Focal Adhesion Maturation Research Articles

A unique role for clathrin light chain A in cell spreading and migration.

Clathrin heavy chain is the structural component of the clathrin triskelion, but unique functions for the two distinct and highly conserved clathrin light chains (CLCa and CLCb, also known as CLTA and CLTB, respectively) have been elusive. Here, we show that following detachment and replating, CLCa is uniquely responsible for promoting efficient cell spreading and migration. Selective depletion of CLCa, but not of CLCb, reduced the initial phase of isotropic spreading of HeLa, H1299 and HEK293 cells by 60-80% compared to siRNA controls, and wound closure and motility by ∼50%. Surface levels of β1-integrins were unaffected by CLCa depletion. However, CLCa was required for effective targeting of FAK (also known as PTK2) and paxillin to the adherent surface of spreading cells, for integrin-mediated activation of Src, FAK and paxillin, and for maturation of focal adhesions, but not their microtubule-based turnover. Depletion of CLCa also blocked the interaction of clathrin with the nucleation-promoting factor WAVE complex, and altered actin distribution. Furthermore, preferential recruitment of CLCa to budding protrusions was also observed. These results comprise the first identification of CLCa-specific functions, with implications for normal and neoplastic integrin-based signaling and cell migration.

Unique arrangement of bone matrix orthogonal to osteoblast alignment controlled by Tspan11-mediated focal adhesion assembly

During tissue construction, cells coordinate extracellular matrix (ECM) assembly depending on the cellular arrangement. The traditional understanding of the relationship between the ECM and cells is limited to the orientation-matched interaction between them. Indeed, it is commonly accepted that the bone matrix (collagen/apatite) is formed along osteoblast orientation. Nonetheless, our recent findings are contrary to the above theory; osteoblasts on nanogrooves organize formation of the bone matrix perpendicular to cell orientation. However, the precise molecular mechanisms underlying the orthogonal organization of bone matrix are still unknown. Here, we show that mature fibrillar focal adhesions (FAs) facilitate the perpendicular arrangement between cells and bone matrix. The osteoblasts aligned along nanogrooves expressed highly mature fibrillar FAs mediated by integrin clustering. Microarray analysis revealed that Tspan11, a member of the transmembrane tetraspanin protein family, was upregulated in cells on the nanogrooved surface compared with that in cells on isotropic, flat, or rough surfaces. Tspan11 silencing significantly disrupted osteoblast alignment and further construction of aligned bone matrix orthogonal to cell orientation. Our results demonstrate that the unique bone matrix formation orthogonal to cell alignment is facilitated by FA maturation. To the best of our knowledge, this report is the first to show that FA assembly mediated by Tspan11 determines the direction of bone matrix organization.

OR34-2 SREBP1 Drives KRT80-Dependent Cytoskeletal Changes and Invasive Behaviour in Endocrine-Resistant ERα Breast Cancer

