Actin Cytoskeleton Research Articles

Targeting cholangiocarcinoma cells by cold piezoelectric plasmas: in vitro efficacy and cellular mechanisms

Cold piezoelectric plasma (CPP) is a novel approach in cancer therapy, enabling the development of portable treatment devices capable of triggering cancer cell death. While its effectiveness remains underexplored, this research focuses on its application against cholangiocarcinoma (CCA), an aggressive cancer of the biliary tract. A CPP device is utilized to generate either a corona discharge (Pz-CD) or a dielectric barrier discharge (Pz-DBD) for in vitro experiments. Notably, Pz-CD can deliver more power than Pz-DBD, although both sources produce significant levels of reactive species in plasma and liquid phases. This work shows that CPP causes a gradient increase in medium temperature from the center towards the edges of the culture well, especially for longer treatment times. Although Pz-CD heats more significantly, it cools quickly after plasma extinction. When applied to human CCA cells, CPP shows immediate and long-term effects, more localized for Pz-CD, while more uniform for Pz-DBD. Immediate effects result also in actin cytoskeleton remodeling without alteration of the cell membrane permeability. Long-term effects of CPP, although the antioxidant system is engaged, include activation of the DNA damage response pathway leading to cell death. In conclusion, CPP should be recognized as a promising antitumor therapy.

An integrated picture of the structural pathways controlling the heart performance

The regulation of heart function is attributed to a dual filament mechanism: i) the Ca2+-dependent structural changes in the regulatory proteins of the thin, actin-containing filament making actin available for myosin motor attachment, and ii) the release of motors from their folded (OFF) state on the surface of the thick filament allowing them to attach and pull the actin filament. Thick filament mechanosensing is thought to control the number of motors switching ON in relation to the systolic performance, but its molecular basis is still controversial. Here, we use high spatial resolution X-ray diffraction data from electrically paced rat trabeculae and papillary muscles to provide a molecular explanation of the modulation of heart performance that calls for a revision of the mechanosensing hypothesis. We find that upon stimulation, titin-mediated structural changes in the thick filament switch motors ON throughout the filament within ~½ the maximum systolic force. These structural changes also drive Myosin Binding Protein-C (MyBP-C) to promote first motor attachments to actin from the central 1/3 of the half-thick filament. Progression of attachments toward the periphery of half-thick filament with increase in systolic force is carried on by near-neighbor cooperative thin filament activation by attached motors. The identification of the roles of MyBP-C, titin, thin and thick filaments in heart regulation enables their targeting for potential therapeutic interventions.

The kinetochore protein KNL-1 regulates the actin cytoskeleton to control dendrite branching.

The function of the nervous system is intimately tied to its complex and highly interconnected architecture. Precise control of dendritic branching in individual neurons is central to building the complex structure of the nervous system. Here, we show that the kinetochore protein KNL-1 and its associated KMN (Knl1/Mis12/Ndc80 complex) network partners, typically known for their role in chromosome-microtubule coupling during mitosis, control dendrite branching in the Caenorhabditis elegans mechanosensory PVD neuron. KNL-1 restrains excess dendritic branching and promotes contact-dependent repulsion events, ensuring robust sensory behavior and preventing premature neurodegeneration. Unexpectedly, KNL-1 loss resulted in significant alterations of the actin cytoskeleton alongside changes in microtubule dynamics within dendrites. We show that KNL-1 modulates F-actin dynamics to generate proper dendrite architecture and that its N-terminus can initiate F-actin assembly. These findings reveal that the postmitotic neuronal KMN network acts to shape the developing nervous system by regulating the actin cytoskeleton and provide new insight into the mechanisms controlling dendrite architecture.

