Novel Coronin7 interactions with Cdc42 and N-WASP regulate actin organization and Golgi morphology

Bhattacharya, K., Swaminathan, Karthic, Peche, V.S., Clemen, C.S., Knyphausen, P., Lammers, M., Noegel, A.A., Rastetter, R.H.

28 February 2020

Yes / The contribution of the actin cytoskeleton to the unique architecture of the Golgi complex is manifold. An important player in this process is Coronin7 (CRN7), a Golgi-resident protein that stabilizes F-actin assembly at the trans-Golgi network (TGN) thereby facilitating anterograde trafficking. Here, we establish that CRN7-mediated association of F-actin with the Golgi apparatus is distinctly modulated via the small Rho GTPase Cdc42 and N-WASP. We identify N-WASP as a novel interaction partner of CRN7 and demonstrate that CRN7 restricts spurious F-actin reorganizations by repressing N-WASP ‘hyperactivity’ upon constitutive Cdc42 activation. Loss of CRN7 leads to increased cellular F-actin content and causes a concomitant disruption of the Golgi structure. CRN7 harbours a Cdc42- and Rac-interactive binding (CRIB) motif in its tandem β-propellers and binds selectively to GDP-bound Cdc42N17 mutant. We speculate that CRN7 can act as a cofactor for active Cdc42 generation. Mutation of CRIB motif residues that abrogate Cdc42 binding to CRN7 also fail to rescue the cellular defects in fibroblasts derived from CRN7 KO mice. Cdc42N17 overexpression partially rescued the KO phenotypes whereas N-WASP overexpression failed to do so. We conclude that CRN7 spatiotemporally influences F-actin organization and Golgi integrity in a Cdc42- and N-WASP-dependent manner. / This work was supported by SFB 670 and DFG NO 113/22. K.B. was supported by a fellowship from the NRW International Graduate School “From Embryo to Old Age: the Cell Biology and Genetics of Health and Disease” (IGSDHD), Cologne.

Actin cytoskeleton

Golgi complex

Coronin7 (CRN7)

N-WASP

Actin organization

Golgi morphology

Coordination by Cdc42 of actin, contractility, and adhesion for melanoblast movement in mouse skin

Woodham, E.F., Paul, N.R., Tyrrell, B., Spence, H.J., Swaminathan, Karthic, Scribner, M.R., Giampazolias, E., Hedley, A., Clark, W., Kage, F., Marston, D.J., Hahn, K.M., Tait, S.W.G., Larue, L., Brakebusch, C.H., Insall, R.H., Machesky, L.M.

28 February 2020

Yes / The individual molecular pathways downstream of Cdc42, Rac, and Rho GTPases are well documented, but we know surprisingly little about how these pathways are coordinated when cells move in a complex environment in vivo. In the developing embryo, melanoblasts originating from the neural crest must traverse the dermis to reach the epidermis of the skin and hair follicles. We previously established that Rac1 signals via Scar/WAVE and Arp2/3 to effect pseudopod extension and migration of melanoblasts in skin. Here we show that RhoA is redundant in the melanocyte lineage but that Cdc42 coordinates multiple motility systems independent of Rac1. Similar to Rac1 knockouts, Cdc42 null mice displayed a severe loss of pigmentation, and melanoblasts showed cell-cycle progression, migration, and cytokinesis defects. However, unlike Rac1 knockouts, Cdc42 null melanoblasts were elongated and displayed large, bulky pseudopods with dynamic actin bursts. Despite assuming an elongated shape usually associated with fast mesenchymal motility, Cdc42 knockout melanoblasts migrated slowly and inefficiently in the epidermis, with nearly static pseudopods. Although much of the basic actin machinery was intact, Cdc42 null cells lacked the ability to polarize their Golgi and coordinate motility systems for efficient movement. Loss of Cdc42 de-coupled three main systems: actin assembly via the formin FMNL2 and Arp2/3, active myosin-II localization, and integrin-based adhesion dynamics. / Cancer Research UK (to L.M.M. [A17196], R.H.I. [A19257], and S.W.G.T.) and NIH grants P01-GM103723 and P41-EB002025 (to K.M.H.). N.R.P. is supported by a Pancreatic Cancer Research Fund grant (to L.M.M.). Funding to Prof. Rottner by the Deutsche Forschungsgemeinschaft (grant RO2414/3-2).