About one third of oestrogen receptor alpha breast cancer (ERα BC) patients progress to invasive metastatic disease despite targeted endocrine therapies1. Our previous study showed how breast cancer cells developing resistance to aromatase inhibitors (AI) endogenously trigger cholesterol biosynthesis potentially through activation of sterol regulatory element binding protein 1 (SREBP1) to promote sustained oestrogen independent, ERα activation2. Tumour cells are phenotypically characterized by an aberrant architecture and, although this feature is associated with cell migration and invasion, the mechanisms underlying the cytoskeletal reorganization are still poorly understood. In this study, we used breast cancer models to investigate the relationship between acquisition of drug resistance and invasive potential. We showed that cells acquiring resistance to AI undergo active cytoskeleton re-organisation via Keratin 80 (KRT80) and F-Actin remodelling. This process is driven by epigenetic reprogramming at the type II keratin locus leading to KRT80 upregulation. Chromatin Immunoprecipitation coupled with Next Generation Sequencing (ChIP-seq) revealed that reprogramming is dependent on de novo SREBP1 binding to a single enhancer that is activated upon chronic AI treatment. AI-treated patients’ samples are characterized by KRT80 cytoskeletal re-organization and an increased number of KRT80 positive cells at relapse (seventy-five human breast specimens and ten metastatic lymph nodes were selected for immunostaining with the Trust Tissue Bank approval). Using confocal microscopy imaging we found that KRT80 activation and redeployment led to increased F-actin deposition and increased focal adhesion. Additionally, results from 3D organoids invasion assay showed KRT80 manipulation directly contributed to changes in cellular stiffness and invasive potential. Intriguingly, radiological exam using shear wave elasticity imaging performed on twenty prospectively recruited cancer patients confirmed that KRT80 levels correlate with stiffer tumours in vivo. Our data strongly suggested that therapy plays a direct role in shaping the biophysical properties and invasive potential of cancer cells, by inducing epigenetic rearrangements leading to KRT80 upregulation and concomitant cytoskeletal reorganization. We also described an unexpected role for intermediate filaments in promoting cancer cell invasion by showing for the first time that KRT80 promotes actin fibre formation as well as focal adhesion maturation and lamellipodia formation. The link between epigenetic and cytoskeleton reprogramming offers an intriguing axis for drug development and biomarker discovery, especially within the goal of preventing metastatic invasion in BC patients.

Unveiling the Mechanotransduction Mechanism of Substrate Stiffness‐modulated Cancer Cell Motility via ROCK1 and ROCK2 Differentially Regulated Manner

In addition to soluble factors and stromal cells, the mechanical properties of extracellular matrix (ECM) are considered to be an important component of tumor microenvironment. In particular, substrate stiffness is a mechanical characteristic of the ECM by which certain anchorage cells sense and respond to a variety of cellular behaviors. At the same time, clinical studies have observed that substrate stiffness was increased during tumorigenesis, which could promote tumor malignant transformation and metastasis. However, the biomechanical behavior of tumor cells and the underlying mechanotransduction pathways remain unclear. Here, using stiffness‐regulable polyacrylamide (PAA) substrates to simulate the tissue stiffness at different progress stages of breast cancer in vitro, we found that moderate substrate stiffness induced the emergence of malignant phenotypes and further unregulated breast cancer cell motility. Subcellular structure observation showed that moderate substrate stiffness promote the formation of leading‐edge protrusion by accelerating focal adhesion maturation and polarizing intracellular traction force distribution. Moreover, the substrate stiffness directly activated integrin β1 and focal adhesion kinase (FAK), which accelerate focal adhesion (FA) maturation and induce the downstream cascades of intracellular signals of the RhoA/ROCK pathway. Interestingly, the differential regulatory mechanism between two ROCK isoforms (ROCK1 and ROCK2) in cell motility and mechanotransduction was clearly identified. ROCK1 phosphorylated the myosin‐regulatory light chain (MRLC) and facilitated the generation of traction force, while ROCK2 phosphorylated cofilin and regulated the cytoskeletal remodeling by suppressing F‐actin depolymerization. The ROCK isoforms differentially regulated the pathways of RhoA/ROCK1/p‐MLC and RhoA/ROCK2/p‐cofilin in a coordinate fashion to modulate breast cancer cell motility in a substrate stiffness‐dependent manner via integrin β1‐activated FAK signaling. Our findings provide new insights into the mechanisms of matrix mechanical property‐induced cancer cell migration and malignant behaviors. Taming these physical forces by implanting scaffolds with specific stiffness or by inhibiting specific ROCK isoforms could have potential implications for improving therapeutic outcomes in cancer.Support or Funding InformationThis work was supported, in part or in whole, by the National Natural Science Foundation of China (11772088, 31470906, 31700811, 11802056, and 31800780).This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

Nanoneedle-Mediated Stimulation of Cell Mechanotransduction Machinery.

