A genetic melanotic neoplasm of Drosophila melanogaster

The construction of mature fruiting bodies occurs during the culmination stage of development of Dictyostelium discoideum. These contain at least two different cell types, spores and stalks, which originate from an initially homogenous population of vegetative amoebas. As an attempt to identify proteins whose synthesis is regulated in each cell type during differentiation, we have analyzed the two-dimensional profiles of proteins synthesized by spore and stalk cells during the culmination stage. We have identified 5 major polypeptides which are specifically synthesized by spore cells during culmination and 9 which are only made by stalk cells. Furthermore, synthesis of about 20 polypeptides appears to be enriched either in the spore or in the stalk cells. We also show that synthesis of actin, a major protein synthesized during Dictyostelium development, is specifically inhibited in the spore cells during culmination. Synthesis of most of the cell type-specific proteins initiates at 19–20 hr, during culmination. Moreover, the proteins whose synthesis is induced after formation of tight aggregates, the time when the major change in gene expression occurs, are not specifically incorporated into spores or stalk cells, and appear to be synthesized by both cell types. We conclude that a new class of genes is expressed during the culmination stage in Dictyostelium, giving rise to specific patterns of protein synthesis in spore and stalk cells.     

Cytoskeletal organization affects cellular responses to cytochalasins: comparison of a normal line and its transformant

The relationships between cytoskeletal network organization and cellular response to cytochalasin D (CD) in a normal rat fibroblast cell line (Hmf-n) and its spontaneous transformant (tHmf-e), with markedly different cytoskeletal phenotypes, were compared (using immunofluorescence, electron microscopy, and DNAse I assay for actin content). Hmf-n have prominent, polar stress fiber (SF) arrays terminating in vinculin adhesion plaques whereas tHmf-e, which are apolar, epithelioid cells with dense plasma membrane-associated actin networks, lack SF and adhesion plaques. Hmf-n exposed to CD become markedly retracted and dendritic, SF-derived actin aggregates form large endoplasmic masses, and discrete tabular aggregates at the distal ends of retraction processes. Prolonged exposure leads to recession of process, cellular rounding, and development of large cystic vacuoles. tHmf-e cells exposed to similar doses of CD display a diagnostically different response; retraction is less drastic, cells retain broad processes containing scattered actin aggregates in discrete foci often associated with plasma membrane, large tabular aggregates are never found and processes persist throughout long exposure, vacuolation is uncommon. The CD-induced microfilamentous aggregates in Hmf-n are composed of short, kinky filament fragments forming a felt-like skein, often aggregates contain a more ordered array of roughly parallel fragments, while those of tHmf-e are very short, kinky, randomly orientated filaments imparting a distinctly granular nature to the mass. Total actin content and the amount of actin associated with detergent-resistant cytoskeletons increase following CD exposure in both cell types. Throughout exposure to CD, the actin-associated contractile proteins tropomyosin, myosin, and alpha-actinin co-localize within the actin aggregates in both cell types. Fodrin, the protein linking cortical actin to membrane, co-localizes with actin aggregates in tHmf-e cells and most, but not all, such aggregates in Hmf-n cells, consistent with their stress fiber derivation. Vinculin is lost from the tabular aggregates at the distal ends of retraction processes in Hmf-n cells concomitant with the fragmentation and contraction of SF. The aborized processes in both cells types contain strikingly similar axial cores of bundled vimentin filaments associated with passively compressed microtubules. The characteristic CD-induced distribution of actin filament aggregates and redistribution of vimentin in these cell types also occur when cells are allowed to respread from the rounded state in the presence of CD.     

