Actin Isoforms Research Articles

Diverse functions of homologous actin isoforms are defined by their nucleotide, rather than their amino acid sequence.

β- and γ-cytoplasmic actin are nearly indistinguishable in their amino acid sequence, but are encoded by different genes that play non-redundant biological roles. The key determinants that drive their functional distinction are unknown. Here, we tested the hypothesis that β- and γ-actin functions are defined by their nucleotide, rather than their amino acid sequence, using targeted editing of the mouse genome. Although previous studies have shown that disruption of β-actin gene critically impacts cell migration and mouse embryogenesis, we demonstrate here that generation of a mouse lacking β-actin protein by editing β-actin gene to encode γ-actin protein, and vice versa, does not affect cell migration and/or organism survival. Our data suggest that the essential in vivo function of β-actin is provided by the gene sequence independent of the encoded protein isoform. We propose that this regulation constitutes a global 'silent code' mechanism that controls the functional diversity of protein isoforms.

Measurement of enzymatic and motile activities of Arabidopsis myosins by using Arabidopsis actins

There are two classes of myosin, XI and VIII, in higher plants. Myosin XI moves actin filaments at high speed and its enzyme activity is also very high. In contrast, myosin VIII moves actin filaments very slowly with very low enzyme activity. Because most of these enzymatic and motile activities were measured using animal skeletal muscle α-actin, but not plant actin, they would not accurately reflect the actual activities in plant cells. We thus measured enzymatic and motile activities of the motor domains of two Arabidopsis myosin XI isoforms (MYA2, XI-B), and one Arabidopsis myosin VIII isoform (ATM1), by using three Arabidopsis actin isoforms (ACT1, ACT2, and ACT7). The measured activities were different from those measured by using muscle actin. Moreover, Arabidopsis myosins showed different enzymatic and motile activities when using different Arabidopsis actin isoforms. Our results suggest that plant actin should be used for measuring enzymatic and motile activities of plant myosins and that different actin isoforms in plant cells might function as different tracks along which affinities and velocities of each myosin isoform are modulated.

Upregulation of the actin cytoskeleton via myocardin leads to increased expression of type 1 collagen

Liver fibrosis, a model wound healing system, is characterized by excessive deposition of extracellular matrix (ECM) in the liver. Although many fibrogenic cell types may express ECM, the hepatic stellate cell (HSC) is currently considered to be the major effector. HSCs transform into myofibroblast-like cells, also known as hepatic myofibroblasts in a process known as activation; this process is characterized in particular by de novo expression of smooth muscle alpha actin (SM α-actin) and type 1 collagen. The family of actins, which form the cell's cytoskeleton, are essential in many cellular processes. β-actin and cytoplasmic γ-actin (γ-actin) are ubiquitously expressed, whereas SM α-actin defines smooth muscle cell and myofibroblast phenotypes. Thus, SM α-actin is tightly associated with multiple functional properties. However, the regulatory mechanisms by which actin isoforms might regulate type 1 collagen remain unclear. In primary HSCs from normal and fibrotic rat liver, we demonstrate that myocardin, a canonical SRF cofactor, is upregulated in hepatic myofibroblasts and differentially regulates SM α-actin, γ-actin, and β-actins through activation of an ATTA box in the SM α-actin and a CCAAT box in γ-actin and β-actin promoters, respectively; moreover, myocardin differentially activated serum response factor (SRF) in CArG boxes of actin promoters. In addition, myocardin-stimulated Smad2 phosphorylation and RhoA expression, leading to increased expression of type 1 collagen in an actin cytoskeleton-dependent manner. Myocardin also directly enhanced SRF expression and stimulated collagen 1α1 and 1α2 promoter activities. In addition, overexpression of myocardin in vivo during carbon tetrachloride-induced liver injury led to increased HSC activation and fibrogenesis. In summary, our data suggest that myocardin plays a critical role in actin cytoskeletal dynamics during HSC activation, in turn, specifically regulating type I collagen expression in hepatic myofibroblasts.