Rho GTPases

Migration

Actin cytoskeleton

Cell motility

Melanocyte

Myosin

Actin

Adhesion

Integrin

Cdc42

WASP restricts active Rac to maintain cells' front-rear polarization

Amato, C., Thomason, P.A., Davidson, A.J., Swaminathan, Karthic, Ismail, S., Machesky, L.M., Insall, R.H.

28 February 2020

Yes / Efficient motility requires polarized cells, with pseudopods at the front and a retracting rear. Polarization is maintained by restricting the pseudopod catalyst, active Rac, to the front. Here, we show that the actin nucleation-promoting factor Wiskott-Aldrich syndrome protein (WASP) contributes to maintenance of front-rear polarity by controlling localization and cellular levels of active Rac. Dictyostelium cells lacking WASP inappropriately activate Rac at the rear, which affects their polarity and speed. WASP’s Cdc42 and Rac interacting binding (“CRIB”) motif has been thought to be essential for its activation. However, we show that the CRIB motif’s biological role is unexpectedly complex. WASP CRIB mutants are no longer able to restrict Rac activity to the front, and cannot generate new pseudopods when SCAR/WAVE is absent. Overall levels of Rac activity also increase when WASP is unable to bind to Rac. However, WASP without a functional CRIB domain localizes normally at clathrin pits during endocytosis, and activates Arp2/3 complex. Similarly, chemical inhibition of Rac does not affect WASP localization or activation at sites of endocytosis. Thus, the interaction between small GTPases and WASP is more complex than previously thought—Rac regulates a subset of WASP functions, but WASP reciprocally restricts active Rac through its CRIB motif. / Cancer Research UK grants A15672, A24450, and multidisciplinary grant A20017.

Actin polymerization

Arp2/3 complex

Cell polarity

Uropod

Small GTPases

CRIB motif

Actin cytoskeleton

The small GTPases Ras and Rap1 bind to and control TORC2 activity

Khanna, Ankita, Lotfi, Pouya, Chavan, Anita J., Montaño, Nieves M., Bolourani, Parvin, Weeks, Gerald, Shen, Zhouxin, Briggs, Steven P., Pots, Henderikus, Van Haastert, Peter J. M., Kortholt, Arjan, Charest, Pascale G.

13 May 2016

Target of Rapamycin Complex 2 (TORC2) has conserved roles in regulating cytoskeleton dynamics and cell migration and has been linked to cancer metastasis. However, little is known about the mechanisms regulating TORC2 activity and function in any system. In Dictyostelium, TORC2 functions at the front of migrating cells downstream of the Ras protein RasC, controlling F-actin dynamics and cAMP production. Here, we report the identification of the small GTPase Rap1 as a conserved binding partner of the TORC2 component RIP3/SIN1, and that Rap1 positively regulates the RasC-mediated activation of TORC2 in Dictyostelium. Moreover, we show that active RasC binds to the catalytic domain of TOR, suggesting a mechanism of TORC2 activation that is similar to Rheb activation of TOR complex 1. Dual Ras/Rap1 regulation of TORC2 may allow for integration of Ras and Rap1 signaling pathways in directed cell migration.

