New dimensions in cell migration

Studies of cell migration in three-dimensional (3D) cell culture systems and in vivo have revealed several differences when compared with cell migration in two dimensions, including their morphology and mechanical and signalling control. Here, researchers assess the contribution of 3D models to our understanding of cell migration, both in terms of the mechanisms used to drive single cell and collective cell migration and how migrating cells respond to a changing environment in vivo.

The use of a conventional tissue culture plate as an optically accessible perfusion chamber for in situ assays and for long-term cultivation of mammalian cells

An alternative culture system has been developed based on a conventional tissue culture plate (3.5 cm diameter) which is changed into a closed perfusion chamber. The system can easily be scaled up from one to several chambers. The shape and the size of the area of cell growth may be designed to individual experimental demands. The whole culture chamber is optically accessible, so cell growth and morphology can be evaluated by light microscopy. Furthermore the cellular physiology can be characterised by any fluorimetric assay using a bottom type fluorescence reader. A peristaltic pump sustains a constant medium flow through the chamber thus creating true homeostasis. The use of HPLC-valves and connectors allows the switching between different media or assay solutions. Thus it is possible to perform in situ assays also measuring transient effects. A protocol for vitality tests using calcein-AM is worked out for an adherent cell line and for a suspension cell line. The lower detection limits are 7 × 10(2) cells cm(-2) for the adherent cells and 5 × 10(4) cells mL(-1) for the suspension cells. The upper limits are 1-2 × 10(5) cells cm(-2) respectively 8 × 10(6) cells mL(-1).

A large-scale (19)F MRI-based cell migration assay to optimize cell therapy

Adoptive transfer of cells for therapeutic purposes requires efficient and precise delivery to the target organ whilst preserving cell function. Therefore, therapeutically applied cells need to migrate and integrate within their target tissues after delivery, e.g. dendritic cells (DCs) need to migrate to lymph nodes to elicit an antigen-specific immune response. Previous studies have shown that inappropriate cell delivery can hinder DC migration and result in insufficient immune induction. As migration can be extremely difficult to study quantitatively in vivo, we propose an in vitro assay that reproduces key in vivo conditions to optimize cell delivery and migration in vivo. Using DC migration along a chemokine gradient, we describe here a novel (19)F MR-based, large-scale, quantitative assay to measure cell migration in a three-dimensional collagen scaffold. Unlike conventional migration assays, this set-up is amenable to both large and small cell numbers, as well as opaque tissue samples and the inclusion of chemokines or other factors. We labeled primary human DCs with a (19)F label suitable for clinical use; (0.5-15) × 10(6) cells in the scaffolds were imaged sequentially, and migration was assessed using two independent methods. We found no migration with larger numbers of cells, but up to 3% with less than one million cells. Hence, we show that the cell density in cell bolus injections has a decisive impact on migration, and this may explain the limited migration observed using large cell numbers in the clinic.

Classifying collective cancer cell invasion

Most invasive solid tumours display predominantly collective invasion, in which groups of cells invade the peritumoral stroma while maintaining cell-cell contacts. As the concepts and experimental models for functional analysis of collective cancer cell invasion are rapidly developing, we propose a framework for addressing potential mechanisms, experimental strategies and technical challenges to study this process.

Intravital third harmonic generation microscopy of collective melanoma cell invasion: Principles of interface guidance and microvesicle dynamics

Cancer cell invasion is an adaptive process based on cell-intrinsic properties to migrate individually or collectively, and their adaptation to encountered tissue structure acting as barrier or providing guidance. Whereas molecular and physical mechanisms of cancer invasion are well-studied in 3D in vitro models, their topographic relevance, classification and validation toward interstitial tissue organization in vivo remain incomplete. Using combined intravital third and second harmonic generation (THG, SHG), and three-channel fluorescence microscopy in live tumors, we here map B16F10 melanoma invasion into the dermis with up to 600 µm penetration depth and reconstruct both invasion mode and tissue tracks to establish invasion routes and outcome. B16F10 cells preferentially develop adaptive invasion patterns along preformed tracks of complex, multi-interface topography, combining single-cell and collective migration modes, without immediate anatomic tissue remodeling or destruction. The data suggest that the dimensionality (1D, 2D, 3D) of tissue interfaces determines the microanatomy exploited by invading tumor cells, emphasizing non-destructive migration along microchannels coupled to contact guidance as key invasion mechanisms. THG imaging further detected the presence and interstitial dynamics of tumor-associated microparticles with submicron resolution, revealing tumor-imposed conditioning of the microenvironment. These topographic findings establish combined THG, SHG and fluorescence microscopy in intravital tumor biology and provide a template for rational in vitro model development and context-dependent molecular classification of invasion modes and routes.