Cytokinesis requires localized \u03b2-actin filament production by an actin isoform specific nucleator

Cytokinesis is initiated by the localized assembly of the contractile ring, a dynamic actomyosin structure that generates a membrane furrow between the segregating chromosomal masses to divide a cell into two. Here we show that the stabilization and organization of the cytokinetic furrow is specifically dependent on localized β-actin filament assembly at the site of cytokinesis. β-actin filaments are assembled directly at the furrow by an anillin-dependent pathway that enhances RhoA-dependent activation of the formin DIAPH3, an actin nucleator. DIAPH3 specifically generates homopolymeric filaments of β-actin in vitro. By employing enhancers and activators, cells can achieve acute spatio-temporal control over isoform-specific actin arrays that are required for distinct cellular functions.

Molecular characterization of three muscle alpha actin genes in mud loach (Misgurnus mizolepis; Cypriniformes)

BackgroundTeleosts represent unique features in the regulation of muscle development and growth, with a great deal of myogenic plasticity. Muscle actins are major components to compose muscle fibers, and they play essential roles in cellular mobility and other related functions. In order to understand isoform-dependent roles of muscle actins in the mud loach (Misgurnus mizolepis), this study was aimed to characterize gene structure and expression pattern of the three muscle actin isoforms (α-skeletal, α-cardiac, and α-smooth muscle actins) isolated from this benthic fish species.ResultsMud loach α-actin isoforms (ACTA1, ACTC1, and ACTA2) were fairly conserved in their primary structures and shared a high-sequence identity one another. At genomic level also, all the three isoforms exhibited the same exon-intron organization pattern characterized by eight translated exons. However, in mRNA expression patterns, these three actin isoforms were found to display an apparent isoform-dependency in tissue distribution (i.e., ACTA1 in the skeletal muscles, ACTC1 in the heart, and ACTA2 in the intestines) and developmental regulation (i.e., increased expression of ACTA1 and ACTC1 with the progress of myogenesis, and the significant elevation of ACTA2 during organ development in early larvae).ConclusionData from this study suggest that three muscle actin isoforms have undergone certain functional differentiation with regard to their roles in the development and adult musculature, in spite of high structural similarity. Genetic information on muscle actins obtained in this study could provide a useful base to extend our understanding on evolutionary diversification of the myogenic regulation in teleosts.

Role of Rho-Associated Coiled-Coil Forming Kinase Isoforms in Regulation of Stiffness-Induced Myofibroblast Differentiation in Lung Fibrosis.

Fibrosis is a major cause of progressive organ dysfunction in several chronic pulmonary diseases. Rho-associated coiled-coil forming kinase (ROCK) has been shown to be involved in myofibroblast differentiation driven by altered matrix stiffness in a fibrotic state. There are two known ROCK isoforms in humans, ROCK1 and ROCK2, but the specific role of each isoform in myofibroblast differentiation in lung fibrosis remains unknown. To study this, we developed a gelatin methacryloyl hydrogel-based culture system with different stiffness levels relevant to healthy and fibrotic lungs. We have shown that stiff matrix, but not soft matrix, can induce myofibroblast differentiation with high smooth muscle actin isoform (αSMA) expression. Furthermore, our data confirmed that the inhibition of ROCK signaling by a pharmacological inhibitor (i.e., Y27632) attenuates stiffness-induced αSMA expression and fiber assembly in myofibroblasts. To assess the role of ROCK isoforms in this process, we used short interfering RNA to knock down the expression of each isoform. Our data showed that knocking down either ROCK1 or ROCK2 did not result in a reduction in αSMA expression in myofibroblasts on stiff matrix, as opposed to soft matrix, where αSMA expression was reduced significantly. Paradoxically, on stiff matrix, the absence of one isoform (particularly ROCK2) exaggerated αSMA expression and led to thick fiber assembly. Moreover, complete loss of αSMA fiber assembly was seen only in the absence of both ROCK isoforms, suggesting that both isoforms are implicated in this process. Overall, our results indicate the differential role of ROCK isoforms in myofibroblast differentiation on soft and stiff matrices.

