Long-term Intravital Immunofluorescence Imaging of Tissue Matrix Components with Epifluorescence and Two-photon Microscopy

Besides being a physical scaffold to maintain tissue morphology, the extracellular matrix (ECM) is actively involved in regulating cell and tissue function during development and organ homeostasis. It does so by acting via biochemical, biomechanical, and biophysical signaling pathways, such as through the release of bioactive ECM protein fragments, regulating tissue tension, and providing pathways for cell migration. The extracellular matrix of the tumor microenvironment undergoes substantial remodeling, characterized by the degradation, deposition and organization of fibrillar and non-fibrillar matrix proteins. Stromal stiffening of the tumor microenvironment can promote tumor growth and invasion, and cause remodeling of blood and lymphatic vessels. Live imaging of matrix proteins, however, to this point is limited to fibrillar collagens that can be detected by second harmonic generation using multi-photon microscopy, leaving the majority of matrix components largely invisible. Here we describe procedures for tumor inoculation in the thin dorsal ear skin, immunolabeling of extracellular matrix proteins and intravital imaging of the exposed tissue in live mice using epifluorescence and two-photon microscopy. Our intravital imaging method allows for the direct detection of both fibrillar and non-fibrillar matrix proteins in the context of a growing dermal tumor. We show examples of vessel remodeling caused by local matrix contraction. We also found that fibrillar matrix of the tumor detected with the second harmonic generation is spatially distinct from newly deposited matrix components such as tenascin C. We also showed long-term (12 hours) imaging of T-cell interaction with tumor cells and tumor cells migration along the collagen IV of basement membrane. Taken together, this method uniquely allows for the simultaneous detection of tumor cells, their physical microenvironment and the endogenous tissue immune response over time, which may provide important insights into the mechanisms underlying tumor progression and ultimate success or resistance to therapy.

[1]  M. Swartz,et al.  Optimization and regeneration kinetics of lymphatic-specific photodynamic therapy in the mouse dermis , 2013, Angiogenesis.

[2]  Melody A. Swartz,et al.  Intravital Immunofluorescence for Visualizing the Microcirculatory and Immune Microenvironments in the Mouse Ear Dermis , 2013, PloS one.

[3]  Michael Sixt,et al.  Interstitial Dendritic Cell Guidance by Haptotactic Chemokine Gradients , 2013, Science.

[4]  W. Kilarski,et al.  An in vivo neovascularization assay for screening regulators of angiogenesis and assessing their effects on pre-existing vessels , 2012, Angiogenesis.

[5]  Jeffrey J. Rice,et al.  Mechanisms of Angiogenesis: Perspectives from Antiangiogenic Tumor Therapies , 2012 .

[6]  K. Alitalo,et al.  In vivo imaging of lymphatic vessels in development, wound healing, inflammation, and tumor metastasis , 2012, Proceedings of the National Academy of Sciences.

[7]  Lai Guan Ng,et al.  DC mobilization from the skin requires docking to immobilized CCL21 on lymphatic endothelium and intralymphatic crawling , 2011, The Journal of experimental medicine.

[8]  Hans Clevers,et al.  Intestinal Crypt Homeostasis Results from Neutral Competition between Symmetrically Dividing Lgr5 Stem Cells , 2010, Cell.

[9]  K. Midwood,et al.  J. Cell Commun. Signal. (2009) 3:287–310 DOI 10.1007/s12079-009-0075-1 RESEARCH ARTICLE The role of tenascin-C in tissue injury and tumorigenesis , 2009 .

[10]  Erik Sahai,et al.  Localised and reversible TGFβ signalling switches breast cancer cells from cohesive to single cell motility , 2009, Nature Cell Biology.

[11]  W. Kilarski,et al.  Biomechanical regulation of blood vessel growth during tissue vascularization , 2009, Nature Medicine.

[12]  R. Kalluri,et al.  Tumor stroma derived biomarkers in cancer , 2009, Cancer and Metastasis Reviews.

[13]  E. Sahai,et al.  Imaging amoeboid cancer cell motility in vivo , 2008, Journal of microscopy.

[14]  M. Sixt,et al.  Rapid leukocyte migration by integrin-independent flowing and squeezing , 2008, Nature.

[15]  J. Kreuger,et al.  Heparan sulfate in trans potentiates VEGFR-mediated angiogenesis. , 2006, Developmental cell.

[16]  C. Halin,et al.  In vivo imaging of lymphocyte trafficking. , 2005, Annual review of cell and developmental biology.

[17]  Jeffrey Wyckoff,et al.  Simultaneous imaging of GFP, CFP and collagen in tumors in vivo using multiphoton microscopy , 2005, BMC biotechnology.

[18]  N. Fusenig,et al.  Friends or foes — bipolar effects of the tumour stroma in cancer , 2004, Nature Reviews Cancer.

[19]  Brian Seed,et al.  Dynamic imaging of collagen and its modulation in tumors in vivo using second-harmonic generation , 2003, Nature Medicine.

[20]  J. Segall,et al.  A critical step in metastasis: in vivo analysis of intravasation at the primary tumor. , 2000, Cancer research.

[21]  G. Patterson,et al.  Photobleaching in two-photon excitation microscopy. , 2000, Biophysical journal.

[22]  H. Erickson,et al.  Dynamics and elasticity of the fibronectin matrix in living cell culture visualized by fibronectin-green fluorescent protein. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[23]  Susan K. Kendall,et al.  Encyclopedia of Life Sciences , 2012 .

[24]  Peter Delves,et al.  Encyclopedia of life sciences , 2009 .

[25]  Z. Werb,et al.  Visualizing stromal cell dynamics in different tumor microenvironments by spinning disk confocal microscopy , 2008 .

[26]  W. Falk,et al.  GFP-transfected tumor cells are useful in examining early metastasis in vivo, but immune reaction precludes long-term tumor development studies in immunocompetent mice , 2004, Clinical & Experimental Metastasis.

[27]  R. Jain,et al.  Conventional and high-speed intravital multiphoton laser scanning microscopy of microvasculature, lymphatics, and leukocyte-endothelial interactions. , 2002, Molecular imaging.

[28]  J. Pawley,et al.  Handbook of Biological Confocal Microscopy , 1990, Springer US.