Effects of micropatterned curvature on the motility and mechanical properties of airway smooth muscle cells

Geometric features such as size and shape of the microenvironment are known to alter cell behaviors such as growth, differentiation, apoptosis, and migration. Little is known, however, about the effect of curvature on cell behaviors despite that many cells reside in curved space of tubular organs such as the bronchial airways. To address this question, we fabricated micropatterned strips that mimic airway walls with varying curvature. Then, we cultured airway smooth muscle cells (ASMCs) on these strips and investigated the cells’ motility and mechanical properties using time-lapse imaging microscopy and optical magnetic twisting cytometry (OMTC). We found that both motility and mechanical properties of the ASMCs were influenced by the curvature. In particular, when the curvature increased from 0 to 1/150 μm⁻¹, the velocity of cell migration first decreased (0–1/750 μm⁻¹), and then increased (1/750–1/150 μm⁻¹). In contrast, the cell stiffness increased and then decreased. Thus, at the intermediate curvature (1/750 μm⁻¹) the ASMCs were the least motile, but most stiff. The contractility instead decreased consistently as the curvature increased. The level of F-actin, and vinculin expression within the ASMCs appeared to correlate with the contractility and motility, respectively, in relation to the curvature. These results may provide valuable insights to understanding the heterogeneity of airway constrictions in asthma as well as the developing and functioning of other tubular organs and tissue engineering.     

Probe Sensitivity to Cortical versus Intracellular Cytoskeletal Network Stiffness

In development, wound healing, and pathology, cell biomechanical properties are increasingly recognized as being of central importance. To measure these properties, experimental probes of various types have been developed, but how each probe reflects the properties of heterogeneous cell regions has remained obscure. To better understand differences attributable to the probe technology, as well as to define the relative sensitivity of each probe to different cellular structures, here we took a comprehensive approach. We studied two cell types—Schlemm’s canal endothelial cells and mouse embryonic fibroblasts (MEFs)—using four different probe technologies: 1) atomic force microscopy (AFM) with sharp tip, 2) AFM with round tip, 3) optical magnetic twisting cytometry (OMTC), and 4) traction microscopy (TM). Perturbation of Schlemm’s canal cells with dexamethasone treatment, α-actinin overexpression, or RhoA overexpression caused increases in traction reported by TM and stiffness reported by sharp-tip AFM as compared to corresponding controls. By contrast, under these same experimental conditions, stiffness reported by round-tip AFM and by OMTC indicated little change. Knockout (KO) of vimentin in MEFs caused a diminution of traction reported by TM, as well as stiffness reported by sharp-tip and round-tip AFM. However, stiffness reported by OMTC in vimentin-KO MEFs was greater than in wild type. Finite-element analysis demonstrated that this paradoxical OMTC result in vimentin-KO MEFs could be attributed to reduced cell thickness. Our results also suggest that vimentin contributes not only to intracellular network stiffness but also cortex stiffness. Taken together, this evidence suggests that AFM sharp tip and TM emphasize properties of the actin-rich shell of the cell, whereas round-tip AFM and OMTC emphasize those of the noncortical intracellular network.     

TLR4在气道上皮细胞诱导的哮喘气道平滑肌细胞迁移中的作用

目的:探讨Toll样受体4(TLR4)的激活在气道上皮细胞诱导的哮喘气道平滑肌细胞(ASMCs)迁移中的作用。方法:细胞消化法培养原代哮喘ASMCs,TNF-α刺激上皮细胞系RTE细胞收集细胞培养上清液,检测上清液中IL-8和RANTES的含量,改良Boyden趋化小室检测哮喘ASMCs的跨膜迁移,以TLR4抗体作为工具药,观察其在上皮细胞诱导的哮喘ASMCs跨膜迁移中的作用。结果:各TNF-α组培养上清液中IL-8和RANTES水平均显著增高,20 ng/ml组较其他组显著增高(P<0.01)。各组哮喘ASMCs跨膜迁移较正常组均增加(P<0.01);哮喘组和TNF-α+TLR4抗体组哮喘ASMCs跨膜迁移数较TNF-α组显著减少(P<0.01)。TLR4抗体组哮喘ASMCs跨膜迁移数较哮喘组增加(P<0.05)。结论:气道上皮细胞可能通过分泌细胞因子激活哮喘ASMCs表面的TLR4,诱导增强ASMCs的跨膜迁移,在哮喘的气道重构中发挥一定的作用。     

