Mechanical forces play a major role in the regulation of cell adhesion and cytoskeletal organization. In order to explore the molecular mechanism underlying this regulation, we have investigated the relationship between local force applied by the cell to the substrate and the assembly of focal adhesions. A novel approach was developed for real-time, high-resolution measurements of forces applied by cells at single adhesion sites. This method combines micropatterning of elastomer substrates and fluorescence imaging of focal adhesions in live cells expressing GFP-tagged vinculin. Local forces are correlated with the orientation, total fluorescence intensity and area of the focal adhesions, indicating a constant stress of 5.5 +/- 2 nNmicrom(-2). The dynamics of the force-dependent modulation of focal adhesions were characterized by blocking actomyosin contractility and were found to be on a time scale of seconds. The results put clear constraints on the possible molecular mechanisms for the mechanosensory response of focal adhesions to applied force.
Death-associated protein kinase (DAPk) and DAPk-related protein kinase (DRP)-1 proteins are Ca+2/calmodulin–regulated Ser/Thr death kinases whose precise roles in programmed cell death are still mostly unknown. In this study, we dissected the subcellular events in which these kinases are involved during cell death. Expression of each of these DAPk subfamily members in their activated forms triggered two major cytoplasmic events: membrane blebbing, characteristic of several types of cell death, and extensive autophagy, which is typical of autophagic (type II) programmed cell death. These two different cellular outcomes were totally independent of caspase activity. It was also found that dominant negative mutants of DAPk or DRP-1 reduced membrane blebbing during the p55/tumor necrosis factor receptor 1–induced type I apoptosis but did not prevent nuclear fragmentation. In addition, expression of the dominant negative mutant of DRP-1 or of DAPk antisense mRNA reduced autophagy induced by antiestrogens, amino acid starvation, or administration of interferon-γ. Thus, both endogenous DAPk and DRP-1 possess rate-limiting functions in these two distinct cytoplasmic events. Finally, immunogold staining showed that DRP-1 is localized inside the autophagic vesicles, suggesting a direct involvement of this kinase in the process of autophagy.
Adherens‐type junctions (AJs) are major subcellular targets for tyrosine specific protein phosphorylation [Volberg et al. (1991) Cell Regul., 2, 105–120]. Here we report on the apparent effect of such phosphorylation events on the assembly and integrity of AJs. We show that incubation of MDCK cells with potent inhibitors of tyrosine‐specific phosphatases (PTP), namely H2O2 and vanadate, leads to a dramatic increase in AJ‐associated phosphotyrosine which was apparent already within 2–5 min of treatment and progressed upon further incubation. Examination of H2O2 vanadate treated cells at later time points indicated that intercellular AJs rapidly deteriorated, concomitantly with a marked increase in the number and size of vinculin and actin containing focal contacts. In parallel, major changes were observed in cell structure and topology, as revealed by electron microscopy. These were manifested by rapid rounding‐up of the cells followed by reorganization of the cell monolayer. Other intercellular junctions, including desmosomes and tight junctions, visualized by staining with desmoplakin and ZO‐I antibodies, were not significantly affected. To verify that modulation of AJs was indeed related to tyrosine phosphorylation, we have carried out reciprocal experiments in which Rovs Sarcoma virus (RSV) transformed chick lens cells, expressing high levels of pp60src kinase, were treated with inhibitors of tyrosine kinases, (tyrphostins). We show that following such treatment, intercellular AJs which were deteriorated in the transformed cells, were reformed. Based on these observations, we propose that specific tyrosine phosphorylation of AJ components is involved in the downregulation of these cellular contacts.
Poxviruses are considered to be unique among all DNA viruses, because their infection cycle is carried out exclusively in the host cytoplasm. Such an infection strategy is of interest, because it necessitates generation of elaborate factories in which viral replication and assembly are promoted. By using diverse imaging techniques, we show that the infection cycle of the largest virus currently identified, the Acanthamoeba polyphaga Mimivirus, similarly occurs exclusively in the host cytoplasm. We further show that newly synthesized mRNAs accumulate at discrete cytoplasmic sites that are distinct from the sites where viral replication occurs, and this is observed in vaccinia infection. By revealing substantial physiologic similarity between poxviruses and Mimivirus and thus, implying that an entirely cytoplasmic viral replication might be more common than generally considered, these findings underscore the ability of DNA viruses to generate large and elaborate replication factories.electron tomography | nucleocytoplasmic large DNA viruses | poxviruses | viral factories W ith the single exception of poxviruses, all currently known DNA viruses carry out replication and transcription either entirely or partially within host nuclei. The overwhelming bias to nucleus-centered viral transactions is rationalized by the fact that the nucleus provides the elaborate machinery required for these processes. Moreover, by concentrating essential factors into particular intranuclear sites as well as by enabling spatiotemporal regulation of viral replication and transcription, the nuclear environment considerably enhances the efficiency of these processes (1). Such underlying benefits render the entirely cytoplasmic infection cycle of poxviruses all of the more intriguing (2, 3). Nucleus-centered viral transactions present, however, remarkable hurdles associated with the prerequisite of transporting viral genomes from their entry sites at the cell periphery to and into the nucleus. Specifically, the cellular milieu is refractory to motion of DNA molecules because of the high viscosity of the cytosol and the dense molecular sieve generated by the cytoskeleton (4). Moreover, the nuclear envelope imposes a severe barrier for both entry and exit of long DNA molecules (1).The hurdles associated with genome trafficking are particularly high for nucleocytoplasmic large DNA viruses (NCLDV), which include the eukaryote-infecting families Poxviridae, Phycodnaviridae, Iridoviridae, and Asfarviridae, all characterized by DNA genomes longer than 100 kbp (5). After entry, genomes of phycodnaviruses (6), iridoviruses (7), and the African swine fever virus (8) are released into the cytoplasm at the host cell periphery and then, are shuttled toward and transported into the nucleus where initial replication cycles occur. Viral DNA is subsequently delivered to specific cytoplasmic factories in which all transactions required for viral assembly take place. The factors that attenuate the barriers imposed by the constrained DNA motion and thus, enabl...