Biomaterial substrates can be engineered to present topographical signals to cells which, through interactions between the material and active components of the cell membrane, regulate key cellular processes and guide cell fate decisions. However, targeting mechanoresponsive elements that reside within the intracellular domain is a concept that has only recently emerged. Here, we show that mesoporous silicon nanoneedle arrays interact simultaneously with the cell membrane, cytoskeleton, and nucleus of primary human cells, generating distinct responses at each of these cellular compartments. Specifically, nanoneedles inhibit focal adhesion maturation at the membrane, reduce tension in the cytoskeleton, and lead to remodeling of the nuclear envelope at sites of impingement. The combined changes in actin cytoskeleton assembly, expression and segregation of the nuclear lamina, and localization of Yes-associated protein (YAP) correlate differently from what is canonically observed upon stimulation at the cell membrane, revealing that biophysical cues directed to the intracellular space can generate heretofore unobserved mechanosensory responses. These findings highlight the ability of nanoneedles to study and direct the phenotype of large cell populations simultaneously, through biophysical interactions with multiple mechanoresponsive components.

ROCK isoforms differentially modulate cancer cell motility by mechanosensing the substrate stiffness

Tumors are characterized by extracellular matrix (ECM) remodeling and stiffening. The importance of ECM stiffness in cancer is well known. However, the biomechanical behavior of tumor cells and the underlying mechanotransduction pathways remain unclear. Here, we used polyacrylamide (PAA) substrates to simulate tissue stiffness at different progress stages of breast cancer in vitro, and we observed that moderate substrate stiffness promoted breast cancer cell motility. The substrate stiffness directly activated integrin β1 and focal adhesion kinase (FAK), which accelerate focal adhesion (FA) maturation and induce the downstream cascades of intracellular signals of the RhoA/ROCK pathway. Interestingly, the differential regulatory mechanism between two ROCK isoforms (ROCK1 and ROCK2) in cell motility and mechanotransduction was clearly identified. ROCK1 phosphorylated the myosin regulatory light chain (MRLC) and facilitated the generation of traction force, while ROCK2 phosphorylated cofilin and regulated the cytoskeletal remodeling by suppressing F-actin depolymerization. The ROCK isoforms differentially regulated the pathways of RhoA/ROCK1/p-MLC and RhoA/ROCK2/p-cofilin in a coordinate fashion to modulate breast cancer cell motility in a substrate stiffness-dependent manner through integrin β1-activated FAK signaling. Our findings provide new insights into the mechanisms of matrix mechanical property-induced cancer cell migration and malignant behaviors. Statement of significanceHere, we examined the relationship between substrate stiffness and tumor cellular motility by using polyacrylamide (PAA) substrates to simulate the stages in vivo of breast cancer. The results elucidated the different regulatory roles between the two ROCK isoforms in cell motility and demonstrated that stiff substrate (38 kPa) mediated RhoA/ROCK1/p-MLC and RhoA/ROCK2/p-cofilin pathways through integrin β1-FAK activation and eventually promoted directional migration. Our discoveries would have significant implications in the understanding of the interaction between cancer cells and tumor microenvironments, and hence, it might provide new insights into the metastasis inhibition, which could be an adjuvant way of cancer therapy.

YAP and TAZ limit cytoskeletal and focal adhesion maturation to enable persistent cell motility.

Cell migration initiates by traction generation through reciprocal actomyosin tension and focal adhesion reinforcement, but continued motility requires adaptive cytoskeletal remodeling and adhesion release. Here, we asked whether de novo gene expression contributes to this cytoskeletal feedback. We found that global inhibition of transcription or translation does not impair initial cell polarization or migration initiation, but causes eventual migratory arrest through excessive cytoskeletal tension and over-maturation of focal adhesions, tethering cells to their matrix. The transcriptional coactivators YAP and TAZ mediate this feedback response, modulating cell mechanics by limiting cytoskeletal and focal adhesion maturation to enable persistent cell motility and 3D vasculogenesis. Motile arrest after YAP/TAZ ablation was partially rescued by depletion of the YAP/TAZ-dependent myosin phosphatase regulator, NUAK2, or by inhibition of Rho-ROCK-myosin II. Together, these data establish a transcriptional feedback axis necessary to maintain a responsive cytoskeletal equilibrium and persistent migration.