The effect of lysophosphatidic acid on the composition of cytoplasmic protein complexes that contain myosin-9 and tropomyosin

The present article reports immunofluorescence-based analysis of the distribution of the actin-binding protein myosin-9 in the cytoplasm of human embryonic lung fibroblasts. Electrophoresis and Western blotting were used to demonstrate that myosin-9, actin, and high molecular weight tropomyosin isoforms are incorporated into cytoplasmic protein complexes not bound to cytoskeletal structures. Cross-immunoprecipitation was used to show that these complexes were rapidly disassembled when the cells were exposed to lysophosphatidic acid (LPA). Moreover, LPA induced proteolytic degradation of myosin-9 associated with the structures of the actin cytoskeleton. The results obtained point at the participation of multimolecular cytoplasmic protein complexes that contain myosin-9 and tropomyosin in the regulation of the cellular response to stimulation with LPA.

Abstract 637: Role of Nuclear Smooth Muscle Alpha-Actin in the Differentiation of Vascular Smooth Muscle Cells

Although the function of the cytoplasmic smooth muscle (SM) α-actin in contractile units has been well characterized in vascular SMCs, whether the SM α-actin is present in the nucleus and its nuclear function are yet to be determined. Our previous study discovered the mutations in ACTA2 , which encodes SM α-actin, predispose to both thoracic aortic disease and occlusive vascular diseases (stroke and coronary artery disease). We hypothesize that nuclear SM α-actin is critical for differentiation of SMCs. The cytoplasmic and nuclear fractions of mouse SMCs were isolated and the SM α-actin was detected in both cytosol and nucleus by immunoblotting. Moreover, both cytoplasmic and nuclear SM α-actin were dramatically upregulated during the differentiation of SMCs stimulated with TGF-β. Two-dimensional gel electrophoresis, which can separate actin isoforms based on distinct isoelectric points, was used to show that the ratio of SM α-actin to β-actin was increased in nuclear fraction when compared to cytoplasmic fraction with differentiation of SMCs, driven by serum starvation and TGF-β treatment. Furthermore, differentiation was associated with a significantly higher nuclear to cytoplasmic ratio of SM α-actin, indicating SM α-actin accumulates in the nucleus during differentiation. Co-immunoprecipitation experiments identified that nuclear SM α-actin is a component of the chromatin remodeling complex, Ino80, and the immunofluorescence confirmed co-localization of SM α-actin and Ino80 in the nucleus. To investigate the transcriptional function of nuclear SM α-actin, we performed the chromatin immunoprecipitation quantitative PCR, which revealed that the SM α-actin, but not β-actin, accumulated to the promoter region of SMC differentiation markers, including Myh11 , Cnn1 , and Tagln , during the differentiation of SMC. As expected, the Acta2 mutant SMCs (pArg149Cys) disrupt the differentiation of SMCs based on decreased contractile protein levels and increased proliferation. Furthermore, specific Acta2 missense mutations disrupt the ability for SM α-actin to localize to the nucleus. Taken together, our study found the SM α-actin concentrates into the nucleus of SMCs and may play a role in chromatin remodeling required for differentiation of SMCs.