CONTROLS CELL-ADHESION

DICTYOSTELIUM-DISCOIDEUM

SIGNAL RELAY

MACROPHAGES PROMOTE

MEDIATED ACTIVATION

ACTIN CYTOSKELETON

PARACRINE LOOP

G-PROTEINS

CHEMOTAXIS

MIGRATION

Evolutionary history of clathrin-mediated endocytosis and the eisosome

Cibrario, Luigi

January 2011

Endocytosis is both an ancient and a diverse feature of the eukaryotic cell. Studying how it evolved can provide insight into the nature of the last common eukaryotic ancestor, and the diversification of eukaryotes into the known extant lineages. In this thesis, I present two studies on the evolution of endocytosis. In the first part of the thesis I report results from a large-scale, phylogenetic and comparative genomic study of clathrin-mediated endocytosis (CME). The CME pathway has been studied to a great level of detail in yeast to mammal model organisms. Several protein families have now been identified as part of the complex set of protein-protein and protein-lipid interactions which mediate endocytosis. To investigate how such complexity evolved, first, I defined the modular nature of the CME interactome (CME-I) by literature review, and then I carried out a systematic phylogenetic and protein domain architecture analysis of the proteins involved. These data were used to construct a model of the evolution of the CME-I network, and to map the expansion of the network's complexity to the eukaryotic tree of life. In the second part of the thesis, I present results from evolutionary and functional studies of the eisosome, a protein complex which has been proposed to regulate the spatial distribution of endocytosis in S. cerevisiae. The phylogeny of eisosomes components Pil1 and Lsp1 reported here, suggests that eisosomes are likely to have originated at the base of the fungi, and then diversified significantly via multiple gene duplications. I thus studied the localisation and function of Pil1 and Lsp1 homologues in Magnaporthe oryzae to investigate the role of eisosomes in filamentous fungi. Results suggests that eisosomes are linked with septal formation and integrity in M. oryzae, and that the septal specific Pil2 paralogue was lost in budding yeasts. Together, the data presented in this thesis describe the evolutionary history of a complex biological system, but also highlights the problem of asymmetry in the understanding of endocytic diversity in the eukaryotes.

571.6

The structural basis of the disabling of the actin polymerization machinery by Yersinia

Lee, Wei Lin

January 2013

Yersinia pestis is a human pathogen and the causative agent of bubonic plague, responsible for causing three massive pandemics, resulting in hundreds of millions of deaths in the 14th century alone. Yersinia’s virulence stems from its ability to overcome host immune defences by the injection of six Yersinia outer proteins (Yops) into the host cells via its Type III secretion system. One of these Yops, YopO specifically disables the actin polymerization machinery, leading to the crippling of phagocytosis. YopO consists of a GDI domain which sequesters Rac and Rho, and a kinase domain, the activity of which is dependent on host actin. Little is known about the targets of the kinase domain and the mechanism of function of YopO remains incomplete. In this work, YopO was crystallized in complex with actin, revealing that YopO binds to actin on subdomain 4, away from the 'hotspot’ between subdomains 1 and 3 which is involved in binding most actin-binding proteins. The structure reveals how recruitment of YopO-bound actin monomers stalls actin polymerization by steric hindrance. The structure also demonstrates how YopO uses actin for self-activation and suggests that actin is being used by YopO as bait for recruitment into actin machineries. Using SILAC mass spectrometry, actin cytoskeletal machineries within macrophages that recruit YopO are identified and these include, amongst others: VASP family proteins, gelsolin family proteins, formins and WASP. Of these, VASP, EVL, diaphanous1, WASP and gelsolin have been identified to be phosphorylated by YopO and were validated by in vitro phosphorylation. This work demonstrates that YopO uses actin as a scaffold for selection of kinase substrates, enabling targeted phosphorylation of the actin machinery and provides insight into the regulation of the actin cytoskeleton by phosphorylation under non-pathogenic conditions.

579.3

Dynamique des réseaux d'actine d'architecture contrôlée / Dynamics of controlled actin network's architecture