Mechanical programming of arterial smooth muscle cells in health and ageing

Arterial smooth muscle cells (ASMCs), the predominant cell type within the arterial wall, detect and respond to external mechanical forces. These forces can be derived from blood flow (i.e. pressure and stretch) or from the supporting extracellular matrix (i.e. stiffness and topography). The healthy arterial wall is elastic, allowing the artery to change shape in response to changes in blood pressure, a property known as arterial compliance. As we age, the mechanical forces applied to ASMCs change; blood pressure and arterial wall rigidity increase and result in a reduction in arterial compliance. These changes in mechanical environment enhance ASMC contractility and promote disease-associated changes in ASMC phenotype. For mechanical stimuli to programme ASMCs, forces must influence the cell’s load-bearing apparatus, the cytoskeleton. Comprised of an interconnected network of actin filaments, microtubules and intermediate filaments, each cytoskeletal component has distinct mechanical properties that enable ASMCs to respond to changes within the mechanical environment whilst maintaining cell integrity. In this review, we discuss how mechanically driven cytoskeletal reorganisation programmes ASMC function and phenotypic switching.     

血管内皮生长因子及其受体2与哮喘模型大鼠气道平滑肌细胞增殖关系的研究

目的探讨血管内皮生长因子(VEGF)及其受体2(Flk-1)在哮喘大鼠气道平滑肌细胞(ASMC)中表达变化及其对ASMC增殖的影响。方法 SD大鼠18只,随机分为对照组,哮喘模型组和地塞米松干预组各6只,并培养各组气道平滑肌细胞。用免疫组织化学技术检测ASMC增殖细胞核抗原(PCNA)的表达;用RT-PCR及Western blot方法分别检测VEGF和Flk-1mRNA及蛋白质在不同组大鼠ASMC的表达程度。结果(1)哮喘模型组ASMC PCNA表达较对照组和干预组显著增加(P0.05)。(2)哮喘模型组ASMC VEGF164,VEGF188mRNA和VEGF205mRNA的表达较对照组和干预组显著增加(P0.05或P0.01)。(3)哮喘模型组ASMC VEGF及Flk-1蛋白质在大鼠ASMC中的表达较对照组和干预组显著增加(P0.05)。直线相关性分析显示,大鼠ASMC PCNA表达与大鼠ASMC中VEGF205,188,164及Flk-1mRNA表达水平呈正相关(r分别为0.79,0.86,0.83,0.68;P0.05);大鼠ASMC PCNA表达与大鼠ASMC中VEGF及Flk-1蛋白质表达水平也呈正相关(r分别为0.80,0.77;P0.05)。结果 哮喘模型大鼠ASMC中VEGF及其受体Flk-1表达上调,并与气道平滑肌细胞增殖有密切关系。该结果提示VEGF及其受体2可能参与了哮喘气道重建中气道平滑肌细胞增殖的过程。     

TOLL样受体4在哮喘大鼠气道平滑肌细胞增殖、凋亡中的作用

目的:探讨Toll样受体4(TLR4)在哮喘状态下气道平滑肌细胞(ASMCs)增殖、凋亡中的作用.方法:建立哮喘大鼠模型,分离、培养哮喘大鼠气道平滑肌细胞,应用小分子RNA干扰技术、脂质体转染法进行小分子RNA-TLR4的转染、MTT,法检测细胞增殖、TUNNEL法检测细胞凋亡情况、逆转录聚合酶链式反应(RT-PCR)...     

Lipopolysaccharide-induced proliferation and glycolysis in airway smooth muscle cells via activation of Drp1

Abnormal airway smooth muscle cells (ASMCs) proliferation is an important pathological process in airway remodeling contributes to increased mortality in asthma. Mitochondrial dynamics and metabolism have a central role in the maintenance of the cell function. In this study, lipopolysaccharide (LPS)-induced ASMCs proliferative model was used to investigate the effect of mitochondria on the proliferation of ASMCs and the possible mechanism. We used cell and molecular biology to determine the effect of dynamin-related protein 1 (Drp1) on LPS-mediated ASMCs cell cycle progression and glycolysis. The major findings of the current study are as follows: LPS promoted an increased mitochondrial fission and phosphorylation of Drp1 at Ser616 (p-Drp1 Ser616). LPS-induced ASMCs proliferation and cell cycle progression, which was significantly inhibited application of Drp1 RNA interfering. Glycolysis inhibitor 2-deoxyglucose (2-DG) depressed ASMCs proliferative process induced by LPS stimulation. LPS caused mitochondrial metabolism disorders and aerobic glycolysis in a dependent on Drp1 activation. These results indicated that Drp1 may function as a key factor in asthma airway remodeling by mediating ASMC proliferation and cell cycle acceleration through an effect on mitochondrial metabolic disturbance.     

