EL4 Murine-Lymphoma-Stromal-Cell Fusion Hybrids Observed With Multiple Distinct Morphologies in the Primary Tumor and Metastatic Organs of a Syngeneic Mouse Model.

BACKGROUND/AIM: We and others have previously shown that cell fusion plays an important role in cancer metastasis. Color coding of cancer and stromal cells with spectrally-distinct fluorescent proteins is a powerful tool, as pioneered by our laboratory to detect cell fusion. We have previously reported color-coded cell fusion between cancer cells and stromal cells in metastatic sites by using color-coded EL4 murine lymphoma cells and host mice expressing spectrally-distinct fluorescent proteins. Cell fusion occurred between cancer cells or, between cancer cells and normal cells, such as macrophages, fibroblasts, and mesenchymal stem cells. In the present study, the aim was to morphologically classify the fusion-hybrid cells observed in the primary tumor and multiple metastases EL4 formed from cells expressing red fluorescent protein (RFP) in transgenic mice expressing green fluorescent protein (GFP), in a syngeneic model. MATERIALS AND METHODS: RFP-expressing EL4 murine lymphoma cells were cultured in vitro. EL4-RFP cells were harvested and injected intraperitoneally into immunocompetent transgenic C57/BL6-GFP mice to establish a syngeneic model. Two weeks later, mice were sacrificed and each organ was harvested, cultured, and observed using confocal microscopy. RESULTS: EL4 intraperitoneal tumors (primary) and metastases in the lung, liver, blood, and bone marrow were formed. All tumors were harvested and cultured. In all specimens, RFP-EL4 cells, GFP-stromal cells, and fused yellow-fluorescent hybrid cells were observed. The fused hybrid cells showed various morphologies. Immune cell-like round-shaped yellow-fluorescent fused cells had a tendency to decrease with time in liver metastases and circulating blood. In contrast fibroblast-like spindle-shaped yellow-fluorescent fused cells increased in the intraperitoneal primary tumor, lung metastases, and bone marrow. CONCLUSION: Cell fusion between EL4-RFP cells and GFP stromal cells occurred in primary tumors and all metastatic sites. The morphology of the fused hybrid cells varied in the primary and metastatic sites. The present results suggest that fused cancer and stromal hybrid cells of varying morphology may play an important role in cancer progression.

Exosome Transfer Between Different Co-implanted Human Pancreatic Cancer Cell Lines Occurs in the Primary Tumor and Multiple Metastatic Sites of Nude Mice But Not in Co-Culture In Vitro.

BACKGROUND/AIM: Exosome exchange between cancer cells or between cancer and stromal cells is involved in cancer metastasis. We have previously developed in vivo color-coded labeling of cancer cells and stromal cells with spectrally-distinct fluorescent genetic reporters to demonstrate the role of exosomes in metastasis. In the present study, we studied exosome transfer between different pancreatic-cancer cell lines in vivo and in vitro and its potential role in metastasis. MATERIALS AND METHODS: Human pancreatic-cancer cell lines AsPC-1 and MiaPaCa-2 were used in the present study. AsPC-1 cells contain a genetic exosome reporter gene labeled with green fluorescent protein (pCT-CD63-GFP) and MiaPaCa-2 cells express red fluorescent protein (RFP). Both cell lines were co-injected into the spleen of nude mice (n=5) to further study the role of exosome exchange in metastasis. Three weeks later mice were sacrificed and tumors at the primary and metastatic sites were cultured and observed by confocal fluorescence microscopy for exosome transfer. RESULTS: The primary tumor formed in the spleen and metastasized to the liver, as observed macroscopically. Cells were cultured from the spleen, liver, lung, bone marrow and ascites. Transfer of exosomes from AsPC-1 to MiaPaCa-2 was demonstrated in the cultured cells by confocal fluorescence microscopy. Moreover, cell fusion was also observed along with exosome transfer. Exosome transfer did not occur during in vitro co-culture between the two pancreatic-cancer cell lines, suggesting a role of the tumor microenvironment (TME) in exosome transfer. CONCLUSION: The transfer of exosomes between different pancreatic-cancer cell lines was observed during primary-tumor and metastatic growth in nude mice. This cell-cell communication might be a trigger of cell fusion and promotion of cancer metastasis. Exosome transfer between the two pancreatic-cancer cell lines appears to be facilitated by the TME, as it did not occur during in vitro co-culture.

Color-Coded Imaging of the Tumor Microenvironment (TME) in Human Patient-Derived Orthotopic Xenograft (PDOX) Mouse Models.