Assessment of molecular modulation by multifrequency electromagnetic pulses to preferably eradicate tumorigenic cells

Physics methods of cancer therapy are extensively used in clinical practice, but they are invasive and often confront undesired side effects. A fully new equipment that allows sustained emission of intense and time-controlled non-ionizing multifrequency electromagnetic pulse (MEMP), has been applied to eukaryotic cells in culture. The equipment discriminates the overall electronegative charge of the cell cultures, and its subsequent proportional emission may thereby become higher and lethal to cancer cells of generally high metabolic activity. In contrast, low tumorigenic cells would be much less affected. We tested the specificity and efficacy of the equipment against a collection of (i) highly tumorigenic cells of human (glioblastoma, cervical carcinoma, and skin) and mouse (colon adenocarcinoma) origin; (ii) cell lines of much lower tumorigenicity (non-human primate kidney and mouse fibroblasts), and (iii) primary porcine macrophages lacking tumorigenicity. Time and intensity control of the MEMP allowed progressive decay of viability fairly correlating to cell tumorigenicity, which was provoked by a proportional alteration of the cytoplasmic membrane permeability, cell cycle arrest at G2, and general collapse of the actin cytoskeleton to the perinuclear region. Correspondingly, these effects drastically inhibited the proliferative capacity of the most tumorigenic cells in clonogenic assays. Moreover, MEMP suppressed in a dose-dependent manner the tumorigenicity of retrovirally transduced luciferase expressing colon adenocarcinoma cells in xenografted immune-competent mice, as determined by tumor growth in a bioluminescence imaging system. Our results support MEMP as an anti-cancer non-invasive physical treatment of substantial specificity for tumorigenic cells with promising therapeutic potential in oncology.

The open to closed D-loop conformational switch determines length in filopodia-like actin bundles

Filopodia, microspikes and cytonemes are implicated in sensing the environment and in dissemination of morphogens, organelles and pathogens across tissues. Their major structural component is parallel bundles of actin filaments that assemble from the cell membrane. Whilst the length of filopodia is central to their function, it is not known how their lengths are determined by actin bundle dynamics. Here, we identified a set of monoclonal antibodies that lengthen filopodia-like structures formed in a cell-free reconstitution system, and used them to uncover a key molecular switch governing length regulation. Using immunolabelling, enzyme-linked immunosorbent assays, immunoprecipitation and immunoblock experiments, we identified four antibodies that lengthen actin bundles by selectively binding the open DNase 1-binding loop (D-loop) of actin filaments. The antibodies inhibit actin disassembly and their effects can be alleviated by providing additional actin or cofilin. This work indicates that maintaining an open state of the actin filament D-loop is a mechanism of generating long filopodia-like actin bundles.

CHUP1 restricts chloroplast movement and effector-triggered immunity in epidermal cells.

Chloroplast Unusual Positioning 1 (CHUP1) plays an important role in the chloroplast avoidance and accumulation responses in mesophyll cells. In epidermal cells, prior research showed silencing CHUP1-induced chloroplast stromules and amplified effector-triggered immunity (ETI); however, the underlying mechanisms remain largely unknown. CHUP1 has a dual function in anchoring chloroplasts and recruiting chloroplast-associated actin (cp-actin) filaments for blue light-induced movement. To determine which function is critical for ETI, we developed an approach to quantify chloroplast anchoring and movement in epidermal cells. Our data show that silencing NbCHUP1 in Nicotiana benthamiana plants increased epidermal chloroplast de-anchoring and basal movement but did not fully disrupt blue light-induced chloroplast movement. Silencing NbCHUP1 auto-activated epidermal chloroplast defense (ECD) responses including stromule formation, perinuclear chloroplast clustering, the epidermal chloroplast response (ECR), and the chloroplast reactive oxygen species (ROS), hydrogen peroxide (H2O2). These findings show chloroplast anchoring restricts a multifaceted ECD response. Our results also show that the accumulated chloroplastic H2O2 in NbCHUP1-silenced plants was not required for the increased basal epidermal chloroplast movement but was essential for increased stromules and enhanced ETI. This finding indicates that chloroplast de-anchoring and H2O2 play separate but essential roles during ETI.

