Role Of Actin Cytoskeleton Research Articles

Proteomic Analysis of Prehypertensive and Hypertensive Patients: A Novel Role of Actin Cytoskeleton in Disease Progression

Background: Hypertension is a pervasive and widespread health condition that poses a significant risk factor for cardiovascular disease, which includes conditions such as heart attack, stroke, and heart failure. Despite its widespread occurrence, the exact cause of hypertension remains unknown, and the mechanisms underlying the progression from prehypertension to hypertension require further investigation. Methods: To uncover potential biomarkers related to disease development, proteomic profiling using SOMAscan proteomic platform was conducted on Qatari individuals with prehypertension and hypertension. In this study, proteomic data collected from the Qatar Biobank were analyzed to compare participants with prehypertension, hypertension, and normal blood pressure. Statistical analysis was performed to identify altered protein expression between the study groups and to elucidate the biological pathways contributing to this disease. Results: The results revealed a cluster of proteins, including the SRC family, CAMK2B and CAMK2D, TEC, GSK3, VAV, and RAC, that were markedly upregulated in patients with hypertension compared to those with prehypertension (fold change ≥ 1.6 or ≤ -1.6, area under the curve ≥ 0.8, and q-value < 0.05). Pathway analysis showed that the majority of these proteins play a role in actin cytoskeleton remodeling, a crucial pathological event involved in hypertension progression. Conclusion: Actin cytoskeleton reorganization affects various biological processes that contribute to the maintenance of blood pressure, including vascular tone, endothelial function, cellular signaling, inflammation, fibrosis, and mechanosensing. Therefore, the findings of this study suggest a potential novel role of actin cytoskeleton-related proteins in the progression from prehypertension to hypertension. The present study sheds light on the underlying pathological mechanisms involved in hypertension and could pave the way for new diagnostic and therapeutic approaches for the treatment of this disease. This study was made possible through the support of Qatar University. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

Primary cilia and actin regulatory pathways in renal ciliopathies.

Ciliopathies are a group of rare genetic disorders caused by defects to the structure or function of the primary cilium. They often affect multiple organs, leading to brain malformations, congenital heart defects, and anomalies of the retina or skeletal system. Kidney abnormalities are among the most frequent ciliopathic phenotypes manifesting as smaller, dysplastic, and cystic kidneys that are often accompanied by renal fibrosis. Many renal ciliopathies cause chronic kidney disease and often progress to end-stage renal disease, necessitating replacing therapies. There are more than 35 known ciliopathies; each is a rare hereditary condition, yet collectively they account for a significant proportion of chronic kidney disease worldwide. The primary cilium is a tiny microtubule-based organelle at the apex of almost all vertebrate cells. It serves as a "cellular antenna" surveying environment outside the cell and transducing this information inside the cell to trigger multiple signaling responses crucial for tissue morphogenesis and homeostasis. Hundreds of proteins and unique cellular mechanisms are involved in cilia formation. Recent evidence suggests that actin remodeling and regulation at the base of the primary cilium strongly impacts ciliogenesis. In this review, we provide an overview of the structure and function of the primary cilium, focusing on the role of actin cytoskeleton and its regulators in ciliogenesis. We then describe the key clinical, genetic, and molecular aspects of renal ciliopathies. We highlight what is known about actin regulation in the pathogenesis of these diseases with the aim to consider these recent molecular findings as potential therapeutic targets for renal ciliopathies.

Rai14 is a novel interactor of Invariant chain that regulates macropinocytosis.