Reymann, Anne-Cécile

11 July 2011

Mon travail fut de développer différents projets en vue de mieux comprendre la dynamique et l'organisation des réseaux d'actine et les mécanismes moléculaires à l'origine de la production de force, cela en systèmes reconstitués bio-mimétiques. Dans un premier temps je me suis intéressée à l'étude de l'organisation spatio-temporelle des réseaux d'actine et de ses protéines associées durant la motilité de particules recouverte de promoteurs de nucléation (Achard et al, Current Biology, 2010 et Reymann et al, sous presse à MBOC). J'ai suivi en temps réel l'incorporation de deux régulateurs de l'actine (capping protein et ADF/cofiline) et montré que leur contrôle biochimique sur l'actine gouverne également ces propriétés mécaniques. Afin de mieux caractériser les propriétés mécaniques de ces réseaux d'actine en expension, j'ai ensuite développé un système biomimétique novateur utilisant un set-up de micro-patterning permettant un contrôle spatial reproductible des sites de nucléation d'actine. Cela m'a permis de montrer comment des barrières géométriques, semblables à celles trouvées dans les cellules, peuvent influencer la formation dynamique de réseaux organisés d'actine et ainsi contrôler la localisation de la production de forces. (Reymann et al, Nature Materials, 2010). De plus l'addition de moteurs moléculaires sur ce système versatile nous a permis d'étudier la contraction induite par des myosines. En particulier les myosines VI-HMM interagissent de manière sélective sur différentes architectures d'actine (organisation parallèle ou antiparallèle, réseau enchevêtré), aboutissant à un processus en trois phase : tension puis déformation des réseaux d'actine fortement couplé à un désassemblage massif des filaments. Ce phénomène est intimement dépendant de l'architecture du réseau d'actine et pourrait donc jouer un rôle essentiel dans la régulation spatiale des zones d'expansion et de contraction du cytosquelette in vivo. (Travail en cours d'écriture). / I have developed different projects in order to tackle the problem of actin network dynamics and organization as well as the molecular mechanism at the origin of force production in biomimetic reconstituted systems. My first interest concerned the spatiotemporal organization of actin networks and actin-binding proteins during actin based motility of nucleation promoting factor-coated particles (Achard et al, Current Biology, 2010 and Reymann et al, in press at MBOC). I tracked in real time the incorporation of two actin regulators and showed that their biochemical control of actin dynamics also governs its mechanical properties. To further characterize mechanical properties of expanding actin networks, I used an innovative micro-patterning set-up allowing a reproducible spatial control of actin nucleation sites. It allowed me to show that geometrical boundaries, such as those encountered in cells, affect the dynamic formation of highly ordered actin structures and hence control the location of force production (Reymann et al, Nature Materials, 2010). Finally the addition of molecular motors on this tunable system allowed me to study implications for myosin-induced contractility. In particular, HMM-MyosinVI selectively interact with the different actin network architectures (parallel, anti-parallel organization or entangled networks) and leads to a selective three-phase process of tension, deformation of actin networks tightly coupled to massive filament disassembly. This phenomenon being highly dependent on actin network architecture could therefore play an essential role in the spatial regulation of expanding and contracting regions of actin cytoskeleton in cells. (Work in writing process).

Cytoskelette actine

Biophysique

Production de force

Myosine

Systèmes biomimétiques

Actin cytoskeleton

Biophysics

Force production

Myosin

Biomimetic sytems

530

Estudo das propriedades mecânicas das células de músculo liso vascular em situações fisiológicas e patológicas / Study of the mechanical properties of vascular smooth muscle cells under physiological and pathological situations