Twenty-third annual Pezcoller Symposium: engineering influences in cancer research

The cross-disciplinary focus of the meeting highlighted recent progress in physical and genetic analysis and engineering of cancer disease models. As the central theme, mechanical forces affecting cell signaling, growth, differentiation, and metastasis were discussed with emphasis on the tumor microenvironment and cellular immunity, taking into account novel nanotechnology, biosensing, and intravital microscopy tools to monitor animal cancer models and human cancer. Emerging themes were the role of extracellular matrix imposing mechanical mechanisms on tumor cell function, including microenvironmental cues controlling the movement of tumor and immune cells, advanced genetic animal models for cancer that better recapitulate human disease, and preclinical and clinical molecular imaging of tumor architecture and stiffness, as well as novel nanotechnologies for anticancer drug delivery.

MS1-1: Imaging Cancer Invasion In Vivo: Mechanisms and Implications for Therapy

The tumor microenvironment contributes to cancer invasion, growth and survival and thereby impacts tumor responses to therapy. Using infrared-excited multiphoton microscopy in orthotopic fibrosarcoma and melanoma xenografts, we here identify a novel radio- and chemoresistance niche consisting of invading tumor cell strands consisting of several hundred connected cells located within collagen-rich stroma nearby blood and lymph vessels. Despite normoxia, perivascular invasion strands were resistant to high-dose hypofractionated irradiation which otherwise was sufficient to induce regression of the tumor main mass. This invasion-associated chemo-and radioresistance was sensitive to the simultaneous inhibition of β1 and β3 integrins by RNA interference or combined anti-β1/aV integrin antibody treatment leading to proliferation arrest, anoikis induction and subtotal to complete regression of both tumor lesion and invasion strands. Thus, collective invasion is an important invasion mode in solid tumors into a microenvironmentally priviledged perivascular survival niche which conveys radioresistance by integrin-dependent signals.

Citation Information: Cancer Res 2011;71(24 Suppl):Abstract nr MS1-1.

Extracellular matrix determinants of proteolytic and non-proteolytic cell migration

Cell invasion into the 3D extracellular matrix (ECM) is a multistep biophysical process involved in inflammation, tissue repair, and metastatic cancer invasion. Migrating cells navigate through tissue structures of complex and often varying physicochemical properties, including molecular composition, porosity, alignment and stiffness, by adopting strategies that involve deformation of the cell and engagement of matrix-degrading proteases. We review how the ECM determines whether or not pericellular proteolysis is required for cell migration, ranging from protease-driven invasion and secondary tissue destruction, to non-proteolytic, non-destructive movement that solely depends on cell deformability and available tissue space. These concepts call for therapeutic targeting of proteases to prevent invasion-associated tissue destruction rather than the migration process per se.

A serum-free medium formulation supporting growth of human umbilical cord vein endothelial cells in long-term cultivation

A serum-free medium formulation - TUD-1 - was developed supporting growth of HUVEC in tissue culture. Special features of the basal medium formulation are highly elevated levels of glutamine and serine as well as the inclusion of N-acetylcysteine and phosphoascorbic acid. The cellular mitogenic needs are satisfied by bFGF, VEGF, EGF and liver growth factor. Further hormone supplementation consists of insulin and hydrocortisone. A protocoll for serum-free passage of HUVEC was established for serum-free long-term cultivation of freshly isolated HUVEC for up to 20 cumulative population doublings without significant differences in final cell density compared to controls cultivated with serum.

Cytotoxic T lymphocyte migration and effector function in the tumor microenvironment

Immunological control of cancer lesions requires local uptake of tumor-specific antigen followed by the activation and expansion of tumor specific cytotoxic T-lymphocytes (CTL). An efficient effector phase further depends upon the entry of activated CTL into the tumor microenvironment and scanning of tumor tissue, which leads to direct interaction of the CTL with target cells followed by apoptosis induction and shrinkage of the tumor lesion. Whereas the antigens and pathways that lead to efficient activation of tumor-specific CTL are well established, the local mechanisms that enable efficient - or deficient - CTL function in the tumor tissue are poorly understood. Firstly, effector T lymphocytes need to be mobile to reach the tumor lesion. Next, they must physically interact with and scan tumor cells for antigenic MHC/peptide complexes. Lastly, CTLs must undergo activation and functional conjugation with target cells to induce apoptosis either by the release of perforins or the engagement of Fas/FasL. All these steps of effector function are interdependent and require the amoeboid migration of CTL through tissue to reach, engage with and leave encountered cells.