Abstract. Transfection of chicken vinculin cDNA into two tumor cell lines expressing diminished levels of the endogenous protein, brought about a drastic suppression of their tumorigenic ability. The SV-40-transformed Balb/e 3T3 line (SV'F2) contains four times less vinculin than the parental 3T3 cells, and the rat adenocarcinoma BSp73ASML has no detectable vinculin. Restoration of vinculin in these cells, up to the levels found in 3T3 cells, resulted in an apparent increase in substrate adhesiveness, a decrease in the ability to grow in soft agar, and suppression of their eapacity to develop tumors after injection into syngeneic hosts or nude mice. These results suggest that vinculin, a cytoplasmic component of cell-matrix and cell-cell adhesions, may have a major suppressive effect on the transformed phenotype.
The inducible SOS response increases the ability of bacteria to cope with DNA damage through various DNA repair processes in which the RecA protein plays a central role. Here we present the first study of the morphological aspects that accompany the SOS response in Escherichia coli. We find that induction of the SOS system in wild-type bacteria results in a fast and massive intracellular coaggregation of RecA and DNA into a lateral macroscopic assembly. The coaggregates comprise substantial portions of both the cellular RecA and the DNA complement. The structural features of the coaggregates and their relation to in vitro RecA-DNA networks, as well as morphological studies of strains carrying RecA mutants, are all consistent with the possibility that the intracellular assemblies represent a functional entity in which RecA-mediated DNA repair and protection activities occur.biocrystallization ͉ DNA repair ͉ homology search ͉ stress response R ecA-mediated DNA recombination and repair processes proceed through several sequential phases (1-3). A presynaptic filament in which RecA molecules coat a single-stranded DNA substrate is initially formed. The filament acts then as a sequence-specific DNA-binding entity, capable of searching and binding dsDNA sites that are homologous to the RecA-coated segment. Within the resulting joint species, DNA strand exchange and heteroduplex extension processes are promoted. The mechanism that enables a rapid search for DNA homology in vivo, within a highly crowded and complex genome, remains enigmatic.To reach its target, any sequence-specific DNA-binding protein must overcome two general obstacles: a minute cellular concentration of the target, and a vast excess of nontarget, yet still competitive, DNA sites. The search for a homologous DNA site conducted by the RecA-DNA presynaptic filament shares these hurdles, but is further encumbered by the uniquely adverse diffusion characteristics of its components. A DNA target corresponds to a segment that is part of, and embedded within, the chromosome. This, and the large structural asymmetry of DNA, conspire to minimize the diffusion constant of DNA sites (4, 5). In a homology search executed by the RecA-DNA filament, both the searching and the target entities are chromosomal DNA sites whose small diffusion constants drastically attenuate their encounter rate. How then does a RecA-mediated intracellular search evade the kinetic impediments that are intrinsic to the nature of its components?Here we show that damages inflicted on bacterial DNA lead to a rapid formation of an ordered intracellular assembly that accommodates both RecA and DNA. We suggest that the striated morphology of this RecA-DNA assembly is capable of promoting an in vivo homology search by attenuating both the sampling volume and the dimensionality of the process. Moreover, RecA was shown to protect chromosomal DNA from degradation (6) through unknown mechanisms. The tight crystalline packaging that is progressively assumed by the intracellular RecA-DNA assemblies as ...
Invadopodia are actin-rich membrane protrusions through which cells adhere to the extracellular matrix and degrade it. In this study, we explored the mechanical interactions of invadopodia in melanoma cells, using a combination of correlative light and electron microscopy. We show here that the core actin bundle of most invadopodia interacts with integrin-containing matrix adhesions at its basal end, extends through a microtubule-rich cytoplasm, and at its apical end, interacts with the nuclear envelope and indents it. Abolishment of invadopodia by microtubules or src inhibitors leads to the disappearance of these nuclear indentations. Based on the indentation profile and the viscoelastic properties of the nucleus, the force applied by invadopodia is estimated to be in the nanoNewton range. We further show that knockdown of the LINC complex components nesprin 2 or SUN1 leads to a substantial increase in the prominence of the adhesion domains at the opposite end of the invadopodia. We discuss this unexpected, long-range mechanical interplay between the apical and basal domains of invadopodia, and its possible involvement in the penetration of invadopodia into the matrix.
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