Selective measurement of \u03b1 smooth muscle actin: why \u03b2-actin can not be used as a housekeeping gene when tissue fibrosis occurs

BackgroundPrevalence of fibroproliferative diseases, including chronic kidney disease is rapidly increasing and has become a major public health problem worldwide. Fibroproliferative diseases are characterized by increased expression of α smooth muscle actin (α-SMA) that belongs to the family of the six conserved actin isoforms showing high degree homology. The aim of the present study was to develop real-time PCRs that clearly discriminate α-SMA and ß-actin from other actin isoforms.ResultsReal-time PCRs using self-designed mouse, human and rat specific α-SMA or ß-actin primer pairs resulted in the specific amplification of the artificial DNA templates corresponding to mouse, human or rat α-SMA or ß-actin, however ß-actin showed cross-reaction with the housekeeping γ-cyto-actin. We have shown that the use of improperly designed literary primer pairs significantly affects the results of PCRs measuring mRNA expression of α-SMA or ß-actin in the kidney of mice underwent UUO.ConclusionWe developed a set of carefully designed primer pairs and PCR conditions to selectively determine the expression of mouse, human or rat α-SMA and ß-actin isoforms. We demonstrated the importance of primer specificity in experiments where the results are normalized to the expression of ß-actin especially when fibrosis and thus increased expression of α-SMA is occur.

Are non-muscle actin isoforms functionally equivalent?

Actin is highly conserved and it is the most widespread protein in eukaryotic cells. One of the most important features of actin, which allows it to have many different functions, is its ability to polymerize and interact with many other proteins. Actins are the major constituent of the actin cytoskeleton, which is an important system that is involved in various aspects of cell function, including cell motility, structure, integrity, regulation of signal transduction and transcription. Six mammal actin isoforms are highly conserved and share common functions. Two of them, β and γ non-muscle actin isoforms, which differ only by four amino acids located at the N-terminus of the polypeptide chain, are required for survival and proper cell functioning. We also summarized data about actbl2, which is suggested to be a newly discovered isoactin. Here, we review the current knowledge about tissue-specific expression of the non-muscle actin isoforms and possible functional differences between them. We also discuss molecular tools, which in recent years have allowed for a better understanding of the role of these proteins in cell functioning.

Involvement of β- and γ-actin isoforms in actin cytoskeleton organization and migration abilities of bleb-forming human colon cancer cells.

Amoeboid movement is characteristic for rounded cells, which do not form strong adhesion contacts with the ECM and use blebs as migratory protrusions. It is well known that actin is the main component of mature forms of these structures, but the exact role fulfilled by non-muscle actin isoforms β- and γ- in bleb formation and migration of these cells is still not fully understood. The aim of this study was to establish the role of β- and γ-actin in migration of bleb-forming cancer cells using isoform-specific antibodies and expression of fluorescently tagged actin isoforms. We observed, after staining with monoclonal antibodies, that both actins are present in these cells in the form of a cortical ring as well as in the area of blebs. Additionally, using simultaneous expression of differentially tagged β- and γ-actin in cells, we observed that the actin isoforms are present together in a single bleb. They were involved during bleb expansion as well as retraction. Also present in the area of these protrusions formed by both isoforms were the bleb markers–ezrin and myosin II. The overexpression of β- or γ-actin led to actin cytoskeletal rearrangement followed by the growth of migration and invasion abilities of examined human colon cancer cells, LS174T line. In summary these data prove that both actin isoforms have an impact on motility of bleb-forming cancer cells. Moreover, we conclude that monoclonal antibodies directed against actin isoforms in combination with the tagged actins are good tools to study their role in important biological processes.

Divergent roles of β- and γ-actin isoforms during spread of vaccinia virus.

Actin is a major component of the cytoskeleton and is present as two isoforms in non‐muscle cells: β‐ and γ‐cytoplasmic actin. These isoforms are strikingly conserved, differing by only four N‐terminal amino acids. During spread from infected cells, vaccinia virus (VACV) particles induce localized actin nucleation that propel virus to surrounding cells and facilitate cell‐to‐cell spread of infection. Here we show that virus‐tipped actin comets are composed of β‐ and γ‐actin. We employed isoform‐specific siRNA knockdown to examine the role of the two isoforms in VACV‐induced actin comets. Despite the high level of similarity between the actin isoforms, and their colocalization, VACV‐induced actin nucleation was dependent exclusively on β‐actin. Knockdown of β‐actin led to a reduction in the release of virus from infected cells, a phenotype dependent on virus‐induced Arp2/3 complex activity. We suggest that local concentrations of actin isoforms may regulate the activity of cellular actin nucleator complexes.