Dinardo, Carla Luana

02 December 2015

Introdução: As células do músculo liso vascular (CMLV) são quiescentes nos vasos adultos, com baixa capacidade de migração e de secreção de matriz extracelular, caracterizando fenótipo contrátil. Evidências apontam para a heterogeneidade fenotípica das CMLV ao longo da árvore arterial: há distribuição heterogênea de doenças e de resposta a determinadas drogas nos diferentes vasos, além de variabilidade de expressão dos genes de proteínas contráteis de músculo liso entre eles. O papel das CMLV, em fase adulta, é classicamente descrito como restrito à regulação do tônus de pequenos vasos, sendo insignificante a contribuição da mecânica das CMLV para a complacência das artérias elásticas. Existe a hipótese de que a viscoelasticidade das CMLV contribua para a mecânica final das artérias, sendo o enrijecimento dessas células associado à rigidez arterial. Objetivo: Estudar a variabilidade das propriedades mecânicas e de expressão proteica das CMLV, ao longo da árvore arterial, buscando identificar moduladores regionais para esse fenótipo. Avaliar se situações clínicas sabidamente associadas à rigidez arterial (envelhecimento, sexo feminino pós-menopausa, ancestralidade genética africana, diabetes mellitus e tabagismo) cursam com enrijecimento de CMLV. Métodos: 1) Estudou-se a composição e a organização da camada média de diferentes artérias. As CMLV desses vasos foram avaliadas quanto à viscoelasticidade de citoplasma (G), por meio do ensaio de Citometria Magnético Ótica de Oscilação e, quanto à expressão proteica global, usando cromatografia multidimensional e espectrometria de massas em tandem de alta resolução (Proteômica Shotgun). Os dados mecânicos obtidos foram correlacionados com as características da matriz extracelular (MEC) dos vasos de origem (porcentagem de elastina e quantidade de MEC). Em paralelo, foi realizado experimento de estiramento cíclico (10%/1Hz) das CMLV das diferentes artérias por 24 e 48h, seguido pela mensuração de rigidez de citoplasma. 2) Foram isoladas as CMLV de fragmentos de artéria mamária de 80 pacientes submetidos à cirurgia de revascularização do miocárdio, células essas que foram avaliadas quanto à viscoelasticidade de citoplasma (G, G\' e G\'\'). Elaborou-se modelo estatístico para avaliar se as variáveis clínicas idade, sexo feminino, ancestralidade africana, tabagismo e diabetes mellitus estavam associadas a alterações de mecânica celular. Resultados: 1) A viscoelasticidade das CMLV variou significativamente entre as artérias. As CMLV provenientes de artérias distais (artérias femoral e renal) mostraram-se significativamente mais rígidas que as CMLV de aorta torácica (p < 0,001). Identificou-se correlação negativa entre rigidez de CMLV e quantidade de MEC / elastina na camada média vascular. O regime de estiramento cíclico por 48h reduziu globalmente a rigidez das CMLV. As CMLV provenientes da aorta torácica expressaram maior quantidade de proteínas relacionadas com a estrutura e a organização do citoesqueleto em relação às CMLV da artéria femoral. 2) Constatou-se variabilidade interindividual de viscoelasticidade de CMLV e associação entre tabagismo e sexo feminino com enrijecimento de CMLV. Conclusões: As CMLV são heterogêneas quanto às propriedades mecânicas, à organização do citoesqueleto e à expressão proteica ao longo da árvore arterial, reforçando o conceito de plasticidade fenotípica das CMLV. A mecânica das CMLV é modulada pelas características da MEC e pela tensão circunferencial cíclica aplicada às paredes vasculares pelo fluxo sanguíneo. Mulheres pós-menopausa e tabagistas exibem enrijecimento de CMLV, sendo esse fato um provável contribuinte para a rigidez arterial associada a essas condições e um possível alvo terapêutico a ser avaliado futuramente / Rational: Vascular smooth muscle cells (VSMC) lose their ability to migrate and secrete extracellular matrix (ECM) with the end of vascular development, condition known as contractile phenotype and reversible in the presence of vascular injury. There is evidence of heterogeneity of VSMC phenotype along arterial tree, as the distribution of diseases (atherosclerosis) and the response to drugs vary between different vessels, as well as the expression of smooth muscle-contractile protein genes. The role played by VSMC mechanics on determining large arteries\' compliance was always considered irrelevant. It has been hypothesized that the VSMC mechanical properties are important for vascular mechanics, especially in the pathological scenario, where VSMC stiffening may be associated with arterial rigidity. Goals: Study the variation of VSMC mechanics and protein expression along arterial tree, identifying regional modulators of this phenotype. Evaluate if clinical situations associated with arterial rigidity (ageing, post-menopausal women, African ancestry, diabetes mellitus and smoking) concur with VSMC stiffening. Methods: 1) Different arteries were studied in terms of composition and organization of their media layer. VSMC isolated from these arteries were evaluated regarding cytoplasm viscoelasticity, measured using Optical Magnetic Twisting Cytometry Assay (OMTC), and protein expression, using two-dimensional liquid chromatography and tandem mass spectrometry (Shotgun Proteomics). Mechanical data were correlated with ECM characteristics (percentage of elastin and ECM amount) of the vessels of origin. In parallel, VSMC of different arteries were subjected to cyclic stretching (10%/1Hz) during 24 and 48h, followed by the measurement of their cytoplasm rigidity. 2) VSMC were isolated from fragments of mammary artery of 80 patients subjected to coronary bypass surgery and evaluated regarding their viscoelasticity (G, G\' e G\'\'). A statistic model was elaborated to address if the clinical variables age, female sex, African ancestry, smoking and diabetes mellitus were associated with changes of VSMC mechanics. Results: 1) VSMC viscoelasticity varied significantly amongst the studied arteries. VSMC from heart-distant arteries (femoral and renal arteries) were stiffer than VSMC from thoracic aorta (p < 0,001). There was a negative correlation between VSMC rigidity and the amount of ECM / percentage of elastin within the media layer. 48h-cyclic stretching was associated with a global reduction of VSMC rigidity. VSMC of thoracic aorta expressed significantly more proteins associated with cytoskeleton structure and organization than VSMC of femoral artery. 2) There was a significant inter-individual variation of VSMC viscoelasticity. Smoking and female sex were associated with VSMC stiffening. Conclusion: VSMC mechanics, cytoskeleton organization and protein expression are heterogeneous along arterial tree. VSMC mechanical properties are modulated by ECM characteristics and by regional mechanical forces. This reinforces the concept of phenotypic heterogeneity of VSMC. Post-menopausal women and smokers exhibit stiffer VSMC, representing an important factor for the understanding of the arterial rigidity associated with these conditions and also a possible future therapeutic target