Mechanical Responses of Cancer Cells to Different Matrices Measured by AFM and FRET

Integrin-based focal adhesions matured at the front of the migrating cells and dissembled at the retracting edge of cells. In the formation, maturation and disassembly of focal adhesions, talin play an import role as a mediator between mechanosensitive membrane protein, integrin, and actin cytoskeleton. It is known that talin undergo conformational changes when they are stretched with higher force. Vinculin binding sites and actin binding domains is known to be exposed when talin are stretched. Matrix can impact cellular functions, such as cell growth and migration. However, how the physical properties of cancer cells change with the extracellular matrix remains to be an open question. Here, we measured the rigidities of cancer cells at different matrix using AFM and force transduction of cancer cells using a new Forster resonance energy transfer (FRET) tension sensor. Measurements the force changes on talin were conducted in normal cells (MCF10A), non-invasive cancerous cell (MCF7), and invasive cancerous human breast cells (MDA-MB-231). Using atomic force microscopy (AFM), rigidity-based mechanical properties of these three different cell lines under six different substrate stiffnesses are measured and quantified. Magnetic tweezers are used to apply force directly to integrins at focal adhesions. The correlation between the mechanical properties and forces on talin which are showed in our data reveal the different mechanisms adopted by normal and cancerous human breast cells. Our results indicate that the response of cancer cells to matrix is significantly different from that of normal cells, which provide an insight about the properties of cancer cells during the metastasis.

EGFR Activation Enables Increased Integrin Forces and Organization of Mature Focal Adhesions

EGFR Activation Enables Increased Integrin Forces and Organization of Mature Focal Adhesions

ARP3 Controls the Podocyte Architecture at the Kidney Filtration Barrier

SummaryPodocytes, highly specialized epithelial cells, build the outer part of the kidney filtration barrier and withstand high mechanical forces through a complex network of cellular protrusions. Here, we show that Arp2/3-dependent actin polymerization controls actomyosin contractility and focal adhesion maturation of podocyte protrusions and thereby regulates formation, maintenance, and capacity to adapt to mechanical requirements of the filtration barrier. We find that N-WASP-Arp2/3 define the development of complex arborized podocyte protrusions in vitro and in vivo. Loss of dendritic actin networks results in a pronounced activation of the actomyosin cytoskeleton and the generation of over-maturated but less efficient adhesion, leading to detachment of podocytes. Our data provide a model to explain podocyte protrusion morphology and their mechanical stability based on a tripartite relationship between actin polymerization, contractility, and adhesion.

P6 - Redox Modification of the Cytoskeleton During Cell Adhesion and Migration

Actin cytoskeleton assembly and organization are modulated by reactive oxygen species and the cellular redox environment. Focal adhesions link the cytoskeleton to the extracellular matrix and play an important role in growth and migration of vascular smooth muscle cells. We have previously shown that NADPH oxidase Nox4, a H2O2-producing enzyme, and its binding partner, polymerase delta interacting protein 2 (Poldip2), regulate turnover of focal adhesions. Downstream targets of Nox4 include Hic-5 and Hsp27, as well as the small GTPase, Rho A. Activation of Smad signaling by TGFp, which is known to strengthen focal adhesions, is Nox4-dependent, as is upregulation of Hsp27 and Hic-5 by TGFp. Similarly, overexpression of Poldip2 activates RhoA to prevent focal adhesion dissolution, while dominant-negative RhoA reverses the effects of Nox4/Poldip2 on focal adhesions. More recently, we discovered that H2O2 levels increase during integrin-mediated cell attachment due to activation of NOX4. Attachment induces F-actin oxidation by sulfenylation, and depletion of Poldip2 or NOX4 using siRNA, or scavenging of endogenous H2O2 with catalase, inhibits adhesion-induced F-actin oxidation. Of importance, the binding of F-actin to vinculin, a protein present in focal adhesion complexes that regulates focal adhesion maturation, is inhibited after transfection of an oxidation-resistant actin mutant. Silencing of Poldip2 or NOX4 also impairs actin-vinculin interaction. Taken together, our work has identified a major role for Poldip2/Nox4 in cytoskeletal organization, focal adhesion turnover and smooth muscle cell migration.

