured for weeks. Adenovirus cell lysate is used to efficiently transduce the isolated cardiomyocytes. These methods provide a simple, yet powerful model system to study cardiac biology.

Serum supplemented culture medium masks hypertrophic phenotypes in human pluripotent stem cell derived cardiomyocytes

It has been known for over 20 years that foetal calf serum can induce hypertrophy in cultured cardiomyocytes but this is rarely considered when examining cardiomyocytes derived from pluripotent stem cells (PSC). Here, we determined how serum affected cardiomyocytes from human embryonic- (hESC) and induced pluripotent stem cells (hiPSC) and hiPSC from patients with hypertrophic cardiomyopathy linked to a mutation in the MYBPC3 gene. We first confirmed previously published hypertrophic effects of serum on cultured neonatal rat cardiomyocytes demonstrated as increased cell surface area and beating frequency. We then found that serum increased the cell surface area of hESC- and hiPSC-derived cardiomyocytes and their spontaneous contraction rate. Phenylephrine, which normally induces cardiac hypertrophy, had no additional effects under serum conditions. Likewise, hiPSC-derived cardiomyocytes from three MYBPC3 patients which had a greater surface area than controls in the absence of serum as predicted by their genotype, did not show this difference in the presence of serum. Serum can thus alter the phenotype of human PSC derived cardiomyocytes under otherwise defined conditions such that the effects of hypertrophic drugs and gene mutations are underestimated. It is therefore pertinent to examine cardiac phenotypes in culture media without or in low concentrations of serum.

Cardiomyocyte culture - an update on the in vitro cardiovascular model and future challenges

The success of any work with isolated cardiomyocytes depends on the reproducibility of cell isolation, because the cells do not divide. To date, there is no suitable in vitro model to study human adult cardiac cell biology. Although embryonic stem cells and induced pluripotent stem cells are able to differentiate into cardiomyocytes in vitro, the efficiency of this process is low. Isolation and expansion of human cardiomyocyte progenitor cells from cardiac surgical waste or, alternatively, from fetal heart tissue is another option. However, to overcome various issues related to human tissue usage, especially ethical concerns, researchers use large- and small-animal models to study cardiac pathophysiology. A simple model to study the changes at the cellular level is cultures of cardiomyocytes. Although primary murine cardiomyocyte cultures have their own advantages and drawbacks, alternative strategies have been developed in the last two decades to minimise animal usage and interspecies differences. This review discusses the use of freshly isolated murine cardiomyocytes and cardiomyocyte alternatives for use in cardiac disease models and other related studies.

Multipotent stem cells from adult olfactory mucosa

Multipotent stem cells are thought to be responsible for the generation of new neurons in the adult brain. Neurogenesis also occurs in an accessible part of the nervous system, the olfactory mucosa. We show here that cells from human olfactory mucosa generate neurospheres that are multipotent in vitro and when transplanted into the chicken embryo. Cloned neurosphere cells show this multipotency. Multipotency was evident without prior culture in vitro: cells dissociated from adult rat olfactory mucosa generate leukocytes when transplanted into bone marrow-irradiated hosts, and cells dissociated from adult mouse olfactory epithelium generated numerous cell types when transplanted into the chicken embryo. It is unlikely that these results can be attributed to hematopoietic precursor contamination or cell fusion. These results demonstrate the existence of a multipotent stem-like cell in the olfactory mucosa useful for autologous transplantation therapies and for cellular studies of disease.

