Activated cofilin colocalises with Arp2/3 complex in apoptotic blebs during programmed cell death.

Etoposide inhibits topoisomerase II and induces apoptosis in human epidermoid cancer cells (A431) and normal rat fibroblasts (NRK) as verified by apoptotic morphology and chromatin degradation. Here we examine changes in the localisation of actin, cofilin and the Arp2/3 complex during the apoptotic process in response to etoposide. Twenty-four hours after etoposide addition, a large number of cells of both lines exhibited nuclear and cytoplasmic fragmentation with the formation of numerous blebs typical of apoptosis. Etoposide exposure induces dissolution of stress fibres and an increase in actin and cofilin in membrane patches and apoptotic blebs. The actin is more peripherally located than the cofilin, similar to that reported for lamellipodia of highly motile keratocytes. By contrast, in control cells, cofilin is evenly distributed throughout the cytoplasm, though often enriched around the nucleus. The active form is inferred to be more peripherally localised and to be present in apoptotic blebs, since an antibody specific for phosphorylated cofilin did not stain the cell periphery nor apoptotic blebs. Although immunoblots of 2D gels demonstrate that the ratio of de-phosphorylated to phosphorylated cofilin does not change after etoposide treatment, this does not mean that there are no changes in the turnover of the active and inactive forms. Transfection of both cell lines with EGFP-containing constructs of wild-type cofilin and mutants resembling its activated (S3A) and inactivated (S3D) forms shows that the active form has a more peripheral localisation and is also present in the membrane blebs with a strong colocalisation with actin. We further show that Arp2/3 also localises in apoptotic blebs and discuss the role of these proteins in apoptosis by analogy with actin-based protrusive motility in lamellipodia.

Modulation of actin filament dynamics by actin-binding proteins residing in lamellipodia.

Lamellipodial extension depends essentially on the polymerisation cycle of actin. In this cellular compartment the rate and extent of actin polymerisation is tightly regulated by a large number of actin-binding proteins. The main regulators comprise proteins of the actin-depolymerising factor (ADF)/cofilin family, which stimulate actin cycling, but there are also minor constituents like gelsolin and certain variants of tropomyosin that have so far not been considered to be lamellipodial constituents. A number of cell lines express ADF and cofilin simultaneously as shown here for the fibroblastic normal rat kidney (NRK) cell line. Both proteins co-localise in the lamellipodial region. We furthermore demonstrate the presence of gelsolin in lamellipodia by immunostaining with anti-gelsolin antibodies and transfection with EGFP-tagged gelsolin constructs. The presence of tropomyosins in lamellipodia has recently been reported (Hillberg et al., 2006. Tropomyosins are present in lamellipodia of motile cells. Eur. J. Cell Biol. 85, 399-409). In order to evaluate the effect of the simultaneous presence of ADF and cofilin together with tropomyosin and/or gelsolin on the polymerisation cycle of actin, we analysed their effect or combinations of these actin-binding proteins on the steady-state F-actin-ATPase activity in biochemical assays. Our results demonstrate stimulatory effects of ADF/cofilin on actin cycling and a further modulation of ADF/cofilin-stimulated F-actin-ATPase activity by gelsolin and tropomyosin in a complex manner.

Binding of a C-terminal fragment (residues 369 to 435) of vitamin D-binding protein to actin.

The vitamin D-binding protein (DBP) binds to monomeric actin with high affinity. The variation in DBP isoforms is due to genetic polymorphism and varying glycosylation. To obtain a homogeneous preparation, the cDNA for human DBP and truncations thereof were cloned and various systems were applied for heterologous bacterial and yeast expression. The full-length protein and the N- and C-terminal halves of DBP remained insoluble probably because the protein did not fold to its native three-dimensional structure due to formation of accidental intra- and inter-molecular disulfide bonds during expression in bacteria or yeast. This problem was overcome by cloning of a C-terminal fragment comprising residues 369 to 435 that did not contain disulfide bonds and was completely soluble. Binding of the C-terminal fragment to monomeric actin was demonstrated by comigration with actin during native polyacrylamide gel electrophoresis and surface plasmon resonance, however, at considerably lower affinity than full-length DBP. This suggests that in addition to the C-terminal amino acid sequence other parts (amino acid residues or sugar moieties) of DBP participate in actin binding. The C-terminal fragment was found to inhibit denaturation of actin and to decrease the rate of actin polymerisation both at the barbed and at the pointed end in a concentration-dependent manner. According to a quantitative analysis of the polymerisation kinetics, association of actin monomers to nucleate filaments was not prevented by binding of the C-terminal fragment to actin. These data suggest that the sites on the surface of actin that are involved in actin nucleation and elongation are different.