气道平滑肌细胞Ryanodine受体亚型mRNA的表达及其在哮喘中的变化

目的:测定正常大鼠气道平滑肌细胞(ASMCs)中Ryanodine受体(Ryanodine receptor RyR)各亚型mRNA的表达以及在哮喘中的变化.方法:采用胶原酶消化法培养大鼠ASMCs,RT-PCR测定受体各亚型mRNA的表达.卵蛋白致敏并激发大鼠制备慢性哮喘模型,RT-PCR测定各受体mRNA表达水平的变化.结果:大鼠ASMCs中可见RyR1、RyR2和RyR3三种RyR亚型mRNA共表达,扩增片段测序结果与GenBank中登录的大鼠RyR1-3序列完全一致.制备的慢性哮喘模型中,病理切片显示平滑肌层及黏膜层明显增厚,RyR1的表达较对照组有明显的上调P＜0.05.结论:大鼠气道平滑肌细胞中RyR三种亚型共表达,提示存在着复杂的细胞内钙调节机制;并且RyR1在慢性哮喘的发生过程中可能起了一定的作用.     

Ryanodine receptors in muscarinic receptor-mediated bronchoconstriction

Ryanodine receptors (RyRs), intracellular calcium release channels essential for skeletal and cardiac muscle contraction, are also expressed in various types of smooth muscle cells. In particular, recent studies have suggested that in airway smooth muscle cells (ASMCs) provoked by spasmogens, stored calcium release by the cardiac isoform of RyR (RyR2) contributes to the calcium response that leads to airway constriction (bronchoconstriction). Here we report that mouse ASMCs also express the skeletal muscle and brain isoforms of RyRs (RyR1 and RyR3, respectively). In these cells, RyR1 is localized to the periphery near the cell membrane, whereas RyR3 is more centrally localized. Moreover, RyR1 and/or RyR3 in mouse airway smooth muscle also appear to mediate bronchoconstriction caused by the muscarinic receptor agonist carbachol. Inhibiting all RyR isoforms with > or = 200 microM ryanodine attenuated the graded carbachol-induced contractile responses of mouse bronchial rings and calcium responses of ASMCs throughout the range of carbachol used (50 nM to > or = 3 microM). In contrast, inhibiting only RyR1 and RyR3 with 25 microM dantrolene attenuated these responses caused by high (>500 nM) but not by low concentrations of carbachol. These data suggest that, as the stimulation of muscarinic receptor in the airway smooth muscle increases, RyR1 and/or RyR3 also mediate the calcium response and thus bronchoconstriction. Our findings provide new insights into the complex calcium signaling in ASMCs and suggest that RyRs are potential therapeutic targets in bronchospastic disorders such as asthma.     

Focal adhesion kinase stabilizes the cytoskeleton

Focal adhesion kinase (FAK) is a central focal adhesion protein that promotes focal adhesion turnover, but the role of FAK for cell mechanical stability is unknown. We measured the mechanical properties of wild-type (FAKwt), FAK-deficient (FAK−/−), FAK-silenced (siFAK), and siControl mouse embryonic fibroblasts by magnetic tweezer, atomic force microscopy, traction microscopy, and nanoscale particle tracking microrheology. FAK-deficient cells showed lower cell stiffness, reduced adhesion strength, and increased cytoskeletal dynamics compared to wild-type cells. These observations imply a reduced stability of the cytoskeleton in FAK-deficient cells. We attribute the reduced cytoskeletal stability to rho-kinase activation in FAK-deficient cells that suppresses the formation of ordered stress fiber bundles, enhances cortical actin distribution, and reduces cell spreading. In agreement with this interpretation is that cell stiffness and cytoskeletal stability in FAK−/− cells is partially restored to wild-type level after rho-kinase inhibition with Y27632.     