Role of Rab35 in modulating lipid metabolism and viral entry during pseudorabies virus infection

Pseudorabies virus (PRV), the causative agent of Aujeszky's disease in swine, is a significant pathogen in veterinary medicine. Rab35 is a key regulatory GTPase involved in diverse cellular functions, including endocytic recycling, cytokinesis, and the regulation of the actin cytoskeleton. Although Rab35's roles in these processes are well-documented, its contribution to PRV replication dynamics had not been previously elucidated. Our study demonstrated that PRV infection led to an increase in Rab35 expression at both the mRNA and protein levels in both in vitro cell culture and in vivo models. Elevated Rab35 expression was associated with an acceleration of PRV replication, whereas knocking down Rab35 expression significantly impeded viral proliferation. Further investigation revealed that while Rab35 depletion did not impact the initial attachment of PRV to host cells, it critically suppressed subsequent viral entry and effectively obstructed the transcription of early PRV genes. The downregulation of Rab35 disrupted the expression of enzymes critical to lipid synthesis, which are upregulated during PRV infection. Moreover, Rab35 knockdown disrupted lipid dynamics necessary for the virus to integrate into clathrin-coated pits, a pivotal mechanism for PRV cellular entry. These findings collectively suggest that Rab35 plays a facilitatory role in PRV infection by modulating lipid metabolism and the viral entry process, thereby offering new insights into the complex intracellular mechanisms underlying PRV replication.

Remodeling of intracellular architecture during SARS-CoV-2 infection of human endothelium

Clinical data indicate that COVID-19 causes cardiovascular complications, regardless of the severity of the disease. In this work, we have shown that SARS-CoV-2 infection causes vascular dysfunction due to the modification of endothelial cell elasticity. We used human pulmonary endothelial cells (HPAECs) expressing the ACE2 receptor as a model of the endothelium. This system mimics in vivo conditions, as it allows virus entry but not replication. As a reference, we used A549 epithelial cells, a well-described model that supports productive replication of SARS-CoV-2. We show that the infection of HPAECs results in loss of cell elasticity, which correlates with increased polymerization of actin filaments and induction of the inflammatory response. On the contrary, A549 epithelial cells supporting viral replication showed increased elasticity. We also showed that the endothelial cell elasticity were impaired after infection with Alpha, Beta and Delta variants. Consequently, we believe that nonproductive SARS-CoV-2 infection associated with loss of the endothelium elasticity may be clinically relevant and result in dysfunction and damage to this tissue.

The Ras-related nuclear GTPase RAN1 ensures pollen size and tube growth via maintaining actin cytoskeleton.

Controlling organ size in plants is a complex biological process influenced by various factors, including gene expression, genome ploidy, and environmental conditions. Despite its importance for plant growth and development, the mechanisms underlying organ size regulation remain unknown. Here, we investigated the role of RAN1, a member of the Ras-related nuclear GTPases family, in regulating pollen size. A RAN1 knockdown mutant (ran1-1) exhibited a significant reduction in pollen size, accompanied by impaired germination and reduced pollen tube growth. RAN1 mutation caused disruptions in actin filament organization such as aberrant structure of actin collar due to the dysregulation of actin-binding proteins expression. Furthermore, we identified the transcription activator SHB1 (SHORT HYPOCOTYL UNDER BLUE1), whose mutation showed similar but milder phenotypes in pollens compared to ran1-1. Genetic evidence suggested SHB1 acts downstream of RAN1. Transient expression assays in leaves showed that SHB1 was largely retained in the cytoplasm of the ran1-1 mutant, potentially affecting the expression of actin-binding proteins. These findings highlight the pivotal role of RAN1 in modulating pollen size and development, providing valuable insights into cell size regulation.

Transcriptome analysis reveals that PRV XJ delgE/gI/TK protects against intestinal damage in nose-dropping-infected mice by regulating ECM-ITGA/ITGB-P-FAK.