Invariant chain (Ii, CD74) is a type II transmembrane glycoprotein that acts as a chaperone and facilitates the folding and transport of MHC II chains. By assisting the assembly and subcellular targeting of MHC II complexes, Ii has a wide impact on the functions of antigen-presenting cells such as antigen processing, endocytic maturation, signal transduction, cell migration, and macropinocytosis. Ii is a multifunctional molecule that can alter endocytic traffic and has several interacting molecules. To understand more about Ii's function and to identify further Ii interactors, a yeast two-hybrid screening was performed. Retinoic Acid-Induced 14 (Rai14) was detected as a putative interaction partner, and the interaction was confirmed by co-immunoprecipitation. Rai14 is a poorly characterized protein, which is believed to have a role in actin cytoskeleton and membrane remodeling. In line with this, we found that Rai14 localizes to membrane ruffles, where it forms macropinosomes. Depletion of Rai14 in antigen-presenting cells delays MHC II internalization, affecting macropinocytic activity. Intriguingly, we demonstrated that, similar to Ii, Rai14 is a positive regulator of macropinocytosis and a negative regulator of cell migration, two antagonistic processes in antigen-presenting cells. This antagonism is known to depend on the interaction between myosin II and Ii. Here, we show that Rai14 also binds to myosin II, suggesting that Ii, myosin II, and Rai14 work together to coordinate macropinocytosis and cell motility.

Role of actin cytoskeleton in cargo delivery mediated by vertically aligned silicon nanotubes

Nanofabrication technologies have been recently applied to the development of engineered nano–bio interfaces for manipulating complex cellular processes. In particular, vertically configurated nanostructures such as nanoneedles (NNs) have been adopted for a variety of biological applications such as mechanotransduction, biosensing, and intracellular delivery. Despite their success in delivering a diverse range of biomolecules into cells, the mechanisms for NN-mediated cargo transport remain to be elucidated. Recent studies have suggested that cytoskeletal elements are involved in generating a tight and functional cell–NN interface that can influence cargo delivery. In this study, by inhibiting actin dynamics using two drugs—cytochalasin D (Cyto D) and jasplakinolide (Jas), we demonstrate that the actin cytoskeleton plays an important role in mRNA delivery mediated by silicon nanotubes (SiNTs). Specifically, actin inhibition 12 h before SiNT-cellular interfacing (pre-interface treatment) significantly dampens mRNA delivery (with efficiencies dropping to 17.2% for Cyto D and 33.1% for Jas) into mouse fibroblast GPE86 cells, compared to that of untreated controls (86.9%). However, actin inhibition initiated 2 h after the establishment of GPE86 cell–SiNT interface (post-interface treatment), has negligible impact on mRNA transfection, maintaining > 80% efficiency for both Cyto D and Jas treatment groups. The results contribute to understanding potential mechanisms involved in NN-mediated intracellular delivery, providing insights into strategic design of cell–nano interfacing under temporal control for improved effectiveness.

Lymphocyte Cytosolic Protein 1 I232F Mutation Impairs Granulocytic Proliferation with a G2/M Block in Severe Neutropenia