细胞外信号调节激酶活化在慢性支气管哮喘大鼠气道平滑肌细胞增殖中的作用

本文旨在探讨细胞外信号调节激酶（extracellular signal-regulated kinase,ERK）在慢性支气管哮喘大鼠气道平滑肌细胞（airway smooth muscle cells,ASMCs）增殖中的作用。建立慢性哮喘大鼠模型,用ERK激动剂表皮生长因子（epidermal growth factor,EGF）和抑制剂PD98059干预慢性哮喘大鼠ASMCs的培养。采用流式细胞仪、四甲基偶氮唑盐（MTT）法、^3H-thymidine（TdR）掺入法和增殖细胞核抗原（proliferating cell nuclear antigen,PCNA）免疫组织化学法检测ASMCs增殖情况,观察ERK信号通路对ASMCs增殖的影响。RT-PCR和Western blot检测ERK mRNA和ERK1／2、磷酸化ERK1／2（p-ERK1／2）蛋白的表达。与正常对照组ASMCs比较,慢性哮喘组ASMCs的G0/G1期细胞所占比例明显减少,S＋G2／M期细胞所占比例增高;吸光度（A490）值、细胞DNA合成量和PCNA阳性表达量均明显增加,ERK mRNA、ERK1／2蛋白、P-ERK1／2蛋白的表达量以及ERK活化率显著增高。经PD98059干预之后,慢性哮喘组ASMCs的S＋G2／M期细胞所占比例、A490值、细胞DNA合成量和PCNA阳性表达量明显降低,ERK mRNA、ERK1／2蛋白、p-ERK1／2蛋白的表达量以及ERK活化率显著降低。经EGF干预后,慢性哮喘组ASMCs的S＋G2／M期细胞所占比例、A490值、细胞DNA合成量和PCNA阳性表达量进一步增高,而这一作用可以被PD98059抑制。以上结果提示,慢性哮喘大鼠ASMCs内源性增殖活性增加,ERK1／2参与其增殖活性的调控,ERK信号通路在哮喘气道重建的ASMCs增殖调控中具有重要作用。     

Effect of the BMPR-II-SMAD3/MRTF pathway on proliferation and migration of ASMCs and the mechanism in asthma

Background

A variety of smooth muscle-specific genes and proteins, including SMAD3, BMPR-II, and MRTF, are involved in airway remodeling in asthma. As a receptor of bone morphogenetic protein (BMP) signaling, BMPR-II has important roles in airway remodeling in asthma. However, the underlying mechanism of BMPR-II in airway smooth muscle cells (ASMCs) in asthma remains incomplete.

Methods

Wistar rats were intraperitoneally injected with ovalbumin antigen suspension and aluminium hydroxide and, stimulated with ovalbumin nebulized inhalation to constructed asthma model. Primary ASMCs were isolated with collagenase I and identified by testing the α-SMA expression. Quantitative polymerase chain reaction (qPCR) and western blot assay were employed to detect the gene expression. CCK8, Transwell and Fluo-4 A assays were introduced to measure the cell viability, migration and intracellular Ca²⁺. Co-Immunoprecipitation (Co-IP) assay was applied to test the interaction among proteins.

Results

First, we observed significant increases in BMPR-II in asthmatic rat model and ASMCs at both the mRNA and protein levels. Second, we observed that silencing of siBMPR-II inhibited proliferation, migratory capacity and intracellular Ca²⁺ concentration in ASMCs. Furthermore, our study demonstrated that siBMPR-II inhibited the Smad3 expression and overexpression promoted the bioactivity of ASMCs. In addition, this study showed that p-Smad3 could interacted with MRTF and siMRTF inhibits the bioactivity of ASMCs. Finally, our results revealed BMPR-II-SMAD3/MRTF pathway affected the bioactivity of ASMCs.

Conclusions

This study indicates that the BMPR-II-SMAD3/MRTF signaling pathway is involved in the process of ASMCs remodeling, providing novel avenues for the identification of new therapeutic modalities.

     

Salidroside inhibits platelet-derived growth factor–induced proliferation and migration of airway smooth muscle cells

Abnormal proliferation and migration of airway smooth muscle cells (ASMCs) have been found to be important for the airway remodeling during the pathogenesis of asthma. Salidroside a bioactive glucoside that exerts antitumor activity via inhibiting the cell proliferation and migration of cancer cells. The aim of the current study was to evaluate the effects of salidroside on the proliferation and migration of ASMCs. Our results showed that salidroside inhibited the proliferation and migration of ASMCs in response to platelet-derived growth factor (PDGF) stimulation. Salidroside markedly attenuated the PDGF-induced production of matrix metalloproteinase 2 (MMP-2) and MMP-9 in ASMCs. The levels of contractile phenotype markers including smooth muscle α-actin and calponin were reduced in response to PDGF stimulation, which was attenuated by salidroside pretreatment. Salidroside diminished the increase in the expression levels of type I collagen and fibronectin in PDGF-stimulated ASMCs. Furthermore, salidroside blocked the PDGF-induced activation of the nuclear factor-κB (NF-κB) pathway in ASMCs. The results suggested that salidroside functionally regulated the proliferation, migration, phenotype plasticity, and extracellular matrix deposition in PDGF-induced ASMCs and the NF-κB pathway might be implicated in the effects of salidroside on ASMCs induced by PDGF.     