Pseudorabies virus (PRV) is an ideal model for mechanistic investigations into α-herpesvirus. The neurotropism and latent infection of PRV have been extensively studied. Apart from neurological symptoms, diarrhea caused by PRV infection is also an essential cause of mortality in newborn and weaned piglets. However, little research has been done on PRV invasion of the gut. To fill this gap, a nasal drip PRV-infection mouse model was developed, consisting of three groups: the challenged group (Group A), the immunization-challenged group (Group B), and a mock group (Group C). The results showed that immunization with PRV XJ delgE/gI/TK successfully prevented intestinal damage caused by PRV drop-nose infection. Subsequently, intestines were collected for transcriptional analysis. Differentially expressed genes analysis revealed that PRV XJ delgE/gI/TK was effective in reducing the organismal intestinal transcriptional activity caused by PRV. The Group A vs Group C and Group A vs Group B had similar Kyoto Encyclopedia of Genes and Genomes (KEGG)-enriched signaling pathways and the differentially expressed genes were primarily enriched in pathways, such as cell adhesion molecules, focal adhesion kinase, and actin cytoskeleton regulation. Notably, transcriptome analysis indicated that genes associated with the focal adhesion kinase (FAK) signaling pathway (ECM-ITGA/ITGB-p-FAK) were significantly more highly expressed in Group A than in Group B and Group C. The results of quantitative real-time PCR (RT-qPCR) and western blotting were consistent with KEGG analysis. Therefore, we hypothesized that PRV promotes self-infection through activation of the ECM-ITGA/ITGB-p-FAK signaling pathway and that PRV XJ delgE/gI/TK immunization could attenuate the intestinal damage caused by PRV by inhibiting the activation of this pathway.IMPORTANCEPseudorabies virus (PRV) poses a significant threat to the swine industry and public health due to its ability to infect multiple species, including humans, leading to substantial economic losses and potential health risks. This study addresses a critical gap in understanding the impact of PRV infection on the gut, which has been less explored compared to its neurological effects. By developing a drip-nose PRV-infection mouse model, the research indicated that PRV might promote self-infection through activation of the ECM-ITGA/ITGB-p-FAK signaling pathway, and PRV XJ delgE/gI/TK immunization effectively prevents intestinal damage by significantly reducing the expression of genes in the ECM-ITGA/ITGB-p-FAK signaling pathway. The research has important implications for the swine industry and public health by contributing to the development of better vaccines and treatments, ultimately helping to control PRV and prevent its cross-species transmission.

Reduced cofilin activity as a mechanism contributing to endothelial cell stiffening in type 2 diabetes.

An emerging instigator of endothelial dysfunction in type 2 diabetes (T2D) is stiffening of the cell. Previous reports suggest that polymerization of filamentous actin (F-actin) is a potential mediator of endothelial stiffening. Actin polymerization is limited by active cofilin, an F-actin-severing protein that can be oxidized, leading to its inactivation and loss of severing capability. Yet, whether these mechanisms are implicated in endothelial stiffening in T2D remains unknown. Herein, we report that endothelial cells exposed to plasma from male and female subjects with T2D, and the aortic endothelium of diabetic male mice (db/db), exhibit evidence of increased oxidative stress, F-actin, and stiffness. Furthermore, we show reactive oxygen species, including H2O2, are increased in the endothelium of mesenteric arteries isolated from db/db male mice, and that exposure of endothelial cells to H2O2 induces F-actin formation. We also demonstrate, in vitro, that cofilin-1 can be oxidized by H2O2, leading to reduced F-actin severing activity. Finally, we provide evidence that genetic silencing or pharmacological inhibition of LIM kinase 1, an enzyme that phosphorylates and thus inactivates cofilin, reduces F-actin and cell stiffness. In aggregate, this work supports inactivation of cofilin as a potential novel mechanism underlying endothelial stiffening in T2D.

Exploring the molecular basis of efficient feed utilization in low residual feed intake slow-growing ducks based on breast muscle transcriptome