Actin cytoskeleton

Artérias

Arteries

Citoesqueleto

Citoesqueleto de actina

Cytoskeleton

Músculo liso

Proteômica

Proteomics

Rigidez vascular

Smoking

Smooth muscle

Tabagismo

Vascular stiffness

Toca-1 driven actin polymerisation at membranes

Fox, Helen Mary

January 2018

Regulation of the actin cytoskeleton is key to cellular function and underlies processes including cell migration, mitosis and endocytosis. Motile cells send out dynamic actin protrusions that enable them to sense and interact with their environment, as well as generating physical forces. Linking of the actin cytoskeleton to the cell membrane is essential for the formation of these protrusions. The proteins that are thought to fulfil such a role have a membrane interacting domain (such as the PH domain in lamellipodin, or I-BAR protein in IRSp53) and a domain which interacts with actin regulatory proteins (such as the SH3 domain of IRSp53, which binds Ena and VASP). I investigated the contribution of the F-BAR protein Toca-1 in linking actin polymerisation to membranes, by characterising a new protein-protein interaction and the interaction of Toca-1 with giant unilamellar vesicles. FBP17, a homologue of Toca-1, can oligomerise to form 2D flat lattices and 3D tubules on membranes. Proteins of the Toca-1 family have previously been implicated in actin polymerisation in cell-free systems and during endocytosis. However, there is emerging evidence that Toca-1 family proteins could also be involved in the formation of outward facing protrusions, lamellipodia and filopodia. In an in vitro system that recapitulates the formation of filopodia-like structures (FLS) on supported lipid bilayers, Toca-1 is recruited early, suggesting a Toca-1 scaffolding mechanism could precede the recruitment of other actin regulators. One prediction of this model is that Toca-1 would bind proteins previously implicated in filopodia formation, such as formins. I found that extracts depleted of Toca-1 binding partners no longer forms filopodia-like structures and subsequently optimised pull-down assays to identify Toca-1 binding partners by mass-spectrometry. I identified four formins, Diaph1, Diaph3, FHOD1 and INF2, and as well as the actin elongation factors and filopodia proteins, Ena and VASP. I further characterised these interactions and found that Toca-1 binds Ena and VASP via its SH3 domain. The interaction is direct and is strongly reduced if the proline-rich region in Ena is deleted. VASP was still able to bind without its proline rich region, suggesting there could be additional binding sites. I discovered that the binding of Ena and VASP was dependent on the clustering state of Toca-1, whilst the binding of the previously identified Toca-1 binding partner N-WASP was not. This further supports the importance of Toca-1 oligomerisation in actin polymerisation. I tested these interactions in the FLS system and found that increasing Toca-1 concentration leads to increased recruitment of N-WASP, as well as the novel binding partner Ena to the structures, whereas an increase in VASP was not observed. SH3-domain mediated interactions are required for Toca-1 recruitment to FLS, suggesting that its membrane and protein binding activities act cooperatively. I showed that unlike N-WASP, which promotes the formation of branched actin, Ena and VASP are not required for actin polymerisation on supported lipid bilayers, suggesting that they are redundant with other factors in the elongation step of FLS formation. Ena and VASP are known to be important for the formation of neuronal filopodia and so I began to further test the role of these interactions in a cellular context using a neuronal cell culture system. As well as recruiting protein binding partners, F-BAR family proteins are implicated in stabilising lipid microdomains and can induce the clustering of phosphoinositides. I investigated the role of Toca-1 in actin polymerisation on PI(4,5)P2-rich giant unilamellar vesicles (GUVs). Actin-rich tails formed on the GUVs only when excess Toca-1 was supplemented into the extracts, and I propose that this is due to lipid organisation by Toca-1. In summary, my work suggests a model in which Toca-1 clusters, stabilises the membrane lipids and recruits regulators of actin polymerisation, such as Ena. This mechanism could be used to link actin polymerisation to the membrane in cellular protrusions, such as filopodia.