▪Introduction: As critical effectors of innate immune response, neutrophils migrate from the vasculature into inflamed tissue, where they engage in phagocytosis and clearance of pathogens and apoptotic cells. Migration, phagocytosis, and granule release require multiple well-coordinated events involving remodeling of the actin cytoskeleton. While mutations of some regulators of actin polymerization, such as Wiskott-Aldrich Syndrome gene (WAS) result in Severe Congenital Neutropenia (SCN), the role of actin cytoskeleton in regulating neutrophil ontogeny and functions remain poorly understood. Lymphocyte Cytosolic Protein 1 (LCP1) is an actin bundling protein encoded by LCP1 gene. A 7-year-old girl presented at age of 2 years with chronic severe neutropenia and frequent infections. Next generation sequencing did not reveal a variant in genes known to cause neutropenia. Whole exome sequencing identified a novel LCP1 p.I232F variant of unknown significance, which was not present in either parent. Bone marrow examination revealed a granulocytic hypoplasia with significant dysmorphic giant granulocytes with complex hypersegmentation and increased apoptosis. (Figure 1A) Based on these observations, we hypothesized that missense mutation in LCP1 (I232F) impairs granulocytic proliferation, and causes neutropenia.Aims: To investigate the role of LCP1 I232F, discovered in a child with severe symptomatic neutropenia, in granulopoiesis.Methods: in vitro experiments involving the expression of wild type and mutant LCP1 I232F in murine myeloblast cell (32D cells) and human cervical cancer HeLa cell. We deployed various biologic and functional studies to investigate the role of LCP1 I232F in granulocyte proliferation, differentiation, survival, and function.Results: To determine the pathophysiologic significance of LCP1 I232F, we stably transduced interleukin 3-dependent murine myeloblast 32D and human cervical cancer HeLa cell lines with a doxycycline-inducible lentiviral constructs containing the cDNA for either wild type LCP1 or LCP1 I232F. The mutant LCP1 I232F expressing 32D cells showed impaired proliferation with the appearance of dysplastic granulocytic cells. (Figure 1A, B) However, we did not observe block in differentiation. A cell cycle arrest at G2/M phase occurred only in the LCP1 I232F expressing cells (Figure 1B) and was associated with an upregulation of markers of cell cycle arrest (Cdkn1a and Tp53). LCP1 I232F overexpression did not lead to increased expression of genes involved in apoptosis or the unfolded protein response. The LCP1 I232F cells with dysplastic features were further analyzed by confocal microscopy, which demonstrated increased level of F-actin and enrichment of F-actin and LCP1 at the cell cortex. Flow cytometric evaluation of these cells further confirmed the presence of increased level of F actin. (Figure 1C) Expression of LCP1 I232F impaired cell motility and invasiveness in both 32D and HeLa cells. However, mutant LCP1 expressing 32D cells demonstrated normal oxidative burst upon treatment with N-formyl-Met-Leu-Phe (fMLP) and phorbol myristate acetate (PMA). Confocal imaging and subcellular fractionation revealed diffuse localization of LCP1, but only the mutant form was found in the nucleus. (Figure 1C) In LCP1, two tandem CH domains (CH1-CH2 and CH3-CH4) formed two actin-binding domains (ABD1 and ABD2) that bind to actin to participate in actin bundling. I232F is located at LCP1-CH1 that interacts with actin. To study how the mutation impacts LCP1-actin binding, we constructed a model of LCP1-ABD1 based on the cryo-EM structure of F-actin/LCP1-ABD2 and performed 40 ns of molecular dynamics (MD) simulations of LCP1-ABD1 and LCP1-ABD1 I232F alone to study their dynamical motions. We found that LCP1-ABD1 I232F adopted a more stable open conformation than LCP1-ABD1 to bind effectively with F-actin. The model implies a prolonged association of LCP1 I232F with actin than wild-type LCP1, and the consequence is the increased stabilization of actin bundles.Conclusions: Like the WAS gain-of-function mutations in SCN, LCP1 I232F resulted in severe neutropenia with dysplastic granulocytic precursors, cell cycle arrest, impaired motility, and increased F actin. We also found decreased proliferation of granulocytic progenitor and precursor cells. Our findings suggest that LCP1 is an important gene involved in granulopoiesis. [Display omitted] DisclosuresNo relevant conflicts of interest to declare.

Role of actin cytoskeleton in the organization and function of ionotropic glutamate receptors.

Neural networks with precise connection are compulsory for learning and memory. Various cellular events occur during the genesis of dendritic spines to their maturation, synapse formation, stabilization of the synapse, and proper signal transmission. The cortical actin cytoskeleton and its multiple regulatory proteins are crucial for the above cellular events. The different types of ionotropic glutamate receptors (iGluRs) present on the postsynaptic density (PSD) are also essential for learning and memory. Interaction of the iGluRs in association of their auxiliary proteins with actin cytoskeleton regulated by actin-binding proteins (ABPs) are required for precise long-term potentiation (LTP) and long-term depression (LTD). There has been a quest to understand the mechanistic detail of synapse function involving these receptors with dynamic actin cytoskeleton. A major, emerging area of investigation is the relationship between ABPs and iGluRs in synapse development. In this review we have summarized the current understanding of iGluRs functioning with respect to the actin cytoskeleton, scaffolding proteins, and their regulators. The AMPA, NMDA, Delta and Kainate receptors need the stable underlying actin cytoskeleton to anchor through synaptic proteins for precise synapse formation. The different types of ABPs present in neurons play a critical role in dynamizing/stabilizing the actin cytoskeleton needed for iGluRs function.

Role of actin cytoskeleton in podocytes.