Cortical actin filaments fragment and aggregate to form chloroplast-associated and free F-actin rings in mechanically isolatedZinnia mesophyll cells

Summary Changes in F-actin organization following mechanical isolation ofZinnia mesophyll cells were documented by rhodamine-phalloidin staining. Immediately after isolation, most cells contained irregular cortical actin fragments of varying lengths, and less than 5% of cells contained intact cortical filaments. During the first 8 h of culture, filament fragments were replaced by actin rings, stellate actin aggregates, and bundled filament fragments. Some of these aggregates had no association with organelles (free actin aggregates). Other aggregates were associated with chloroplasts, which changed in shape and location at the same time actin aggregates appeared. F-actin was concentrated within or around the nucleus in a small percentage of cells. After 12 h in culture, the percentage of cells with free actin rings and chloroplast-associated actin aggregates began to decline and the percentage of cells having intact cortical actin filaments increased greatly. Intermediate images were recorded that strongly indicate that free actin rings, chloroplast-associated actin rings, and other actin aggregates self-assemble by successive bundling of actin filament fragments. The fragmentation and bundling of F-actin observed in mechanically isolatedZinnia cells resembles changes in F-actin distribution reported after diverse forms of cell disturbance and appears to be an example of a generalized response of the actin cytoskeleton to cell stress.Abbreviations FITC fluorescein isothiocyanate - MBS m-maleimidobenzoic acid N-hydroxysuccinimide ester - RhPh tetramethylrhodamine isothiocyanate-phalloidin     

Poly(a)+ rna during vegetative development ofacetabularia peniculus

Summary In the juvenile stage, the diploid giant-celled green algae Acetabularia spp. are differentiated into an upright stalk and an irregularly branched rhizoid. Early amputation and grafting experiments as well as biochemical and molecular analyses have shown that mRNA (as poly(A)⁺ RNA) is continuously supplied from the primary nucleus in the rhizoid and accumulates in the stalk apex. In the present study, localization of poly(A)⁺ RNA in the juvenile stage of theAcetabularia peniculus was investigated by fluorescent in situ hybridization using oligo(dT) as a probe. The signal was localized in the apical cytoplasm and, in addition, multiple longitudinal striations throughout the stalk and rhizoid cytoplasm. A large portion of the poly(A)⁺ RNA striations exhibited structural polarity, broadened at one end and gradually thinned toward the other end. Some of the striations in the rhizoid cytoplasm were continuous with a zone of signal in the area of the perinuclear rim. The poly(A)⁺ RNA striations were associated with thick bands of longitudinal actin bundles which run through the entire length of the stalk. Cytochalasin D caused fragmentation of the actin bundles and irregular distribution of the fluorescent signal. We suggest that the poly(A)⁺ RNA striations constitute a hitherto unknown form of packaged mRNA that is transported over large distances along the actin cytoskeleton to be stored and expressed in the growing apex.     

The organisation of fruiting body formation in Dictyostelium minutum

The process of culmination was investigated in three strains of the species Dictyostelium minutum. After aggregates have been formed a pulsatile signalling mechanism arises; the centre of signal emission becomes the apex of the developing fruiting structure. In the late aggregate, all cells differentiate into prespore cells. Cells that have reached the apex of the culminating cells mass redifferentiate into stalk cells. In two of the three D. minutum strains, interruption of regular stalk formation, more or less random formation of stalk cells and the synthesis of stalk supporting material from cell debris often takes place. The formation of multiple apices on aggregates and early fruiting structures is characteristic for these two strains. Within the species D. minutum, the exhibition of a marked pulsatile signalling mechanism is correlated with a capacity to form a regularly shaped stalk and to organize relatively large cell masses. The possible function of pulsatile signalling in the culmination process is discussed.     

