Expression and cellular distribution of alpha(v)integrins in beta(1)integrin-deficient embryonic stem cell-derived cardiac cells.

:beta(1)integrin-deficient (beta(1)-/-) ES cells showed increased differentiation of cardiac cells characterized by reduced adhesion and high beating frequency. Whereas in whole embryoid body outgrowths of beta(1)-/- cells maximum levels of alpha(v), beta(3)and beta(5)integrin mRNA were delayed and transiently upregulated, in cardiac clusters isolated from beta(1)-/- cells, only beta(3)integrin mRNA levels were enhanced in comparison to wild-type (wt) cells. To answer the question, whether alpha(v)and beta(3)integrins may compensate, at least partially, the loss of beta(1)integrin function during cardiac differentiation, the distribution of alpha(v)and beta(3)integrins in beta(1)-/- and wt pacemaker-like cardiac cells was analyzed. A different distribution of alpha(v)and beta(3)integrins in beta(1)-/- v wt cardiac cells was found. In wt cardiac cells, beta(1)integrin was localized in specialized subsarcolemmal regions, in particular, at focal contacts and costameres, but alpha(v)integrin was diffusely distributed. In contrast, in beta(1)-/- cardiac cells, alpha(v)integrin was preponderantly localized at cell membranes, focal contacts and costameres. beta(3)integrin displayed a diffuse pattern both in wt and in beta(1)-/- pacemaker-like cells at early differentiation stages, whereas at terminal stages, beta(3)was colocalized with sarcomeres in wt, but not in beta(1)-/- pacemaker-like cells. Quantitative immunofluorescence analysis revealed increased alpha(v)and beta(3)integrin levels in beta(1)-/- pacemaker-like cardiac cells. Our results led us to conclude that altered cellular distribution of alpha(v)integrin and upregulation of beta(3)integrin correlate with growth and survival of beta(1)-/- cardiac pacemaker-like cells at an early developmental state. However, alpha(v)and beta(3)integrins cannot functionally compensate the loss of beta(1)integrin during terminal differentiation of cardiac cells implicating that cardiomyocytes require specific beta(1)integrin functions for cardiac specialization.

Guan K ，Czyz J ，Fürst DO ，Wobus AM ... -  《JOURNAL OF MOLECULAR AND CELLULAR CARDIOLOGY》

Loss of beta 1 integrin function results in upregulation of connexin expression in embryonic stem cell-derived cardiomyocytes.

Czyz J ，Guan K ，Zeng Q ，Wobus AM ... -  《INTERNATIONAL JOURNAL OF DEVELOPMENTAL BIOLOGY》

Relationship between the cellular distribution of the alpha(v)beta3/5 integrins and adenoviral infection in salivary glands.

Delporte C ，Redman RS ，Baum BJ 《LABORATORY INVESTIGATION》

Expression of the alpha 6A integrin splice variant in developing mouse embryonic stem cell aggregates and correlation with cardiac muscle differentiation.

Thorsteinsdóttir S ，Roelen BA ，Goumans MJ ，Ward-van Oostwaard D ，Gaspar AC ，Mummery CL ... -  《DIFFERENTIATION》

Loss of beta1 integrin function results in a retardation of myogenic, but an acceleration of neuronal, differentiation of embryonic stem cells in vitro.

Integrin cell surface receptors play an important role for cell adhesion, migration, and differentiation during embryonic development by mediating cell-cell and cell-matrix interactions. Less is known about the function of integrins during commitment and lineage determination of early embryogenesis. Homozygous inactivation of the beta1 integrin gene results in embryonal death in mice around the time of implantation. In vitro, differentiation of embryonic stem (ES) cells which lack beta1 integrin (beta1-/-) into the cardiogenic lineage is delayed and results in a disordered cellular specification (Fässler et al., J. Cell Sci. 109, 2989-2999, 1996). To analyze beta1 integrin function during myogenesis and neurogenesis we studied differentiation of beta1-/- ES cells via embryoid bodies into skeletal muscle and neuronal cells in vitro. beta1-/- cells showed delayed and reduced myogenic differentiation compared to wildtype and heterozygous (beta1+/-) ES cells. RT-PCR analysis demonstrated delayed expression of skeletal muscle-specific genes in the absence of beta1 integrin. Immunofluorescence studies with antibodies against the sarcomeric proteins myosin heavy chain, titin, nebulin, and slow C-protein showed that myotubes formed, but their number was reduced and the assembly of sarcomeric structures was retarded. In contrast, neuronal cells differentiating from beta1-/- ES cells appeared earlier than wildtype and heterozygous (beta1+/-) ES cells. This was shown by the accelerated expression of neuron-specific genes and an increased number of neuronal cells in beta1-/- embryoid bodies. However, neuronal outgrowth was retarded in the absence of beta1 integrin. No functional difference between wildtype and beta1-/- cells was found with respect to secretion of gamma-aminobutyric acid, the main neurotransmitter of ES cell-derived neuronal cells. The lineage-specific effects of loss of beta1 integrin function, that is the inhibition of mesodermal and acceleration of neuroectodermal differentiation, were supported by differential expression of genes encoding lineage-specific transcription factors (Brachyury, Pax-6, Mash1) and signaling molecules (BMP-4 and Wnt-1). Because of the reduced and delayed expression of the BMP-4 encoding gene in beta1-/- cells, we analyzed in wildtype and beta1-/- cells the regulatory role of exogenously added BMP-4 on the expression of the mesodermal and neuronal marker genes, Brachyury and wnt-1, respectively. The data suggest that BMP-4 plays a regulatory role during differentiation of wildtype and beta1-/- cells by modifying mesodermal and neuronal pathways. The reduced expression of BMP-4 in beta1-/- cells may account for the accelerated neuronal differentiation in beta1-/- ES cells.

Rohwedel J ，Guan K ，Zuschratter W ，Jin S ，Ahnert-Hilger G ，Fürst D ，Fässler R ，Wobus AM ... -  《DEVELOPMENTAL BIOLOGY》