Estudo das propriedades mecânicas das células de músculo liso vascular em situações fisiológicas e patológicas / Study of the mechanical properties of vascular smooth muscle cells under physiological and pathological situations

Carla Luana Dinardo

02 December 2015

Introdução: As células do músculo liso vascular (CMLV) são quiescentes nos vasos adultos, com baixa capacidade de migração e de secreção de matriz extracelular, caracterizando fenótipo contrátil. Evidências apontam para a heterogeneidade fenotípica das CMLV ao longo da árvore arterial: há distribuição heterogênea de doenças e de resposta a determinadas drogas nos diferentes vasos, além de variabilidade de expressão dos genes de proteínas contráteis de músculo liso entre eles. O papel das CMLV, em fase adulta, é classicamente descrito como restrito à regulação do tônus de pequenos vasos, sendo insignificante a contribuição da mecânica das CMLV para a complacência das artérias elásticas. Existe a hipótese de que a viscoelasticidade das CMLV contribua para a mecânica final das artérias, sendo o enrijecimento dessas células associado à rigidez arterial. Objetivo: Estudar a variabilidade das propriedades mecânicas e de expressão proteica das CMLV, ao longo da árvore arterial, buscando identificar moduladores regionais para esse fenótipo. Avaliar se situações clínicas sabidamente associadas à rigidez arterial (envelhecimento, sexo feminino pós-menopausa, ancestralidade genética africana, diabetes mellitus e tabagismo) cursam com enrijecimento de CMLV. Métodos: 1) Estudou-se a composição e a organização da camada média de diferentes artérias. As CMLV desses vasos foram avaliadas quanto à viscoelasticidade de citoplasma (G), por meio do ensaio de Citometria Magnético Ótica de Oscilação e, quanto à expressão proteica global, usando cromatografia multidimensional e espectrometria de massas em tandem de alta resolução (Proteômica Shotgun). Os dados mecânicos obtidos foram correlacionados com as características da matriz extracelular (MEC) dos vasos de origem (porcentagem de elastina e quantidade de MEC). Em paralelo, foi realizado experimento de estiramento cíclico (10%/1Hz) das CMLV das diferentes artérias por 24 e 48h, seguido pela mensuração de rigidez de citoplasma. 2) Foram isoladas as CMLV de fragmentos de artéria mamária de 80 pacientes submetidos à cirurgia de revascularização do miocárdio, células essas que foram avaliadas quanto à viscoelasticidade de citoplasma (G, G\' e G\'\'). Elaborou-se modelo estatístico para avaliar se as variáveis clínicas idade, sexo feminino, ancestralidade africana, tabagismo e diabetes mellitus estavam associadas a alterações de mecânica celular. Resultados: 1) A viscoelasticidade das CMLV variou significativamente entre as artérias. As CMLV provenientes de artérias distais (artérias femoral e renal) mostraram-se significativamente mais rígidas que as CMLV de aorta torácica (p < 0,001). Identificou-se correlação negativa entre rigidez de CMLV e quantidade de MEC / elastina na camada média vascular. O regime de estiramento cíclico por 48h reduziu globalmente a rigidez das CMLV. As CMLV provenientes da aorta torácica expressaram maior quantidade de proteínas relacionadas com a estrutura e a organização do citoesqueleto em relação às CMLV da artéria femoral. 