A dynamic immunological synapse mediates homeostatic TCR-dependent and -independent signaling

For homeostasis, T cells integrate non-cognate TCR-dependent and -independent signals to survive and weakly proliferate. In contrast to antigen-specific, stable, and long-lived contacts, signaling in short-lived homeostatic interactions depends upon the coordination of ongoing T-cell migration on the surface of DC and signaling at the cell-cell junction. To mimic peripheral tissues and analyze how T-cell migration and cell-cell signaling are integrated, we used live-cell imaging and 3-D reconstruction of fixed conjugates between DO11.10 T cells and DC in 3-D low-density collagen matrices. T cells simultaneously maintained amoeboid migration and polarized towards the DC, leading to a fully dynamic interaction plane that delivered signals for homeostatic T-cell survival and proliferation. The contact plane comprised three zones, the actin-rich leading edge poor in signal but driving migration, a mid-zone mediating TCR/MHC-induced signal associated with proliferation, and the rear uropod mediating predominantly MHC-independent signals. Thus a dynamic immunological synapse with distinct signaling sectors enables moving T cells to serially sample resident tissue cells and acquire molecular information "en passant".

Nuclear mechanics during cell migration

During cell migration, the movement of the nucleus must be coordinated with the cytoskeletal dynamics at the leading edge and trailing end, and, as a result, undergoes complex changes in position and shape, which in turn affects cell polarity, shape, and migration efficiency. We here describe the steps of nuclear positioning and deformation during cell polarization and migration, focusing on migration through three-dimensional matrices. We discuss molecular components that govern nuclear shape and stiffness, and review how nuclear dynamics are connected to and controlled by the actin, tubulin and intermediate cytoskeleton-based migration machinery and how this regulation is altered in pathological conditions. Understanding the regulation of nuclear biomechanics has important implications for cell migration during tissue regeneration, immune defence and cancer.

Deep collective cancer invasion: Breaking radioresistance by anti-integrin therapy

The tumor microenvironment contributes to cancer invasion, growth and survival and thereby impacts tumor responses to therapy. We here show for orthotopic fibrosarcoma and melanoma xenografts deep invasive growth driven by proliferation concurrent with collective invasion of multicellular strands along the normoxic perivascular stroma. Invasion was fast (up to 200 µm per day), non-destructive and independent of β1 and β3 integrins. Despite normoxia, perivascular invasion strands were resistant to high-dose hypofractionated irradiation which otherwise was sufficient to induce regression of the tumor main mass. This invasion-associated radioresistance was sensitive to the simultaneous inhibition of β1 and β3 integrins by RNA interference or combined anti-β1/aV integrin antibody treatment caused byproliferation arrest, anoikis induction ablating both tumor lesion and invasion strands. Thus, collective invasion is an important invasion mode in solid tumors into a microenvironmentally privileged perivascular survival niche which conveys radioresistance by integrin-dependent signals. Consequently, combining anti-integrin therapy with hypofractionated irradiation may be amenable to clinical cancer treatment of locally destructive and otherwise radioresistant tumor lesions.

An experimental model to study isolated effects of thrombin in vivo

BACKGROUND

In addition to a recognized role in the coagulation cascade and haemostasis, thrombin is known to have multiple functions. We hypothesized that protracted intravenous infusion of thrombin at steady state will allow to study isolated thrombin effects in vivo.

METHODS

Thrombin (0.05-0.9U/kg/min) was continuously infused in Sprague Dawley rats over five hours (n=38). The study consisted of three parts: dose escalation (n=21), dose verification (n=5) and a parallel group study to investigate whether thrombin effects can be antagonised by concomitant infusion of lepirudin (n=12).

RESULTS

A thrombin dose of 0.9U/kg/min decreased platelet counts by 70% compared to the control group (median 230×10^9/L vs. 752×10^9/L; p=0.041). In accordance, infusion of 0.9U/kg/min of thrombin decreased fibrinogen level by 75% compared to the control group (56mg/dl vs. 220mg/dl; p=0.046). Cumulative thrombin doses of ≥0.1U/kg/min caused bleedings but not thromboembolic events. Thrombin at doses ≥0.15U/kg/min was lethal in four cases (30%). Platelet counts and fibrinogen levels after thrombin infusion correlated with bleeding events and mortality. Administration of thrombin at cumulative doses of 0.3-0.9U/kg/min was associated with a 3 to 6.5 -fold increase in IL-6 levels (139-306pg/ml vs. 47pg/ml, p<0.05). In contrast, thrombin infusion did not alter other markers of inflammation (IL-10, MCP-1 or TNF-alpha). In addition, lepirudin prevented thrombin- induced thrombocytopenia.

CONCLUSION

Protracted intravenous infusion of thrombin offers a new experimental model, where consumption of fibrinogen and platelets correlates with bleedings and mortality. Infusion of thrombin increased only IL-6 levels but not other cytokines.