NOX4 (NADPH Oxidase 4) and Poldip2 (Polymerase δ-Interacting Protein 2) Induce Filamentous Actin Oxidation and Promote Its Interaction With Vinculin During Integrin-Mediated Cell Adhesion.

Objective- Actin cytoskeleton assembly and organization, as a result of focal adhesion (FA) formation during cell adhesion, are dependent on reactive oxygen species and the cellular redox environment. Poldip2 (polymerase δ-interacting protein 2), a novel regulator of NOX4 (NADPH oxidase 4), plays a significant role in reactive oxygen species production and cytoskeletal remodeling. Thus, we hypothesized that endogenous reactive oxygen species derived from Poldip2/NOX4 contribute to redox regulation of actin and cytoskeleton assembly during integrin-mediated cell adhesion. Approach and Results- Using vascular smooth muscle cells, we verified that hydrogen peroxide (H2O2) levels increase during integrin-mediated cell attachment as a result of activation of NOX4. Filamentous actin (F-actin) was oxidized by sulfenylation during cell attachment, with a peak at 3 hours (0.80±0.04 versus 0.08±0.13 arbitrary units at time zero), which was enhanced by overexpression of Poldip2. Depletion of Poldip2 or NOX4 using siRNA, or scavenging of endogenous H2O2 with catalase, inhibited F-actin oxidation by 78±26%, 99±1%, and 98±1%, respectively. To determine the consequence of F-actin oxidation, we examined the binding of F-actin to vinculin, a protein involved in FA complexes that regulates FA maturation. Vinculin binding during cell adhesion as well as migration capacity were inhibited after transfection with actin containing 2 oxidation-resistant point mutations (C272A and C374A). Silencing of Poldip2 or NOX4 also impaired actin-vinculin interaction, which disturbed maturation of FAs and inhibited cell migration. Conclusions- These results suggest that integrin engagement during cell attachment activates Poldip2/Nox4 to oxidize actin, which modulates FA assembly.

Fenofibrate Reduces the Asthma-Related Fibroblast-To-Myofibroblast Transition by TGF-Β/Smad2/3 Signaling Attenuation and Connexin 43-Dependent Phenotype Destabilization

The activation of human bronchial fibroblasts by transforming growth factor-β1 (TGF-β1) leads to the formation of highly contractile myofibroblasts in the process of the fibroblast–myofibroblast transition (FMT). This process is crucial for subepithelial fibrosis and bronchial wall remodeling in asthma. However, this process evades current therapeutic asthma treatment strategies. Since our previous studies showed the attenuation of the TGF-β1-induced FMT in response to lipid-lowering agents (e.g., statins), we were interested to see whether a corresponding effect could be obtained upon administration of hypolipidemic agents. In this study, we investigated the effect of fenofibrate on FMT efficiency in populations of bronchial fibroblasts derived from asthmatic patients. Fenofibrate exerted a dose-dependent inhibitory effect on the FMT, even though it did not efficiently affect the expression of α-smooth muscle actin (α-SMA; marker of myofibroblasts); however, it considerably reduced its incorporation into stress fibers through connexin 43 regulation. This effect was accompanied by disturbances in the actin cytoskeleton architecture, impairments in the maturation of focal adhesions, and the fenofibrate-induced deactivation of TGF-β1/Smad2/3 signaling. These data suggest that fenofibrate interferes with myofibroblastic differentiation during asthma-related subepithelial fibrosis. The data indicate the potential application of fenofibrate in the therapy and prevention of bronchial remodeling during the asthmatic process.