2) Constatou-se variabilidade interindividual de viscoelasticidade de CMLV e associação entre tabagismo e sexo feminino com enrijecimento de CMLV. Conclusões: As CMLV são heterogêneas quanto às propriedades mecânicas, à organização do citoesqueleto e à expressão proteica ao longo da árvore arterial, reforçando o conceito de plasticidade fenotípica das CMLV. A mecânica das CMLV é modulada pelas características da MEC e pela tensão circunferencial cíclica aplicada às paredes vasculares pelo fluxo sanguíneo. Mulheres pós-menopausa e tabagistas exibem enrijecimento de CMLV, sendo esse fato um provável contribuinte para a rigidez arterial associada a essas condições e um possível alvo terapêutico a ser avaliado futuramente / Rational: Vascular smooth muscle cells (VSMC) lose their ability to migrate and secrete extracellular matrix (ECM) with the end of vascular development, condition known as contractile phenotype and reversible in the presence of vascular injury. There is evidence of heterogeneity of VSMC phenotype along arterial tree, as the distribution of diseases (atherosclerosis) and the response to drugs vary between different vessels, as well as the expression of smooth muscle-contractile protein genes. The role played by VSMC mechanics on determining large arteries\' compliance was always considered irrelevant. It has been hypothesized that the VSMC mechanical properties are important for vascular mechanics, especially in the pathological scenario, where VSMC stiffening may be associated with arterial rigidity. Goals: Study the variation of VSMC mechanics and protein expression along arterial tree, identifying regional modulators of this phenotype. Evaluate if clinical situations associated with arterial rigidity (ageing, post-menopausal women, African ancestry, diabetes mellitus and smoking) concur with VSMC stiffening. Methods: 1) Different arteries were studied in terms of composition and organization of their media layer. VSMC isolated from these arteries were evaluated regarding cytoplasm viscoelasticity, measured using Optical Magnetic Twisting Cytometry Assay (OMTC), and protein expression, using two-dimensional liquid chromatography and tandem mass spectrometry (Shotgun Proteomics). Mechanical data were correlated with ECM characteristics (percentage of elastin and ECM amount) of the vessels of origin. In parallel, VSMC of different arteries were subjected to cyclic stretching (10%/1Hz) during 24 and 48h, followed by the measurement of their cytoplasm rigidity. 2) VSMC were isolated from fragments of mammary artery of 80 patients subjected to coronary bypass surgery and evaluated regarding their viscoelasticity (G, G\' e G\'\'). A statistic model was elaborated to address if the clinical variables age, female sex, African ancestry, smoking and diabetes mellitus were associated with changes of VSMC mechanics. Results: 1) VSMC viscoelasticity varied significantly amongst the studied arteries. VSMC from heart-distant arteries (femoral and renal arteries) were stiffer than VSMC from thoracic aorta (p < 0,001). There was a negative correlation between VSMC rigidity and the amount of ECM / percentage of elastin within the media layer. 48h-cyclic stretching was associated with a global reduction of VSMC rigidity. VSMC of thoracic aorta expressed significantly more proteins associated with cytoskeleton structure and organization than VSMC of femoral artery. 2) There was a significant inter-individual variation of VSMC viscoelasticity. Smoking and female sex were associated with VSMC stiffening. Conclusion: VSMC mechanics, cytoskeleton organization and protein expression are heterogeneous along arterial tree. VSMC mechanical properties are modulated by ECM characteristics and by regional mechanical forces. This reinforces the concept of phenotypic heterogeneity of VSMC. Post-menopausal women and smokers exhibit stiffer VSMC, representing an important factor for the understanding of the arterial rigidity associated with these conditions and also a possible future therapeutic target

Artérias

Citoesqueleto

Citoesqueleto de actina

Músculo liso

Proteômica

Rigidez vascular

Tabagismo

Actin cytoskeleton

Arteries

Cytoskeleton

Proteomics

Smoking

Smooth muscle

Vascular stiffness