Modulation of sarcomere organization during embryonic stem cell-derived cardiomyocyte differentiation

Myofibrillogenesis - sarcomeres - mouse embryonic stem cells - cardiomyocytes - beta1 integrin Mouse embryonic stem (ES) cells, when cultivated as embryoid bodies, differentiate in vitro into cardiomyocytes of ventricle-, atrium- and pacemaker-like cell types characterized by developmentally controlled expression of cardiac-specific genes, structural proteins and ion channels. Using this model system, we show here, (I) that during cardiac myofibrillogenesis sarcomeric proteins are organized in a developmentally regulated manner following the order: titin (Z-disk), alpha-actinin, myomesin, titin (M-band), myosin heavy chain, alpha-actin, cardiac troponin T and M-protein, recapitulating the sarcomeric organization in the chicken embryonal heart in vivo. Our data support the view that the formation of I-Z-I complexes is developmentally delayed with respect to A-band assembly. We show (2) that the process of cardiogenic differentiation in vitro is influenced by medium components: Using a culture medium supplemented with glucose, amino acids, vitamins and selenium ions, we were able to increase the efficiency of cardiac differentiation of wild-type, as well as of beta1 integrin-deficient (beta1-/-) ES cells, and to improve the degree of organization of sarcomeric structures in wild-type and in beta1-/- cardiac cells. The data demonstrate the plasticity of cardiogenesis during the differentiation of wild-type and of genetically modified ES cells.

Distribution and organization of desmin in cultured adult cardiac muscle cells: reflection on function

The cell-culture model for the study of desmin in adult cardiac muscle cells has provided insight into the function of desmin based on its distribution and structural organization. Initially, desmin emerged as a filamentous network from the existing amorphous form in the growing adult cardiac myocytes in vitro. Later, desmin became organized in various forms. In addition to the presence of a periodic array of desmin in the Z-line regions as observed in cardiac myocytes in vivo, longitudinally and transversely oriented strands of desmin were observed along the length of myofibrils in cardiac myocytes in vitro. These desmin strands and transverse perodicities formed a complex interwoven network, interlacing myofibrils of cells. Desmin and alpha-actinin were organized in ribbon- or aponeuroses-like structures that appeared as sheet-like, supportive structures for the cell body. The cellular cytoplasmic processes containing myofibrils were supported by desmin bars. The complex desmin network, desmin bars, transverse strands and ribbons or aponeuroses were observed in in vitro cardiac myocytes in contrast to in vivo cardiac myocytes. The functional implication of desmin, as indicated by in vivo studies, required more information concerning the organization of desmin for its supportive function, and is addressed in the present study. The elaborate organization of desmin provides evidence for its supportive function for the maintenance of the structural integrity and function of cardiac muscle cells.

Stability of the contractile assembly and Ca2+-activated tension in adenovirus infected adult cardiac myocytes

Adenovirus-mediated gene transfer into adult cardiac myocytes in primary culture is a potentially useful method to study the structure and function of the contractile apparatus. However, the consequences of adenovirus infection on the highly differentiated state of the cultured myocyte have not been determined. We report here a detailed analysis of myofilament structure and function over time in primary culture and after adenovirus infection. Adult rat ventricular myocytes in primary culture were infected with a recombinant adenovirus vector expressing either the LacZ or alkaline phosphatase reporter gene. Control and infected myocytes were collected at days 0-7 post-isolation/infection, and myofilament isoform expression was determined by SDS-PAGE and Western blot. Laser scanning densitometry showed that the alpha- to beta-myosin heavy chain ratio, the stoichiometry of the myosin light chains and the expression of the adult troponin T isoform did not change over time in culture or with adenovirus treatment. Importantly, examination of Ca2+-activated tension in single myocytes showed no change in the shape or position of the tension-pCa relationship in the control and adenovirus infected myocytes during primary culture. These results indicate that the structure and function of adult cardiac myocytes are stable in short term primary culture and are not affected by adenovirus infection per se, and therefore provide the foundation for the use of adenovirus-mediated myofilament gene transfer to study contractile apparatus structure and function in adult cardiac myocytes.