3081 - Geometrical Control of Stem Cell Fate by Self-Organization of Cytoskeleton

The commitment of mesenchymal stem cells (MSCs) differentiation lineage can be controlled by physical signals, such as geometric cues of extracellular matrix (ECM). It is well known that the physical stimuli drive focal adhesions (FAs) maturation, actin polymerization and stress fiber formation, yet how cell shape controls MSC differentiation through the FA-mediated signals or FA-cytoskeleton organization remains largely unknown. To determine how geometric cues direct MSC lineage commitment, a technique of microcontact printing is performed to shape MSCs. We find that the geometric cues control osteogenic-adipogenic switch in MSC lineage commitment through regulating the organization of FAs, actin filaments, intermediate filaments, microtubules and nucleus, which further influences the distribution of cellular visco-elasticity and traction forces. Our data demonstrate a role for FA signaling in dictating MSC differentiation regulated by geometric cues.

Replacing nonmuscle myosin 2A with myosin 2C1 permits gastrulation but not placenta vascular development in mice.

Three paralogues of nonmuscle myosin 2 (NM 2A, 2B, and 2C) are expressed in mammals, and the heavy chains are the products of three different genes (Myh9, Myh10, and Myh14, respectively). NM 2A and 2B are essential for mouse development, while 2C is not. Studies on NM 2C are limited and the in vivo function of this paralogue is not clear. Using homologous recombination, cDNA encoding nonmuscle myosin heavy chain 2C1 fused with GFP was introduced into the first coding exon of Myh9, replacing NM 2A expression with NM 2C1 expression in mice. In contrast to A–/A– embryos, which die by embryonic day (E) 6.5, AC1*gfp/AC1*gfp embryos survive through E8.5, demonstrating that NM 2C1 can support mouse development beyond gastrulation. At E9.5 and E10.5, however, AC1*gfp/AC1*gfp embryos are developmentally delayed, with abnormalities in placental vascular formation. The defect in vascular formation is confirmed in allantois explants from AC1*gfp/AC1*gfp embryos. Thus, NM 2C1 cannot support normal placental vascular formation. In addition, AC1*gfp/AC1*gfp mouse embryonic fibroblasts (MEFs) migrate rapidly but with impaired persistence and develop smaller, less mature focal adhesions than A+/A+ MEFs. This is attributed to enhanced NM 2C1 actomyosin stability and different NM 2C1 subcellular localization than in NM 2A.

A micron-scale surface topography design reducing cell adhesion to implanted materials

The micron-scale surface topography of implanted materials represents a complementary pathway, independent of the material biochemical properties, regulating the process of biological recognition by cells which mediate the inflammatory response to foreign bodies. Here we explore a rational design of surface modifications in micron range to optimize a topography comprised of a symmetrical array of hexagonal pits interfering with focal adhesion establishment and maturation. When implemented on silicones and hydrogels in vitro, the anti-adhesive topography significantly reduces the adhesion of macrophages and fibroblasts and their activation toward effectors of fibrosis. In addition, long-term interaction of the cells with anti-adhesive topographies markedly hampers cell proliferation, correlating the physical inhibition of adhesion and complete spreading with the natural progress of the cell cycle. This solution for reduction in cell adhesion can be directly integrated on the outer surface of silicone implants, as well as an additive protective conformal microstructured biocellulose layer for materials that cannot be directly microstructured. Moreover, the original geometry imposed during manufacturing of the microstructured biocellulose membranes are fully retained upon in vivo exposure, suggesting a long lasting performance of these topographical features after implantation.