The selectivity of the glomerular filter is established by physical, chemical, and signaling interplay among its three core constituents: glomerular endothelial cells, the glomerular basement membrane, and podocytes. Functional impairment or injury of any of these three components can lead to proteinuria. Podocytes are injured in many forms of human and experimental glomerular disease, including minimal change disease, focal segmental glomerulosclerosis, and diabetes mellitus. One of the earliest signs of podocyte injury is loss of their distinct structure, which is driven by dysregulated dynamics of the actin cytoskeleton. The status of the actin cytoskeleton in podocytes depends on a set of actin binding proteins, nucleators and inhibitors of actin polymerization, and regulatory GTPases. Mutations that alter protein function in each category have been implicated in glomerular diseases in humans and animal models. In addition, a growing body of studies suggest that pharmacological modifications of the actin cytoskeleton have the potential to become novel therapeutics for podocyte-dependent chronic kidney diseases. This review presents an overview of the essential proteins that establish actin cytoskeleton in podocytes and studies demonstrating the feasibility of drugging actin cytoskeleton in kidney diseases.

Regulation of invadosomes by microtubules: Not only a matter of railways

Invadosomes, which encompass podosomes and invadopodia, are actin rich adhesive and protrusive structures facilitating invasion and migration in various cell types. Podosomes are mostly found in normal cells, while invadopodia are hallmarks of invasive transformed cells. Despite evident structural differences, both structures mostly rely on the same pathways for their formation and their activity. While the role of actin cytoskeleton is undeniable, the involvement of microtubules (MTs) in invadosome formation/activity has recently been demonstrated but also somehow underestimated. MTs are components of the eukaryotic cytoskeleton well known for their essential roles for cell division, the maintenance of cell shape, intracellular transport and cell motility. Until now, MTs were mostly seen as railways for the delivery of various cargos required for invadosome functions but recent data suggest a more complex role. In this review, we address the specific functions of MTs on invadosome dynamics, activity, maturation and organization in light with recent data, which extended far beyond simple track delivery. Indeed, MT dynamic instability, which in turn modulates Rho GTPase signalling and likely MT post-translational modifications are playing major roles in invadosome functions.

Lung Endothelial Transcytosis.

Transcytosis of macromolecules through lung endothelial cells is the primary route of transport from the vascular compartment into the interstitial space. Endothelial transcytosis is mostly a caveolae-dependent process that combines receptor-mediated endocytosis, vesicle trafficking via actin-cytoskeletal remodeling, and SNARE protein directed vesicle fusion and exocytosis. Herein, we review the current literature on caveolae-mediated endocytosis, the role of actin cytoskeleton in caveolae stabilization at the plasma membrane, actin remodeling during vesicle trafficking, and exocytosis of caveolar vesicles. Next, we provide a concise summary of experimental methods employed to assess transcytosis. Finally, we review evidence that transcytosis contributes to the pathogenesis of acute lung injury. © 2020 American Physiological Society. Compr Physiol 10:491-508, 2020.

The Rice Actin-Binding Protein RMD Regulates Light-Dependent Shoot Gravitropism.

Light and gravity are two key determinants in orientating plant stems for proper growth and development. The organization and dynamics of the actin cytoskeleton are essential for cell biology and critically regulated by actin-binding proteins. However, the role of actin cytoskeleton in shoot negative gravitropism remains controversial. In this work, we report that the actin-binding protein Rice Morphology Determinant (RMD) promotes reorganization of the actin cytoskeleton in rice (Oryza sativa) shoots. The changes in actin organization are associated with the ability of the rice shoots to respond to negative gravitropism. Here, light-grown rmd mutant shoots exhibited agravitropic phenotypes. By contrast, etiolated rmd shoots displayed normal negative shoot gravitropism. Furthermore, we show that RMD maintains an actin configuration that promotes statolith mobility in gravisensing endodermal cells, and for proper auxin distribution in light-grown, but not dark-grown, shoots. RMD gene expression is diurnally controlled and directly repressed by the phytochrome-interacting factor-like protein OsPIL16. Consequently, overexpression of OsPIL16 led to gravisensing and actin patterning defects that phenocopied the rmd mutant. Our findings outline a mechanism that links light signaling and gravity perception for straight shoot growth in rice.