Identification of protein clusters predictive of tumor response in rectal cancer patients receiving neoadjuvant chemo-radiotherapy.

Preoperative neoadjuvant chemoradiotherapy (nCRT) is the gold standard in locally advanced rectal cancer, only 10–30% of patients achieving benefits. Currently, there is a need of a reliable selection of markers for the identification of poor or non-responders prior to therapy. In this work, we compared protein profiles before therapy of patients differing in their responses to nCRT to find novel predictive markers of response to therapy. Patients were grouped into 3 groups according to their tumor regression grading (TRG) after surgery: 'TRG 1–2′, good responders, 'TRG 3′ and 'TRG 4′, poor responders. Paired surgical specimens of rectal cancer and healthy (histologically confirmed) rectal tissues from 15 patients were analysed before nCRT by two dimensional difference in gel electrophoresis followed by mass spectrometry. Thirty spots were found as differentially expressed (p < 0.05). Among them, 3 spots (spots 471, 683 and 684) showed an increased amount of protein in poor responders compared with good responders, and they were more tumor associated compared with healthy tissues. Proteins of these spots were identified as fibrinogen ß chain fragment D, actin isoforms, B9 and B5 serpins, cathepsin D isoforms and peroxiredoxin-4. In an independent validation set of 20 rectal carcinomas we validated the increased fibrinogen ß chain abundance before nCRT in poor responders by immunoblotting. In conclusion, we propose a risk-stratification tool in predicting the response to nCRT treatment in rectal cancer based on the quantity of these proteins.

Differential roles of α-, β-, and γ-actin in axon growth and collateral branch formation in motoneurons.

Axonal branching and terminal arborization are fundamental events during the establishment of synaptic connectivity. They are triggered by assembly of actin filaments along axon shafts giving rise to filopodia. The specific contribution of the three actin isoforms, Actα, Actβ, and Actγ, to filopodia stability and dynamics during this process is not well understood. Here, we report that Actα, Actβ, and Actγ isoforms are expressed in primary mouse motoneurons and their transcripts are translocated into axons. shRNA-mediated depletion of Actα reduces axonal filopodia dynamics and disturbs collateral branch formation. Knockdown of Actβ reduces dynamic movements of growth cone filopodia and impairs presynaptic differentiation. Ablation of Actβ or Actγ leads to compensatory up-regulation of the two other isoforms, which allows maintenance of total actin levels and preserves F-actin polymerization. Collectively, our data provide evidence for specific roles of different actin isoforms in spatial regulation of actin dynamics and stability in axons of developing motoneurons.

Actin isoform expression patterns in adult extracardiac and cardiac rhabdomyomas indicate a different cell of origin.