Prion‐like protein aggregates exploit the RHO GTPase to cofilin‐1 signaling pathway to enter cells

Protein aggregation is a hallmark of diverse neurodegenerative diseases. Multiple lines of evidence have revealed that protein aggregates can penetrate inside cells and spread like prions. How such aggregates enter cells remains elusive. Through a focused siRNA screen targeting genes involved in membrane trafficking, we discovered that mutant SOD1 aggregates, like viruses, exploit cofilin‐1 to remodel cortical actin and enter cells. Upstream of cofilin‐1, signalling from the RHO GTPase and the ROCK1 and LIMK1 kinases controls cofilin‐1 activity to remodel actin and modulate aggregate entry. In the spinal cord of symptomatic SOD1^G93A transgenic mice, cofilin‐1 phosphorylation is increased and actin dynamics altered. Importantly, the RHO to cofilin‐1 signalling pathway also modulates entry of tau and α‐synuclein aggregates. Our results identify a common host cell signalling pathway that diverse protein aggregates exploit to remodel actin and enter cells.     

Morphogenesis and differentiation of Dictyostelium cells interacting with immobilized glucosides: dependence on DIF production

Previous work has shown that multicellular morphogenesis of submerged Dictyostelium cells is inhibited when they bind to glucosides covalently linked to polyacrylamide gels. The amoebae aggregate normally, but then the aggregates repeatedly disperse and reaggregate, whereas control cells go on to form tight aggregates. We have investigated the role of the stalk cell differentiation inducing factors (DIFs) in this process. In the presence of cyclic AMP, amoebae submerged at high cell density accumulate DIF and differentiate into stalk cells. We find that stalk cell differentiation is inhibited by interaction of the cells with glucoside gels in these conditions, but can be restored by the addition of exogenous DIF-1. Since the responsiveness of cells to DIF-1 is not altered, it appears likely that the effect of the glucoside gel is to block DIF-1 production. Further, the addition of DIF-1 or DIF-2 stimulates the formation of tight aggregates by cells developing on glucoside gels in the absence of cyclic AMP, thus preventing the rounds of aggregation and disaggregation otherwise seen. This suggests a role for DIF in morphogenesis as well as in controlling cell differentiation. We propose a model in which immobilized glucosides activate a specific receptor ("food sensor") which drives the amoebae toward the vegetative state and inhibits DIF accumulation. DIF, on the other hand, induces tight aggregate formation and so locks the amoebae into the developmental program.     

Carbonylation of the cytoskeletal protein actin leads to aggregate formation

Protein carbonylation is a common feature in cells exposed to oxidants, leading to protein dysfunction and protein aggregates. Actin, which is involved in manifold cellular processes, is a sensitive target protein to this oxidative modification. T-cell proteins have been widely described to be sensitive targets to oxidative modifications. The aim of this work was to test whether the formation of protein aggregates contributes to the impaired proliferation of Jurkat cells after oxidative stress and to test whether actin as a major oxidation-prone cytoskeletal protein is an integral part of such protein aggregates. We used Jurkat cells, an established T-cell model, showing the formation of actin aggregates along with the decrease of proteasome activity. The presence of these protein aggregates inhibits Jurkat proliferation even under conditions not influencing viability. As a conclusion, we propose that an oxidative environment leads to actin aggregates contributing to T-cell cellular functional impairment.     

Actin mRNA localizes in the absence of protein synthesis

Actin mRNA is localized in chicken embryo fibroblasts to the distal regions of leading lamellae, but not within the ruffling edges. In this investigation we have addressed the role of actin translation in this process. The translocation of actin mRNA to the cell periphery was studied by monitoring the distribution of actin mRNA in cells during spreading. Within 90 min, actin mRNA moved from a perinuclear to a peripheral distribution. Formation of lamellipodia preceded actin mRNA localization, indicating that localization is not a prerequisite for this event. Neither puromycin (which dissociates ribosomes from mRNA) nor cycloheximide (which stabilizes ribosomes on mRNA) had any effect on this movement of actin mRNA. Anchoring of actin mRNA was studied using cells with peripherally localized actin mRNA. No change in actin mRNA localization was observed for 30 min in the same inhibitors. These data indicate that the presence of the nascent polypeptide is not necessary for translocation of actin mRNA to the cell periphery, or anchoring at that site. This suggests that the mRNA contains information concerning its spatial distribution within the cytoplasm.     