Abstract 1315: Biophysics of polyploidal cancer cells in an aging stroma

Abstract Senescence is a potent tumor-suppressive mechanism that irreversibly arrests the growth of damaged cells. However, senescent cells that accumulate in tissues eventually develop a senescence-associated secretory phenotype (SASP) that alters the microenvironment to promote cancer. Paracrine factors in the SASP may also contribute to the formation of rare giant polyploidal cancer cells (GPCCs). A single-cell mechanical approach was used to profile cytoskeletal and nuclear mechanics, morphology, motility, and adhesion for breast cancer cells treated with conditioned media from senescent fibroblasts. Our study showed that a small but significant population of MDA-MB-231 breast cancer cells (less than 5%) treated with conditioned media from senescent LF-1 fibroblasts develop an enlarged morphology, chromosomal instability, and polyploidy, a phenotype associated with GPCCs. Although GPCCs are highly invasive and chemoresistant, little is known about their biophysical properties. First, we developed a method for identifying the small subpopulation of GPCCs in a heterogeneous population of cancer cells based on increased nuclear area and confirmed that GPCCs are more resistant to paclitaxel than normal-size MDA-MB-231 cells (NCCs). We then compared critical biophysical properties of NCCs and GPCCs, including cytoskeletal and nuclear mechanics, cell and nuclear morphology, motility, and adhesion. Cells were stained for cytoskeletal proteins actin, tubulin, and vinculin. Cytoskeletal organization was dramatically altered in GPCCs compared to NCCs. GPCCs displayed more disorganized microtubule structure, dense actin stress fibers, and mature focal adhesions. Intracellular particle tracking microrheology was used to measure cytoskeletal and nuclear mechanics. These studies demonstrated that although GPCCs are thought to be highly invasive cancer cells, they are inherently stiffer than NCCs, in terms of both their cytoskeletal and nuclear mechanics. This was surprising since more invasive cancer cells are often more compliant than less invasive cancer cells. This result may be in part to the ability for GPCCs to behave like activated stromal cells that stiffen in the tumor; we confirmed that GPCCs display similar adhesive behavior as activated stromal cells. To determine how mechanics correlates with cell migration, we used time-lapse nuclear tracking to measure cell motility. The average cell speed was higher for NCCs than for GPCCs; however, GPCCs moved longer distances over time because their motion was more directional. These findings highlight the unusual biophysical behavior of GPCCs. To develop pharmacologic tools that target GPCCs, it is imperative to understand their biophysical properties. Citation Format: Michelle Dawson, Botai Xuan, Deepraj Ghosh. Biophysics of polyploidal cancer cells in an aging stroma [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 1315.

Engineering subcellular-patterned biointerfaces to regulate the surface wetting of multicellular spheroids

Studying the wetting behaviors of multicellular spheroids is crucial in the fields of embryo implantation, cancer propagation, and tissue repair. Existing strategies for controlling the wetting of multicellular spheroids mainly focus on surface chemistry and substrate rigidity. Although topography is another important feature in the biological micro-environment, its effect on multicellular spheroid wetting has seldom been explored. In this study, the influence of topography on the surface wetting of multicellular spheroids was investigated using subcellularpatterned opal films with controllable colloidal particle diameters (from 200 to 1,500 nm). The wetting of hepatoma carcinoma cellular (Hep G2) spheroids was impaired on opal films compared with that on flat substrates, and the wetting rate decreased as colloidal particle diameter increased. The decrement reached 48.5% when the colloidal particle diameter was 1,500 nm. The subcellular-patterned topography in opal films drastically reduced the cellular mobility in precursor films, especially the frontier cells in the leading edge. The frontier cells failed to form mature focal adhesions and stress fibers on micro-patterned opal films. This was due to gaps between colloidal particles leaving adhesion vacancies, causing weak cell–substrate adhesion and consequent retarded migration of Hep G2 spheroids. Our study manifests the inhibiting effects of subcellular-patterned topography on the wetting behaviors of multicellular spheroids, providing new insight into tissue wetting-associated treatments and biomaterial design.

Poldip2 Affects Collagen I Accumulation by Regulating the Expression of Zyxin in Vascular Smooth Muscle Cells