The role of actin cytoskeleton in regulating the deployment process of mouse cardiac second heart field progenitor cells

The vertebrate heart tube originates from cardiogenic mesodermal cells in the early embryo, and subsequently elongates by progressive addition of second heart field (SHF) progenitor cells from adjacent pharyngeal mesoderm and splanchnic mesoderm. Insufficient addition of SHF cells to the heart tube causes the failure of maximal elongation of the heart tube, which results in a series of developmental defects including the most common congenital birth defects, such as right ventricular dysplasia and outflow tract septation, and alignment anomalies. SHF cells form an atypical, apicobasally polarized epithelium which is characterized by apical monocilia, and dynamic actin-rich basal filopodia. In this review, we summarize recent research progresses of actin cytoskeleton in the deployment process of mouse SHF progenitor cells, and reveal the significance of actin cytoskeleton in SHF development, especially in the deployment of SHF cells to the outflow tract, to provide theoretical reference for elucidating and understanding the biological characteristics of SHF deployment.

The Role of Actin Cytoskeleton in Dendritic Spines in the Maintenance of Long-Term Memory.

Evidence indicates that long-term memory formation involves alterations in synaptic efficacy produced by modifications in neural transmission and morphology. However, it is not clear how such alterations induced by learning, that encode memory, are maintained over long period of time to preserve long-term memory. This is especially intriguing as the half-life of most of the proteins that underlie such changes is usually in the range of hours to days and these proteins may change their location over time. In this review we describe studies that indicate the involvement of dendritic spines in memory formation and its maintenance. These studies show that learning leads to changes in the number and morphology of spines. Disruption in spines morphology or manipulations that lead to alteration in their number after consolidation are associated with impairment in memory maintenance. We further ask how changes in dendritic spines morphology, induced by learning and reputed to encode memory, are maintained to preserve long-term memory. We propose a mechanism, based on studies described in the review, whereby the actin cytoskeleton and its regulatory proteins involved in the initial alteration in spine morphology induced by learning are also essential for spine structural stabilization that maintains long-term memory. In this model glutamate receptors and other synaptic receptors activation during learning leads to the creation of new actin cytoskeletal scaffold leading to changes in spines morphology and memory formation. This new actin cytoskeletal scaffold is preserved beyond actin and its regulatory proteins turnover and dynamics by active stabilization of the level and activity of actin regulatory proteins within these memory spines.

The roles of actin cytoskeleton and actin-associated protein Crn1p in trap formation of Arthrobotrys oligospora

Nematode-trapping fungi include a variety of species capable of generating specific trapping devices to capture nematodes and the production of devices is also an indicator of a switch from saprophytic to predacious lifestyles. Traps are developed from vegetative mycelia, but they are quite different from hyphae in both morphological and physiological characteristics. Therefore, the molecular mechanisms underlying their formation have attracted much attention. In this investigation, Arthrobotrys oligospora, a nematode-trapping fungus, has three-dimensional networks and genomics and proteomics were recently performed, so as to reveal the relationship between actin cytoskeleton and trap formation. Both actin staining via FITC-phalloidin and treatment of actin polymerization inhibitor Lat-B illustrated that the actin cytoskeleton played an important role in trap development. Furthermore, absence of the conserved actin-associated protein Crn1p caused a structural defect of traps and failure to infect nematodes. It was observed that mutant Δcrn1 represented a reduced number of rings and a lower complexity of three-dimensional networks, likely due to the disturbance of actin branching. Collectively, our study confirmed the involvement of the actin cytoskeleton as well as the conserved actin-associated protein Crn1p in trap formation. It further suggested the manners in which Crn1p influences the development of three-dimensional networks in A. oligospora.

Actin cytoskeleton regulator Arp2/3 complex is required for DLL1 activating Notch1 signaling to maintain the stem cell phenotype of glioma initiating cells.