TPA has no influence on the expression of myosin heavy chain isoforms in cultured adult cardiac muscle cells

The effect of a tumor promoter, 12-O-tetradecanoyl phorbol-13-acetate (TPA), on the expression of myosin heavy chain isoforms in cultured rat cardiac ventricular muscle cells was studied. The previous preliminary report [Claycomb WC (1988): "Biology of Isolated Adult Cardiac Myocytes." In Clark WA, Decker RS, Borg TK (eds): New York: Elsevier, pp 284-287] indicated that TPA turns off the expression of myosin heavy chain genes in cultured adult cardiac myocytes. Electrophoretic and immunocytochemical analyses were carried out in the present studies. The myosin heavy chain isoform profiles of cardiac myocytes exposed to TPA at concentrations of 50-250 ng/ml culture medium for varying periods were similar to those of controls that were grown in the absence of TPA, showing predominant isoform V1. Immunofluorescence microscopy with monoclonal antibodies to cardiac ventricular isomyosin revealed the structural organization of myosin in TPA-treated cells. The organization of myosin was variable among different myocytes and within a single myocyte. Immunofluorescence microscopy was extended to the examination of the organization of alpha-actinin which did not differ from that of myosin in some myocytes. In contrast to the previous report [Claycomb, 1988], this study has demonstrated that TPA has no influence on the expression of myosin heavy chain isoforms in cultured adult ventricular cardiac muscle cells.

A method for the harvest, culture, and characterization of human adult atrial myocardial cells: correlation with age of donor

Myocardial cell culture methods are now well established for animal and fetal human tissue. We present here a method for harvesting and culturing adult human atrial myocardiocytes. Cells are obtained from fresh atrial tissue normally discarded after being removed to cannulate the right atrium during open heart surgery. The atrial tissue is minced and then digested using collagenase. The single cell suspension is initially cultured in serum-containing growth medium, then transferred to defined medium, selective for myocardial cell growth. The cells are characterized by immunoperoxidase stains and transmission electron microscopy. The cultured cells stain positive for myoglobin, whereas control cultured fibroblasts and endothelial cells do not. Electron microscopy shows the presence of numerous myofibrils, Z-bodies, pleomorphic mitochondria, and secretory granules. The chronological age of the donor was an important factor in culturing the adult tissue, the younger tissue correlated with a higher success rate. This method provides a means for in vitro study of human adult myocardial cells and provides guidelines for appropriate atrial tissue to use.

Differential response of cultured adult cardiac muscle cells to a tumor promotor: analysis of myofibrillar organization

Cultured adult rat ventricular cardiac muscle cells were exposed to varying concentrations of 12-0-tetradecanoyl-phorbol-13 acetate (TPA) for two weeks. A considerable number of cardiac myocytes exposed to a medium with less than 200 ng/ml TPA were rich in myofibrils. The rest of the myocytes lacked organized myofibrils; the terminal parts of these myofibrils were transformed into cord-like structures largely consisting of dense Z-band materials. Some of these aberrant myofibrils contained short normal myofibrillar segments, with sarcomeres. A number of myocytes exposed to 200-250 ng/ml TPA contained myofibrils, which terminated in cord-like structures. The Z-band materials appeared as amorphous dense matrices and some sarcomeres were replaced completely or partially by leptomeres; the myocytes contained autophagosomes. The other myocytes did not contain myofibrils when exposed to the above higher concentrations of TPA. The patches of Z-band materials and structures containing Z-band materials attached to thin filaments on either side were scattered throughout the sarcoplasm of the cells, which were packed with myofilaments and 10 nm microfilaments. Some of these myocytes assumed a spindle shape and contained myofilaments, 10 nm microfilaments and leptomeres. Some of the myocytes, treated with TPA for 1-7 days and then allowed to recover in control medium for 7 days, contained various stages of myofibrillar organization, which did not differ significantly from those of the myofibril-containing cells exposed continuously to TPA as discussed above. The rest of the myocytes during the recovery period in control medium did not contain myofibrils. Rough endoplasmic reticulum and Golgi bodies in TPA-treated myocytes were found to be highly developed as compared to the controls. It is evident from these studies that the responsiveness of cardiac myocytes to TPA not only differs from that of skeletal muscle cells studied by others, but also varies within a population of cardiac myocytes.