Objectives: Polymerase delta interacting protein 2 (Poldip2) has previously been implicated in migration, proliferation and extracellular matrix (ECM) production in vascular smooth muscle cells. Thereby, regulation of Poldip2 protein expression is suggested to prevent the development and progression of diabetic macroangiopathy. We recently reported that Poldip2+/- mouse aortic smooth muscle cells (MASMs) exhibit higher β1-Integrin expression and activity of the PI3K/Akt/mTOR signaling pathway, leading to increased ECM protein synthesis. We further investigated the mechanism of Podlip2 in regulating the β1-Integrin expression. Approach and Results: Cell adhesion and cell signaling, below the focal adhesion, were investigated. Poldip2+/- MASMs (HET) showed both quicker cell attachment and detachment than Poldip2+/+ MASMs (WT). Paxillin, one of the components of focal adhesion, is expressed in all areas (from front to back) of lamellipodia in WT, on the other hand HET express the Paxillin only front area, which may induce weaker cell adhesion. The mature focal adhesion marker, Zyxin, expression is decreased in HET significantly. Intriguingly, the activity of RhoA is increased in HET and induced MRTF-A translocation from cytosol to nacreous. Conclusions: It is revealed that Poldip2 is positive regulator of Zyxin. HET has weak cell adhesion, and may induce Poldip2+/- MASMs exhibit higher β1-Integrin expression as a compensation against immature focal adhesion. Thus PI3K/Akt/mTOR signaling pathway is activated, leading to increased ECM protein synthesis. Translocation of MRTF-A from cytosol to the nucleus, may contribute to bind to transcriptional factor for Collagen I. This phenomenon is suggested as one more pathway, which Collagen I accumulates in HET. These findings have important implications for atherosclerotic vascular diseases such as diabetic macroangiopathy in which ECM accumulation plays a role. Disclosure M. Fujii: None. N. Sonoda: None. M. Okamoto: None. H. Morinaga: None. Y. Ogawa: Research Support; Self; AstraZeneca. Advisory Panel; Self; Gilead Sciences, Inc.. Research Support; Self; Japan Agency for Medical Research and Development, Japan Society for the Promotion of Science, Mitsubishi Tanabe Pharma Corporation, Mochida Pharmaceutical Co., Ltd., Sumitomo Dainippon Pharma Co., Ltd.. K. Griendling: None.

In vitro response of mesenchymal stem cells to biomimetic hydroxyapatite substrates: A new strategy to assess the effect of ion exchange

Biomaterials can interact with cells directly, that is, by direct contact of the cells with the material surface, or indirectly, through soluble species that can be released to or uptaken from the surrounding fluids. However, it is difficult to characterise the relevance of this fluid-mediated interaction separately from the topography and composition of the substrate, because they are coupled variables. These fluid-mediated interactions are amplified in the case of highly reactive calcium phosphates (CaPs) such as biomimetic calcium deficient hydroxyapatite (CDHA), particularly in static in vitro cultures. The present work proposes a strategy to decouple the effect of ion exchange from topographical features by adjusting the volume ratio between the cell culture medium and biomaterial (VCM/VB). Increasing this ratio allowed mitigating the drastic ionic exchanges associated to the compositional changes experienced by the material exposed to the cell culture medium. This strategy was validated using rat mesenchymal stem cells (rMSCs) cultured on CDHA and beta-tricalcium phosphate (β-TCP) discs using different VCM/VB ratios. Whereas in the case of β-TCP the cell response was not affected by this ratio, a significant effect on cell adhesion and proliferation was found for the more reactive CDHA. The ionic exchange, produced by CDHA at low VCM/VB, altered cell adhesion due to the reduced number of focal adhesions, caused cell shrinkage and further rMCSs apoptosis. This was mitigated when using a high VCM/VB, which attenuated the changes of calcium and phosphate concentrations in the cell culture medium, resulting in rMSCs spreading and a viability over time. Moreover, rMSCs showed an earlier expression of osteogenic genes on CDHA compared to sintered β-TCP when extracellular calcium fluctuations were reduced. Statement of SignificanceFluid mediated interactions play a significant role in the bioactivity of calcium phosphates. Ionic exchange is amplified in the case of biomimetic hydroxyapatite, which makes the in vitro characterisation of cell-material interactions especially challenging. The present work proposes a novel and simple strategy to explore the mechanisms of interaction of biomimetic and sintered calcium phosphates with mesenchymal stem cells. The effects of topography and ion exchange are analysed separately by modifying the volume ratio between cell culture medium and biomaterial. High ionic fluctuations interfered in the maturation of focal adhesions, hampering cell adhesion and leading to increased apoptosis and reduced proliferation rate.