Rhabdomyomas are rare striated muscle-type tumors arising in the heart or in soft tissues. Using a monoclonal antibody specific for the cardiac isoform of α-actin (α-cardiac actin, α-CAA), differential expression patterns in striated muscle tissues were reported previously. The purpose of the present study was to determine whether the α-actin isoform specificity is maintained in rhabdomyomas according to their origin, comparing extracardiac to cardiac rhabdomyomas. We immunohistochemically investigated adult extracardiac (pharyngeal) rhabdomyomas (n=4) and cardiac rhabdomyomas (n=7) employing isoform-specific monoclonal antibodies. The extracardiac rhabdomyomas revealed only a few scattered α-CAA-positive tumor cells (antibody cAc1-20.42) while the cardiac rhabdomyomas exhibited abundant expression of α-CAA, indicating a close relatedness to cardiac muscle fibers. The α-skeletal actin (α-SKA) specific monoclonal antibody (3B3) produced the reverse results. General sarcomeric antibodies (HHF35 and Alpha Sr-1) displayed strong positivity in all rhabdomyomas studied. Alpha-smooth muscle actin (α-SMA) was negative or heterogeneously positive in extracardiac and cardiac rhabdomyomas. Our results suggest that despite similar morphology, the intrinsic differential alpha-actin isoform specificity of mature skeletal vs. cardiac muscle is maintained in extracardiac and cardiac rhabdomyomas. Thus, adult extracardiac rhabdomyomas differentiate towards mature skeletal muscle although they may exhibit centrally placed nuclei like cardiac muscle cells, while cardiac rhabdomyomas reflect true cardiac muscle differentiation. Our findings appear to indicate a different biological nature of cardiac and extracardiac rhabdomyomas, probably related to a different cell of origin. To our knowledge, this is the first report suggesting a derivation of extracardiac and cardiac rhabdomyomas from skeletal and cardiac muscle cells, respectively.

Relative importance of βcyto- and γcyto-actin in primary mouse embryonic fibroblasts.

The highly homologous β (βcyto) and γ (γcyto) cytoplasmic actins are hypothesized to carry out both redundant and unique essential functions, but studies using targeted gene knockout and siRNA-mediated transcript knockdown to examine βcyto- and γcyto-isoform--specific functions in various cell types have yielded conflicting data. Here we quantitatively characterized actin transcript and protein levels, as well as cellular phenotypes, in both gene- and transcript-targeted primary mouse embryonic fibroblasts. We found that the smooth muscle αsm-actin isoform was the dominantly expressed actin isoform in WT primary fibroblasts and was also the most dramatically up-regulated in primary βcyto- or β/γcyto-actin double-knockout fibroblasts. Gene targeting of βcyto-actin, but not γcyto-actin, led to greatly decreased cell proliferation, decreased levels of cellular ATP, and increased serum response factor signaling in primary fibroblasts, whereas immortalization induced by SV40 large T antigen supported fibroblast proliferation in the absence of βcyto-actin. Consistent with in vivo gene-targeting studies in mice, both gene- and transcript-targeting approaches demonstrate that the loss of βcyto-actin protein is more disruptive to primary fibroblast function than is the loss of γcyto-actin.

Histochemical and Immunohistochemical Study of α-SMA, Collagen, and PCNA in Epithelial Ovarian Neoplasm

Background:Alpha-smooth muscle actin (α-SMA) is an isoform of actin, positive in myofibroblasts and is an epithelial to mesenchymal transition (EMT) marker. EMT is a process by which tumor cells develop to be more hostile and able to metastasize. Progression of tumor cells is always followed by cell composition and extracellular matrix component alteration. Increased α-SMA expression and collagen alteration may predict the progressivity of ovarian neoplasms.Objective:The aim of this research was to analyse the characteristic of α-SMA and collagen in tumor cells and stroma of ovarian neoplasms. In this study, PCNA (proliferating cell nuclear antigen) expression was also investigated.Methods:Thirty samples were collected including serous, mucinous, endometrioid, and clear cell subtypes. The expression of α-SMA and PCNA were calculated in cells and stroma of ovarian tumors. Collagen was detected using Sirius Red staining and presented as area fraction.Results:The overexpressions of α-SMA in tumor cells were only detected in serous and clear cell ovarian carcinoma. The histoscore of α-SMA was higher in malignant than in benign or borderline ovarian epithelial neoplasms (105.3±129.9 vs. 17.3±17.1, P=0.011; mean±SD). Oppositely, stromal α-SMA and collagen area fractions were higher in benign than in malignant tumors (27.2±6.6 vs 20.5±8.4, P=0.028; 31.0±5.6 vs. 23.7±6.4, P=0.04). The percentages of epithelial and stromal PCNA expressions were not significantly different between benign and malignant tumors.Conclusion:Tumor cells of serous and clear cell ovarian carcinoma exhibit mesenchymal characteristic as shown by α-SMA positive expression. This expression might indicate that these subtypes were more aggressive. This research showed that collagen and α-SMA area fractions in stroma were higher in benign than in malignant neoplasms.