Residual feed intake (RFI) has recently gained attention as a key indicator of feed efficiency in poultry. In this study, 800 slow-growing ducks with similar initial body weights were reared in an experimental facility until they were culled at 42 d of age. Thirty high RFI (HRFI) and 30 low RFI (LRFI) birds were selected to evaluate their growth performance, carcass characteristics, and muscle development. Transcriptome and weighted gene co-expression correlation network analyses of pectoral muscles were conducted on six LRFI and six HRFI ducks. The results revealed that selecting for LRFI significantly reduced feed consumption (P < 0.05) and improved feed efficiency without affecting the growth performance, slaughter rate, or meat quality of ducks (P > 0.05). Moreover, compared with HRFI ducks, LRFI ducks had a lower pectoral muscle fat content (P < 0.05), larger muscle fiber diameter and area (P < 0.05), and lower muscle fiber density (P < 0.05). There were significant differences in gene expression between LRFI and HRFI ducks, with 102 upregulated and 258 downregulated genes, which were enriched in the PPAR signaling pathway, adipocytokine signaling pathway, actin cytoskeleton regulation, ECM-receptor interaction, and focal adhesion. The expression of genes associated with fat and energy metabolism, including ACSL6, PCK1, APOC3, HMGCS2, PRKAG3, and G6PC1, was downregulated in LRFI ducks, and weighted gene co-expression correlation network analysis identified PRKAG3 as a hub gene. Our findings indicate that reduced mitochondrial energy metabolism may contribute to the RFI of slow-growing ducks, with PRKAG3 playing a pivotal role in this biological process. These findings provide novel insights into the molecular changes underlying RFI variation in slow-growing ducks.

RNAi library screening reveals Gβ1, Casein Kinase 2 and ICAP-1 as novel regulators of LFA-1-mediated T cell polarity and migration.

The αLβ2 integrin LFA-1 plays a key role in T-cell adhesion to the endothelial vasculature and migration into both secondary lymphoid organs and peripheral tissues via interactions with its target protein ICAM-1, but the pathways that regulate LFA-1-mediated T-cell polarity and migration are not fully understood. In this study we screened two RNAi libraries targeting G protein-coupled receptors (GPCR)/GPCR-associated proteins and kinases in a HuT 78 T cell line model of LFA-1-stimulated T-cell migration. Based on staining of the actin cytoskeleton, multiple parameters to measure cell morphology were used to assess the contribution of 1109 genes to LFA-1-mediated T-cell polarity and migration. These RNAi screens identified a number of both novel and previously identified genes that either increased or decreased the polarity and migratory capacity of these cells. Following multiparametric analysis, hierarchical clustering and pathway analysis, three of these genes were characterized in further detail using primary human T cells, revealing novel roles for the heterotrimeric G protein subunit Gβ1 and Casein Kinase 2 in LFA-1-mediated T-cell polarity and migration in vitro. Our studies also highlighted a new role for ICAP-1, an adaptor protein previously described to be associated with β1 integrins, in β2 integrin LFA-1-directed migration in T cells. Knockdown of ICAP-1 expression in primary T cells revealed a role in cell polarity, cell velocity and transmigration towards SDF-1 for this adaptor protein. This study therefore uncovers new roles for GPCR/GPCR-associated proteins and kinases in T-cell migration and provides potential novel targets for modulation of the T-cell immune response.

Actin Polymerization Status Regulates Tenocyte Homeostasis Through Myocardin-Related Transcription Factor-A.

The actin cytoskeleton is a potent regulator of tenocyte homeostasis. However, the mechanisms by which actin regulates tendon homeostasis are not entirely known. This study examined the regulation of tenocyte molecule expression by actin polymerization via the globular (G-) actin-binding transcription factor, myocardin-related transcription factor-a (MRTF). We determined that decreasing the proportion of G-actin in tenocytes by treatment with TGFβ1 increases nuclear MRTF. These alterations in actin polymerization and MRTF localization coincided with favorable alterations to tenocyte gene expression. In contrast, latrunculin A increases the proportion of G-actin in tenocytes and reduces nuclear MRTF, causing cells to acquire a tendinosis-like phenotype. To parse out the effects of F-actin depolymerization from regulation by MRTF, we treated tenocytes with cytochalasin D. Exposure of cells to cytochalasin D increases the proportion of G-actin in tenocytes. However, as compared to latrunculin A, cytochalasin D has a differential effect on MRTF localization by increasing nuclear MRTF. This led to an opposing effect on the regulation of a subset of genes. The differential regulation of genes by latrunculin A and cytochalasin D suggests that actin signals through MRTF to regulate a specific subset of genes. By targeting the deactivation of MRTF through the inhibitor CCG1423, we verify that MRTF regulates Type I Collagen, Tenascin C, Scleraxis, and α-smooth muscle actin in tenocytes. Actin polymerization status is a potent regulator of tenocyte homeostasis through the modulation of several downstream pathways, including MRTF. Understanding the regulation of tenocyte homeostasis by actin may lead to new therapeutic interventions against tendinopathies, such as tendinosis.