A prespore gene, Dd31, expressed during culmination of Dictyostelium discoideum

During culmination of Dictyostelium fruiting bodies, prespore and prestalk cells undergo terminal differentiation to form spores and a cellular stalk. A genomic fragment was isolated by random cloning that hybridizes to a 1.4-kb mRNA present during culmination. Cell type separations at culmination showed that the mRNA is present in prespore cells and spores, but not in prestalk or stalk cells. After genomic mapping, an additional 3 kb of DNA surrounding the original 1-kb fragment was cloned. The gene was sequenced and named Dd31 after the size of the predicted protein product in kilodaltons. Accumulation of Dd31 mRNA occurs immediately prior to sporulation. Addition of 20 mM 8-Br-cAMP to cells dissociated from Mexican hat stage culminants induced sporulation and the accumulation of Dd31 mRNA, while 20 mM cAMP did not. Dd31 mRNA does not accumulate in the homeotic mutant stalky in which prespore cells are converted to stalk cells rather than spores. Characterization of Dd31 extends the known temporal dependent sequence of molecular differentiations to sporulation.     

Localization of Actin mRNA during the Establishment of Cell Polarity and Early Cell Divisions in Fucus Embryos

Localization of mRNA is a well-described mechanism to account for the asymmetric distribution of proteins in polarized somatic cells and embryos of animals. In zygotes of the brown alga Fucus, F-actin is localized at the site of polar growth and accumulates at the cell plates of the first two divisions of the embryo. We used a nonradioactive, whole-mount in situ hybridization protocol to show the pattern of actin mRNA localization. Until the first cell division, the pattern of actin mRNA localization is identical to that of total poly(A)+ RNA, that is, a symmetrical distribution in the zygote followed by an actin-dependent accumulation at the thallus pole at the time of polar axis fixation. At the end of the first division, actin mRNA specifically is redistributed from the thallus pole to the cell plates of the first two divisions in the rhizoid. This specific pattern of localization in the zygote and embryo involves the redistribution of previously synthesized actin mRNA. The initial asymmetry of actin mRNA at the thallus pole of the zygote requires polar axis fixation and microfilaments but not microtubules, cell division, or polar growth. However, redistribution of actin mRNA from the thallus pole to the first cell plate is insensitive to cytoskeletal inhibitors but is dependent on cell plate formation. The F-actin that accumulates at the rhizoid tip is not accompanied by the localization of actin mRNA. However, maintenance of an accumulation of actin protein at the cell plates of the rhizoid could be explained, at least partially, by a mechanism involving localization of actin mRNA at these sites. The pattern and requirements for actin mRNA localization in the Fucus embryo may be relevant to polarization of the embryo and asymmetric cell divisions in higher plants as well as in other tip-growing plant cells.     

Cytochemical Localization of Actin and Myosin Aggregates in Interphase Nuclei in Situ

Biochemical and ultrastructural studies on isolated nuclear compartments have previously shown actin and myosin to be constituents of interphase nuclei. In the present work, immunocytochemistry, in conjunction with confocal microscopy and ultrastructural immunogold techniques, shows that interphase nuclei of intact dorsal root ganglion neurons and of PC12 cells contain actin and myosin. Nuclear actin was observed to be distributed throughout the nucleoplasm occurring as distinct aggregates. Frequently, prominent actin aggregates were associated with the nucleolar periphery, often near nucleolar satellites. Ultrastructurally, actin was observed to be associated with linear, electrondense structures, putatively identified as chromatin fibers, extending from nucleoli. Use of three antibodies against subclasses of α-actin isoforms revealed that nuclear actin is more closely related to α-sarcomeric actin than to α-smooth muscle actin. Those aggregates associated with the nucleolus were found to be in the polymerized F-actin form, in a small fraction of neurons, as assessed by FITC-phalloidin. A myosin-like antigen was also observed to occur as intranuclear aggregates. Quantitative assays of the distribution of actin and myosin aggregates by nearest neighbour analysis indicated a distribution characterized as uniform and failed to reveal statistically significant associations between any set of aggregates, The evidence presented herein indicates that actin and myosin are constituent proteins of interphase nuclei in situ of both normal mammalian and transformed mammalian cells.     