Spatial and temporal coordination of traction forces in one-dimensional cell migration

ABSTRACT

Migration of a fibroblast along a collagen fiber can be regarded as cell locomotion in one-dimension (1D). In this process, a cell protrudes forward, forms a new adhesion, produces traction forces, and releases its rear adhesion in order to advance itself along a path. However, how a cell coordinates its adhesion formation, traction forces, and rear release in 1D migration is unclear. Here, we studied fibroblasts migrating along a line of microposts. We found that when the front of a cell protruded onto a new micropost, the traction force produced at its front increased steadily, but did so without a temporal correlation in the force at its rear. Instead, the force at the front coordinated with a decrease in force at the micropost behind the front. A similar correlation in traction forces also occurred at the rear of a cell, where a decrease in force due to adhesion detachment corresponded to an increase in force at the micropost ahead of the rear. Analysis with a bio-chemo-mechanical model for traction forces and adhesion dynamics indicated that the observed relationship between traction forces at the front and back of a cell is possible only when cellular elasticity is lower than the elasticity of the cellular environment.     

Cellular traction stresses increase with increasing metastatic potential

Cancer cells exist in a mechanically and chemically heterogeneous microenvironment which undergoes dynamic changes throughout neoplastic progression. During metastasis, cells from a primary tumor acquire characteristics that enable them to escape from the primary tumor and migrate through the heterogeneous stromal environment to establish secondary tumors. Despite being linked to poor prognosis, there are no direct clinical tests available to diagnose the likelihood of metastasis. Moreover, the physical mechanisms employed by metastatic cancer cells to migrate are poorly understood. Because metastasis of most solid tumors requires cells to exert force to reorganize and navigate through dense stroma, we investigated differences in cellular force generation between metastatic and non-metastatic cells. Using traction force microscopy, we found that in human metastatic breast, prostate and lung cancer cell lines, traction stresses were significantly increased compared to non-metastatic counterparts. This trend was recapitulated in the isogenic MCF10AT series of breast cancer cells. Our data also indicate that increased matrix stiffness and collagen density promote increased traction forces, and that metastatic cells generate higher forces than non-metastatic cells across all matrix properties studied. Additionally, we found that cell spreading for these cell lines has a direct relationship with collagen density, but a biphasic relationship with substrate stiffness, indicating that cell area alone does not dictate the magnitude of traction stress generation. Together, these data suggest that cellular contractile force may play an important role in metastasis, and that the physical properties of the stromal environment may regulate cellular force generation. These findings are critical for understanding the physical mechanisms of metastasis and the role of the extracellular microenvironment in metastatic progression.     

A Mathematical Analysis of Agonist- and KCl-Induced Ca Oscillations in Mouse Airway Smooth Muscle Cells

Airway hyperresponsiveness is a major characteristic of asthma and is generally ascribed to excessive airway narrowing associated with the contraction of airway smooth muscle cells (ASMCs). ASMC contraction is initiated by a rise in intracellular calcium concentration ([Ca²⁺]_i), observed as oscillatory Ca²⁺ waves that can be induced by either agonist or high extracellular K⁺ (KCl). In this work, we present a model of oscillatory Ca²⁺ waves based on experimental data that incorporate both the inositol trisphosphate receptor and the ryanodine receptor. We then combined this Ca²⁺ model and our modified actin-myosin cross-bridge model to investigate the role and contribution of oscillatory Ca²⁺ waves to contractile force generation in mouse ASMCs. The model predicts that: 1), the difference in behavior of agonist- and KCl-induced Ca²⁺ waves results principally from the fact that the sarcoplasmic reticulum is depleted during agonist-induced oscillations, but is overfilled during KCl-induced oscillations; 2), regardless of the order in which agonist and KCl are added into the cell, the resulting [Ca²⁺]_i oscillations will always be the short-period, agonist-induced-like oscillations; and 3), both the inositol trisphosphate receptor and the ryanodine receptor densities are higher toward one end of the cell. In addition, our results indicate that oscillatory Ca²⁺ waves generate less contraction than whole-cell Ca²⁺ oscillations induced by the same agonist concentration. This is due to the spatial inhomogeneity of the receptor distributions.     