New insight into the functional role of myorod

In this paper, we present a refined version of the previously proposed suspension contractile model based on catch muscle proteins of the Gray's mussel (Crenomytilus grayanus). The objective of this model was to test the current hypotheses about the catch state, a unique phenomenon observed in the adductor muscle of bivalve molluscs. This state allows the muscle to maintain the force developed by contraction for a long time with minimum energy expenditure. Our study has resolved the issue of constructing a catch muscle model capable of controlled contraction and relaxation in an ATP-resistant manner. As a result, we have gained insight into the functional role of myorod, a unique protein of the catch muscle, and have tested the modified myorod-links hypothesis of the catch state. Myorod was shown capable of forming strong and functional cross-links between actin and synthetic thick filaments. This finding removes the last shortcoming of the myorod-links hypothesis of the catch state. There is now no doubt that myorod plays the main role of the catch-link we have been seeking all this time.

ATF3 regulates CDC42 transcription and influences cytoskeleton remodeling, thus inhibiting the proliferation, migration and invasion of malignant skin melanoma cells.

Cutaneous malignant melanoma (CMM) is one of the most aggressive and lethal types of skin cancer. Cytoskeletal remodeling is a key factor in the progression of CMM. Previous research has shown that activating transcription factor 3 (ATF3) inhibits metastasis in bladder cancer by regulating actin cytoskeleton remodeling through gelsolin. However, whether ATF3 plays a similar role in cytoskeletal remodeling in CMM cells remains unknown. Various gene and protein expression analyses were performed using techniques such as reverse transcription quantitative PCR, western blot, immunofluorescent staining, and immunohistochemical staining. CMM viability, migration, and invasion were examined through cell counting kit-8 and transwell assays. The interactions between cell division cycle 42 (CDC42) and ATF3 were investigated using chromatin immunoprecipitation and dual-luciferase reporter assays. CDC42 was upregulated in CMM tissues and cells. Cytoskeletal remodeling of CMM cells, as well as CMM cell proliferation, migration, and invasion, were inhibited by CDC42 or ATF3. ATF3 targeted the CDC42 promoter region to regulate its transcriptional activity. ATF3 suppresses cytoskeletal remodeling in CMM cells, thereby inhibiting CMM progression and metastasis through CDC42. This research may provide a foundation for using ATF3 as a therapeutic target for CMM.

Mechanical Extrusion of the Plasma Membrane to Generate Ectosome-Mimetic Nanovesicles for Lung Targeting.

Extracellular vehicles (EVs) are naturally occurring nanocarriers that participate in the transportation of biologics between cells. Despite their potential in drug delivery, their optimal use in therapy remains a challenge, which comes from the difficulty in preparation scale-up and cargo loading efficiency. As a membrane-enclosed nanoscale system, EVs are reluctant to be transfected with cargos and purified by conventional methods. In the present study, we proposed an EV-mimetic nanovesicle system to overcome the challenges. Using the easy-culture mammalian cells as raw materials, we isolated the plasma membrane sheets and vesiculated them into membrane-enclosed nanovesicles as an EV mimic by the mechanical extrusion through porous membranes. In order to controllably load the cargos in the lumen of vesicles, the endogenous actin filament was chosen as an anchor to capture the cargos (fused with an anti-actin nanobody) in the inner leaflet of plasma membrane sheets and vesiculated inside after extrusion. By loading the bioluminescent tracer nano-luciferase (Nluc) and tracking biodistribution in mice, we unclosed the lung-tropic nature of these nanovesicles. Furthermore, we demonstrated that nanovesicles can be genetically engineered with chimeric antigen receptors to achieve the active targeting of lung cancer cells. In conclusion, our study indicated that plasma membrane extrusion might be an applicable approach to generate EV mimics for drug delivery, especially to the lung tissue.