Gene-specific expression of the actin multigene family of Dictyostelium discoideum

We have investigated the expression of 14 cloned genes of the 20-member actin multigene family of Dictyostelium discoideum using gene-specific mRNA complementary probes and an RNase protection assay. Actin gene expression was studied in vegetative cells and in cells at a number of developmental stages chosen to represent the known major shifts in actin mRNA and protein synthesis. At least 13 of these genes are expressed. A few genes are expressed very abundantly at 10% or more of total actin mRNA; however, the majority are maximally expressed at 1 to 5% of actin message. Although all of the genes are transcribed in vegetative cells, most genes appear to be independently regulated. Actin 8 appears to be transcribed at constant, high levels throughout growth and development. Actin 12 mRNA is maximally expressed in vegetative cells but the level is reduced appreciably by the earliest stage of development examined, while Actin 7 mRNA is specifically induced approximately sevenfold at this time. The rest of the genes appear to be induced 1.5 to 2-fold early in development, coincident with the increase in total actin mRNA. Since 12 of the genes code for extremely homologous proteins, it is possible that the large number of actin genes in Dictyostelium is utilized for precise regulation of the amount of actin produced at any stage of development, even though individual gene expression appears in some cases to be very stage-specific. In addition to these 13 actin genes, at least two and possibly four more genes are known to be expressed, because they are represented by complementary DNA clones, and an additional one or two expressed genes are indicated by primer extension experiments. Only one known gene, Actin 2-sub 2, is almost certainly a pseudogene. Thus the vast majority of Dictyostelium actin genes are expressed.     

A method for the morphological identification of contractile filaments in single cells

A simple negative staining procedure has been developed for the demonstration of actin filaments and myosin aggregates in single giant amoeba (Chaos carolinensis) that is applicable to other single cells. Cytoplasm is first isolated in physiological solutions in which contractility and state of association of contractile proteins can be controlled. Cytoplasm isolated in low calcium, low ATP concentration solutions contains actin associated with myosin aggregates sometimes forming light-microscopically visible fibrils. When exogenous ATP is added to these preparations, actin filaments and myosin aggregates are seen separately.     

Requirement of cell division for muscle actin expression in the primary muscle cell lineage of ascidian embryos

The role of cell division in the expression of muscle actin and its relationship to acetylcholinesterase (AChE) development was examined in cleavage-arrested embryos of the ascidian Styela. Muscle actin expression was detected by two-dimensional gel electrophoresis of radioactively labelled proteins and by in situ hybridization with a cDNA probe, whereas AChE activity was assayed by enzyme histochemistry. In the majority of cases, muscle actin expression was first detected in embryos arrested after the 16-cell stage. Some embryos showed muscle actin expression after arrest at the 8-cell stage, however, muscle actin mRNA did not accumulate in embryos arrested at earlier cleavages. The cells that expressed muscle actin in 8- to 64-cell cleavage-arrested embryos belonged to the primary muscle lineage; secondary muscle cell precursors did not express muscle actin. Zygotic muscle actin mRNA appeared to accumulate with myoplasmic pigment granules in the perinuclear region of cleavage-arrested embryos, suggesting that the myoplasm may have a role in the organization of muscle cells. In contrast to muscle actin, AChE was detected in a small proportion of embryos treated with cytochalasin as early as the 1- or 2-cell stage, and most embryos treated with cytochalasin at later cleavages expressed this enzyme in some of their cells. Most primary muscle lineage cells expressed both muscle actin mRNA and AChE, however, some cells expressed only muscle actin mRNA or AChE. The results suggest that at least three cleavages are required for muscle actin expression and that muscle actin and AChE expression can be uncoupled in cleavage-arrested embryos.     