Glioblastoma (GBM) is the most common and lethal primary intracranial tumor. Actin cytoskeleton regulator Arp2/3 complex stimulates glioma cell motility and migration, and thus triggers tumor invasion. However, little is known regarding the role of actin cytoskeleton in maintaining the stem cell phenotype. Here, we showed that Arp2/3 complex improved stem cell phenotype maintenance through sustaining the activated Notch signaling. ShRNA targeting Notch ligand Delta-like 1 (DLL1) decreased CD133 and Nestin expression, and impaired the self-renewal ability of CD133+ U87-MG and U251-MG glioma cells, indicating DLL1/Notch1 signaling promoted stem cell phenotype maintenance. Interestingly, inhibiting Arp2/3 complex also induced the similar effect of shDLL1. Silencing DLL1 in the Arp2/3 inhibited CD133+ cells did not further abrogate the stem cell phenotype, suggesting DLL1 function requires Arp2/3 complex in glioma initiating cells (GICs). However, exogenous soluble DLL1 (sDLL1) instead of endogenous DLL1 rescued the Arp2/3 inhibition-induced stem cell phenotype suppression. The underlying mechanism was that Arp2/3 inhibition impeded DLL1 vesicular transport from cytoplasm to cell membrane, which resulted in DLL1 unable to activate Notch pathway. Furthermore, we illustrated that Arp2/3 inhibition abolished the tumorigenicity of CD133+ U87-MG neurosphere cells in the intracranial model. These findings suggested that cytoskeleton maintained the stem cell phenotype in GBM, which provide novel therapeutic strategy that anti-invasive targeted therapies may help eliminate GICs.

Role of Actin Cytoskeleton in the Regulation of Epithelial Cutaneous Stem Cells.

Cutaneous stem cells (CSCs) orchestrate the homeostasis and regeneration of mammalian skin. Epithelial CSCs have been isolated and characterized from the skin and hold great potential for tissue engineering and clinical applications. The actin cytoskeleton is known to regulate cell adhesion and motility through its intricate participation in signal transduction and structural modifications. The dynamics of actin cytoskeleton can directly influence CSCs behaviors including tissue morphogenesis, homeostasis, niche maintenance, activation, and wound repair. Various regulators of the actin cytoskeleton including kinases, actin-remodeling proteins, paracrine signals, and micro-RNAs collaborate and contribute to epithelial CSC proliferation, adhesion, and differentiation. This review brings together the latest mechanistic insights into how the actin cytoskeleton participates in the regulation of epithelial CSCs during development, homeostasis, and wound repair.

The Role of Actin Cytoskeleton in Memory Formation in Amygdala.

The central, lateral and basolateral amygdala (BLA) nuclei are essential for the formation of long-term memories including emotional and drug-related memories. Studying cellular and molecular mechanisms of memory in amygdala may lead to better understanding of how memory is formed and of fear and addiction-related disorders. A challenge is to identify molecules activated by learning that subserve cellular changes needed for memory formation and maintenance in amygdala. Recent studies show that activation of synaptic receptors during fear and drug-related learning leads to alteration in actin cytoskeleton dynamics and structure in amygdala. Such changes in actin cytoskeleton in amygdala are essential for fear and drug-related memories formation. Moreover, the actin cytoskeleton subserves, after learning, changes in neuronal morphogenesis and glutamate receptors trafficking in amygdala. These cellular events are involved in fear and drug-related memories formation. Actin polymerization is also needed for the maintenance of drug-associated memories in amygdala. Thus, the actin cytoskeleton is a key mediator between receptor activation during learning and cellular changes subserving long-term memory (LTM) in amygdala. The actin cytoskeleton may serve as a target for pharmacological treatment of fear memory associated with fear and anxiety disorders and drug addiction to prevent the debilitating consequences of these diseases.

Role of actin cytoskeleton at multiple levels of T cell activation

Actin cytoskeleton is an essential cellular structure that is involved in many physiological aspects, including T cell antigenic responses. In has been proposed that actin modulates biophysical parameters of the antigen recognition, forms a barrier inhibiting spontaneous signaling in resting T cells, facilitates TCR signal transduction, stabilizes contacts between T cells and antigen presenting cells, and contributes to the establishment of the antigen affinity threshold. In this review, we discuss the role of actin cytoskeleton at these particular levels of T cell activation.