Research progress in the small G-protein Rac1

The small G-protein Rac1 is the main regulatory factor of the actin cytoskeleton. Rac1 cycles between the inactive GDP-bound form and the active GTP-bound form. Rac1 not only promotes viral replication and infection, but also regulates the actin cytoskeleton rearrangement, adhesion, and invasion of glioma cells. In addition, Rac1 is implicated in human diseases such as tumors and epilepsy. This article reviews the latest research on the small G-protein Rac1 in virology, cell biology, and human pathology. It is found that the existence of Rac1 is closely related to the replication and infection of viruses, that is, inhibiting the existence of Rac1 can effectively reduce the replication and transportation of viruses, providing new ideas for the development of various therapeutic drugs targeting Rac1.

Study of Cytotoxicity of Spiro-Fused [3-Azabicyclo[3.1.0]hexane]oxindoles and Cyclopropa[a]pyrrolizidine-oxindoles Against Tumor Cell Lines

Background: A series of spiro-fused heterocyclic compounds containing cyclopropa[a]pyrrolizidine-2,3′-oxindole and 3-spiro[3-azabicyclo[3.1.0]-hexane]oxindole frameworks were synthesized and studied for their in vitro antiproliferative activity against human erythroleukemia (K562), cervical carcinoma (HeLa), acute T cell leukemia (Jurkat), melanoma (Sk-mel-2) and breast cancer (MCF-7) as well as mouse colon carcinoma (CT26) cell lines. Methods: Cell proliferation was evaluated in vitro by MTS assay. Confocal microscopy was used to study actin cytoskeleton structure and cell motility. Cell cycle analysis was evaluated by flow cytometry. Results: It was found that compounds 4, 8, 18 and 24 showed antiproliferative activity against the Jurkat, K-562, HeLa and Sk-mel-2 cell lines with IC50 ranging from 2 to 10 μM (72 h). Evaluation of the impact on cell cycle progression showed that the tested compounds achieved significant cell-cycle perturbation with a higher accumulation of cells in the SubG1 and G0/G1 phases of the cell cycle, in comparison to the negative control. I Incubation with tested compounds led to the disappearance of stress fibers (granular actin was distributed diffusely in the cytoplasm in up to 38% of treated HeLa cells) and changes in the number of filopodia-like deformations (reduced from 93% in control cells to 64% after treatment). The impact on the Sk-mel-2 cell actin cytoskeleton structure was even greater: granular actin was distributed diffusely in the cytoplasm in up to 90% of treated cells while the number of filopodia-like deformations was reduced by up to 23%. A scratch test performed on the human melanoma cell line showed that these cells did not fill the scratched strip and lose their ability to move under treatment. Conclusions: The obtained results support the antitumor effect of the tested spiro-compounds and encourage the extension of this study in order to improve their anticancer activity as well as reduce their toxicological risks.

SPIRRIG is required for BRICK1 stability and salt stress induced root hair developmental plasticity in Arabidopsis

Developmental plasticity is critical for plants to adapt to constantly changing environments. Plant root hairs display dramatic plasticity under different environments and therefore play crucial roles in defense against environmental stressors. Here, we report the isolation of an Arabidopsis mutant, salinityover-sensitivemutant 1–1 (som1-1), also exhibiting root hair developmental defects. Map-based cloning and allelic analyses confirmed that som1-1 is a new mutant allele of SPIRRIG (SPI), which encodes a Beige and Chediak Higashi (BEACH) domain-containing protein. SPI has been reported to facilitate actin dependent root hair development by temporally and spatially regulating the expression of BRICK1 (BRK1), a subunit of the SCAR/WAVE actin nucleating promoting complex. Our living cell imaging examinations revealed that salt stress induces an altered actin organization in root hair that mimics those in the spi mutant, implying SPI may respond to salt stress induced root hair plasticity by modulating actin cytoskeleton organization. Furthermore, we found BRK1 is also involved in root hair developmental change under salt stress, and overexpression of BRK1 resulted in root hairs over-sensitive to salt stress as those in spi mutant. Moreover, based on biochemical analyses, we found BRK1 is unstable and SPI mediates BRK1 stability. Functional loss of SPI results in the accumulation of steady-state of BRK1.