Actin isoforms and neoplastic transformation

The cytoplasmic actins (β and γ) play crucial roles during key cellular processes like adhesion, migration, polarization and cytokinesis. The understanding of their specific underlying mechanisms would be of major relevance not only for fundamental research but also for clinical applications, since modulations of actin isoforms are directly or indirectly correlated with severe pathologies. The major goal of the research was to elucidate the function of the actin isoforms during motile activities, adhesions and cell division and to investigate whether their expression and/or structural organization is related to pathological function. Selective depletion of β- and γ-cytoplasmic actins allowed attributing functional diversities of β- and γ-сytoplasmic actins. β-Сytoplasmic actin plays a preferential role in contractile activities, whereas γ-cytoplasmic actin mainly participates in the formation of a submembranous network necessary for cell shape flexibility and motile activity. The roles of isoforms in regulating the integrity of adherens and tight junctions respectively were demonstrated. Unique roles of β- and γ-cytoplasmic actins in normal cells were shown. Similar results were obtained in cancer cells compared with normal epithelial cells in culture and in human pathological tissue sections of mammary gland, colon, lung and cervix. Malignant cell transformation requires changes in the ability of cells to migrate. The disruption of actin cytoskeleton and intercellular adhesions is an important component of the acquisition of invasive properties in epithelial malignancies.

A change in the expression of membrane-associated proteins and cytoplasmic actin isoforms in the progression of human colon tumors

Тo identify correlations between clinical features, risk of progression and/or recurrence of human colon adenocarcinomas (CAC), and EMT-related tumor markers. Descending colon and sigmoid colon adenocarcinoma samples were examined immunohistochemically. Formalin-fixed paraffin-embedded tissue sections were incubated with antigen-specific antibodies, then secondary antibodies labeled with fluorochromes, and the fluorescence intensity of microscopy images was analyzed. The cells of a tumor compared to those of intact colon tissue showed a weak staining of E-cadherin in the cell-cell contact areas. The reduced membrane staining and nuclear localization of β-catenin were detected in moderately (G2) and poorly (G3) differentiated tumors. There were substantially decreased β-actin levels in almost all tumor samples and increased γ-actin ones, mainly in the samples belonging to stage IV disease. A correlation was found between stage, tumor differentiation grade, risk for relapse or progression of disease, and the impaired expression of different EMT markers: total or partial loss of E-cadherin expression, β-catenin reorganization in cell-cell contacts, and a change in the ratio of cytoplasmic actin isoforms in the late stages of CAC development. We believe that these molecular markers may have a prognostic potential.

Actin Is Crucial for All Kinetically Distinguishable Forms of Endocytosis at Synapses

Mechanical force is needed to mediate endocytosis. Whether actin, the most abundant force-generating molecule, is essential for endocytosis is highly controversial in mammalian cells, particularly synapses, likely due to the use of actin blockers, the efficiency and specificity of which are often unclear in the studied cell. Here we addressed this issue using a knockout approach combined with measurements of membrane capacitance and fission pore conductance, imaging of vesicular protein endocytosis, and electron microscopy. We found that two actin isoforms, β- and γ-actin, are crucial for slow, rapid, bulk, and overshoot endocytosis at large calyx-type synapses, and for slow endocytosis and bulk endocytosis at small hippocampal synapses. Polymerized actin provides mechanical force to form endocytic pits. Actin also facilitates replenishment of the readily releasable vesicle pool, likely via endocytic clearance of active zones. We conclude that polymerized actin provides mechanical force essential for all kinetically distinguishable forms of endocytosis at synapses.