Cofilin as a Promising Therapeutic Target for Ischemic and Hemorrhagic Stroke.

Neurovascular unit (NVU) is considered as a conceptual framework for investigating the mechanisms as well as developing therapeutic targets for ischemic and hemorrhagic stroke. From a molecular perspective, oxidative stress, excitotoxicity, inflammation, and disruption of the blood brain barrier are broad pathophysiological frameworks on the basis on which potential therapeutic candidates for ischemic and hemorrhagic stroke could be discussed. Cofilin is a potent actin-binding protein that severs and depolymerizes actin filaments in order to generate the dynamics of the actin cytoskeleton. Although studies of the molecular mechanisms of cofilin-induced reorganization of the actin cytoskeleton have been ongoing for decades, the multicellular functions of cofilin and its regulation in different molecular pathways are expanding beyond its primary role in actin cytoskeleton. This review focuses on the role of cofilin in oxidative stress, excitotoxicity, inflammation, and disruption of the blood brain barrier in the context of NVU as well as how and why cofilin could be studied further as a potential target for ischemic and hemorrhagic stroke.

Induction of Mindin is Associated with Pathological Changes in the Kidney of Cd151‐/‐ Mice

The presence of CD151, a transmembrane protein involved in cell adhesion complexes with α3β1 integrins, is essential for glomerular function. We have identified significant increases in mindin in the glomeruli of CD151 knock‐out mice (Cd151‐/‐)compared to wild‐types (Cd151+/+). Due to mindins known role in actin cytoskeleton and cell adhesion signalling, we hypothesised that aberrant expression of mindin in the glomerulus leads to the abnormal extracellular matrix deposition, and disruption to podocyte actin cytoskeleton structure, which occurs in this disease model.Immunofluorescent labelling of mindin in 3‐week‐old Cd151+/+ and Cd151‐/‐ kidneys demonstrated specific accumulation in Cd151‐/‐ glomeruli, (absent in Cd151+/+). No expression of mindin was observed in 5 day old mice (when Cd151‐/‐ glomeruli first exhibit pathology) indicating it is unlikely to be involved in initial pathology.As mindin is also an immune cell activator, we examined whether the induction of mindin leads to immune‐mediated glomerular injury as part of disease progression in the Cd151‐/‐ kidney. We also investigated mindin as a potential biomarker of glomerular disease in the broader sense and characterised immune cell infiltrates in Cd151‐/‐ kidneys.Infiltration of lymphocytes, neutrophils, macrophages and eosinophils was observed as early as 3 weeks of age in Cd151‐/‐ but not Cd151+/+ kidneys by differential histological staining. This infiltration was progressive and more pronounced in 12 week old Cd151‐/‐ mice, associated with extensive inflammatory lesions. Together, these data suggest that in the absence of CD151, mindin is induced early in disease, associated with disruption to podocyte actin cytoskeleton homeostasis, and immune‐mediated glomerular damage.

Interconnection between actin cytoskeleton and plant defense signaling

Actin cytoskeleton is the fundamental structural component of eukaryotic cells. It has a role in numerous elementary cellular processes such as reproduction, development and also in response to abiotic and biotic stimuli. Remarkably, the role of actin cytoskeleton in plant response to pathogens is getting to be under magnifying glass. Based on microscopic studies, most of the data showed, that actin plays an important role in formation of physiological barrier in the site of infection. Actin dynamics is involved in the transport of antimicrobial compounds and cell wall fortifying components (e.g. callose) to the site of infection. Also the role in PTI (pathogen triggered immunity) and ETI (effector triggered immunity) was recently indicated. On the other hand much less is known about the transcriptome reprogramming upon changes in actin dynamics. Our recently published results showed that drugs inhibiting actin polymerization (latrunculin B, cytochalasin E) cause the induction of genes which are involved in salicylic acid (SA) signaling pathway. In this addendum we would like to highlight in more details current state of knowledge concerning the involvement of actin dynamics in plant defense signaling.