Beta and gamma actin mRNAs are differentially located within myoblasts

Actin is of fundamental importance to all eukaryotic cells. Of the six mammalian actins, beta (beta) and gamma (gamma) cytoplasmic are the isoforms found in all nonmuscle cells and differ by only four amino acids at the amino-terminal region. Both genes are regulated temporally and spatially, though no differences in protein function have been described. Using fluorescent double in situ hybridization we describe the simultaneous intracellular localization of both beta and gamma actin mRNA. This study shows that myoblasts differentially segregate the beta and gamma actin mRNAs. The distribution of gamma actin mRNA, only to perinuclear and nearby cytoplasm, suggests a distribution based on diffusion or restriction to nearby cytoplasm. The distribution of beta actin mRNA, perinuclear and at the cell periphery, implicates a peripheral localizing signal which is unique to the beta isoform. The peripheral beta actin mRNA corresponded to cellular morphologies, extending processes, and ruffling edges that reflect cell movement. Total actin and gamma actin protein steady-state distributions were identified by specific antibodies. gamma actin protein was found in both stress fibers and at the cell plasma membrane and does not correspond to its mRNA distribution. We suggest that localized protein synthesis rather than steady-state distribution functionally differentiates between the actin isoforms.     

Trypanosoma cruzi infection affects actin mRNA regulation in heart muscle cells

We have previously described alterations in the cytoskeletal organization of heart muscle cells (HMC) infected with Trypanosoma cruzi in vitro. Our aim was to investigate whether these changes also affect the regulation of the actin mRNAs during HMC differentiation. Northern blot analysis revealed that alpha-cardiac actin mRNA levels increased during cell differentiation while beta-actin mRNA levels declined. Nonmuscle cells displayed beta-actin mRNA signal localized at the cell periphery, while alpha-cardiac actin mRNA had a perinuclear distribution in myocytes. Trypanosoma cruzi-infected cells showed 50% reduction in alpha-cardiac actin mRNA expression after 72 h of infection. In contrast, beta-actin mRNA levels increased approximately 79% after 48 h of infection. In addition, in situ beta-actin mRNA was delocalized from the periphery into the perinuclear region. These observations support the hypothesis that Trypanosoma cruzi affects actin mRNA regulation and localization through its effect on the cytoskeleton of heart muscle cells.     

The role of microfilaments in the capping of epidermal growth factor receptor in A431 cells

Capping of the EGF receptor (EGF-R) on the surface of suspended and adherent epidermoid carcinoma cells, A431, is studied. It was induced at 20 degrees C after treating cells with monoclonal antibody to the EGF receptor followed by the second antibody conjugated with FITC. Accumulation of cortical actin under the caps was detected by rhodamine-phalloidin. Destruction of the actin stress-fiber-like bundles was observed during incubation of cells with the ligands at 0 degrees C. Two processes appear to take place at 20 degrees C: redistribution of the EGF-R with cortical actin into the caps within 15-30 min and reconstruction of cytoplasmic actin bundles over 45-60 min. Dihydrocytochalasin B prevented cap formation in adherent cells, but small patches of EGF-R colocalized with actin aggregates under plasma membrane were observed. The function of different actin-containing cytoskeleton structures in the process of capping is discussed.     

Asymmetric distribution of actin mRNA and cytoskeletal pattern generation in polarized epithelial cells

We analysed the distribution of actin mRNA in intestinal epithelial cells using in situ hybridization of 35S-labelled cytoplasmic beta-actin RNA. We found that the distribution of actin mRNA generally parallels that of polymerized actin, i.e. there is an accumulation of actin mRNA in the apical end of villous epithelial cells. Furthermore, the development of this asymmetric localization of actin mRNA appears to parallel the elaboration of the cytoskeleton during cellular differentiation. We discuss the possibility that the interaction between actin and its mRNA may be important for the establishment and maintenance of cytoskeletal pattern in polarized epithelial cells.