Release of biologically active TGF-beta from airway smooth muscle cells induces autocrine synthesis of collagen

In severe or chronic asthma, there is an increase in airway smooth muscle cell (ASMC) mass as well as an increase in connective tissue proteins in the smooth muscle layer of airways. Transforming growth factor-beta (TGF-beta) exists in three isoforms in mammals and is a potent regulator of connective tissue protein synthesis. Using immunohistochemistry, we had previously demonstrated that ASMCs contain large quantities of TGF-beta1-3. In this study, we demonstrate that bovine ASMC-derived TGF-beta associates with the TGF-beta latency binding protein-1 (LTBP-1) expressed by the same cells. The TGF-beta associated with LTBP-1 localizes TGF-beta extracellularly. Furthermore, plasmin, a serine protease, regulates the secretion of a biologically active form of TGF-beta by ASMCs as well as the release of extracellular TGF-beta. The biologically active TGF-beta released by plasmin induces ASMCs to synthesize collagen I in an autocrine manner. The autocrine induction of collagen expression by ASMCs may contribute to the irreversible fibrosis and remodeling seen in the airways of some asthmatics.     

PTEN inhibition improves wound healing in lung epithelia through changes in cellular mechanics that enhance migration

The phosphoinositide-3 kinase/Akt pathway is a vital survival axis in lung epithelia. We previously reported that inhibition of phosphatase and tensin homolog deleted on chromosome 10 (PTEN), a major suppressor of this pathway, results in enhanced wound repair following injury. However, the precise cellular and biomechanical mechanisms responsible for increased wound repair during PTEN inhibition are not yet well established. Using primary human lung epithelia and a related lung epithelial cell line, we first determined whether changes in migration or proliferation account for wound closure. Strikingly, we observed that cell migration accounts for the majority of wound recovery following PTEN inhibition in conjunction with activation of the Akt and ERK signaling pathways. We then used fluorescence and atomic force microscopy to investigate how PTEN inhibition alters the cytoskeletal and mechanical properties of the epithelial cell. PTEN inhibition did not significantly alter cytoskeletal structure but did result in large spatial variations in cell stiffness and in particular a decrease in cell stiffness near the wound edge. Biomechanical changes, as well as migration rates, were mediated by both the Akt and ERK pathways. Our results indicate that PTEN inhibition rapidly alters biochemical signaling events that in turn provoke alterations in biomechanical properties that enhance cell migration. Specifically, the reduced stiffness of PTEN-inhibited cells promotes larger deformations, resulting in a more migratory phenotype. We therefore conclude that increased wound closure consequent to PTEN inhibition occurs through enhancement of cell migration that is due to specific changes in the biomechanical properties of the cell.     

Strength in the periphery: growth cone biomechanics and substrate rigidity response in peripheral and central nervous system neurons

There is now considerable evidence of the importance of mechanical cues in neuronal development and regeneration. Motivated by the difference in the mechanical properties of the tissue environment between the peripheral (PNS) and central (CNS) nervous systems, we compare substrate-stiffness-dependent outgrowth and traction forces from PNS (dorsal root ganglion (DRG)) and CNS (hippocampal) neurons. We show that neurites from DRG neurons display maximal outgrowth on substrates with a Young's modulus of ～1000 Pa, whereas hippocampal neurite outgrowth is independent of substrate stiffness. Using traction force microscopy, we also find a substantial difference in growth cone traction force generation, with DRG growth cones exerting severalfold larger forces compared with hippocampal growth cones. The traction forces generated by DRG and hippocampal growth cones both increase with increasing stiffness, and DRG growth cones growing on substrates with a Young's modulus of 1000 Pa strengthen considerably after 18–30 h. Finally, we find that retrograde actin flow is almost three times faster in hippocampal growth cones than in DRG. Moreover, the density of paxillin puncta is significantly lower in hippocampal growth cones, suggesting that stronger substrate coupling of the DRG cytoskeleton is responsible for the remarkable difference in traction force generation. These findings reveal a differential adaptation of cytoskeletal dynamics to substrate stiffness in growth cones of different neuronal types, and highlight the potential importance of the mechanical properties of the cellular environment for neuronal navigation during embryonic development and nerve regeneration.