The tumor microenvironment (TME) contains stromal cells in a complex interaction with cancer cells. This relationship has become better understood with the use of fluorescent proteins for in vivo imaging, originally developed by our laboratories. Spectrally distinct fluorescent proteins can be used for color-coded imaging of the complex interaction of the tumor microenvironment in the living state using cancer cells expressing a fluorescent protein of one color and host mice expressing another color fluorescent protein. Cancer cells engineered in vitro to express a fluorescent protein were orthotopically implanted into transgenic mice expressing a fluorescent protein of a different color. Confocal microscopy was then used for color-coded imaging of the TME. Color-coded imaging of the TME has enabled us to discover that stromal cells are necessary for metastasis. Patient-derived orthotopic xenograft (PDOX) tumors were labeled by first passaging them orthotopically through transgenic nude mice expressing either green, red, or cyan fluorescent protein in order to label the stromal cells of the tumor. The colored stromal cells become stably associated with the PDOX tumors through multiple passages in transgenic colored nude mice or noncolored nude mice. The fluorescent protein-expressing stromal cells included cancer-associated fibroblasts (CAFs) and tumor-associated macrophages (TAMs). Using this model, specific cancer cell or stromal cell targeting by potential therapeutics can be visualized. Color-coded imaging enabled the visualization of apparent fusion of cancer and stromal cells. Color-coded imaging is a powerful tool visualizing the interaction of cancer and stromal cells during cancer progression and treatment.

Exosome Transfer Between Pancreatic-cancer Cells Is Associated With Metastasis in a Nude-mouse Model.

BACKGROUND/AIM: Cancer-derived exosomes play an important role in metastasis. In the present study, we determined whether exosome transfer between cancer cells is associated with metastasis in a mouse model. MATERIALS AND METHODS: AsPC-1 human pancreatic-cancer cells expressing red fluorescent protein (RFP) and AsPC-1 human pancreatic-cancer cells transduced by exosome-specific pCT-CD63-green fluorescent protein (GFP), were co-injected into the spleen of nude mice. RESULTS: Both pancreatic-cancer cell lines grew in the spleen and metastasized to the liver, peritoneum, and lungs, as shown by color-coded imaging. The ratio of GFP-expressing exosomes incorporated in RFP-labeled AsPC-1 cells was statistically-significantly higher in the liver, lung, and peritoneal metastases than in the spleen. CONCLUSION: Exosome transfer between cancer cells is associated with metastasis. Exosome transfer may play a role in increasing the metastatic capability of the recipient cells.

Color-Coded Imaging of Cancer and Stromal-Cell Interaction in the Pancreatic-Cancer Tumor Microenvironment (TME).

The tumor microenvironment (TME) contains stromal cells in a complex interaction with cancer cells. This relationship has become better understood with the use of fluorescent proteins for in vivo imaging, originally developed by our laboratories. Spectrally-distinct fluorescent proteins can be used for color-coded imaging of the complex interaction of the tumor microenvironment in the living state using cancer cells expressing a fluorescent protein of one color and host mice expressing another-color fluorescent protein. Cancer cells engineered in vitro to express a fluorescent protein were orthotopically implanted into transgenic mice expressing a fluorescent protein of a different color. Confocal microscopy was then used for color-coded imaging of the TME. Color-coded imaging of the TME has enabled us to discover that stromal cells are necessary for metastasis. Patient-derived orthotopic xenograft (PDOX) tumors were labeled by first passaging them orthotopically through transgenic nude mice expressing either green, red, or cyan fluorescent protein in order to label the stromal cells of the tumor (Yang et al., Cancer Res 64:8651-8656, 2004; Yang et al. J Cell Biochem 106: 279-284, 2009). The colored stromal cells become stably associated with the PDOX tumors through multiple passages in transgenic colored nude mice or non-colored nude mice. The fluorescent protein-expressing stromal cells included cancer-associated fibroblasts and tumor-associated macrophages. Color-coded imaging enabled the visualization of apparent fusion of cancer and stromal cells. Color-coded imaging is a powerful tool visualizing the interaction of cancer and stromal cells during cancer progression and treatment.

Color-coded Imaging of the Fate of Cancer-cell-derived Exosomes During Pancreatic Cancer Metastases in a Nude-mouse Model.

BACKGROUND/AIM: Tumor-derived exosomes play important roles in tumor metastases. In this report, we observed the fate of tumor-derived exosomes in pancreatic cancer metastatic nude-mouse models using color-coded imaging. MATERIALS AND METHODS: Mia-PaCa-2 human pancreatic cancer cells expressing red fluorescent protein (RFP) were transduced by exosome-specific pCT-CD63-green fluorescent protein (GFP) and injected in the spleen of nude mice. RESULTS: Four weeks after injection of these cells into the spleen, liver metastases developed and tumor-derived exosomes were observed within the metastatic cancer cells and in Kupffer cells. Furthermore, tumor-derived exosomes diffused to bone marrow and lung cells, especially macrophages, without any metastases present. CONCLUSION: In the present study, we visualized the distribution of cancer-derived exosomes for the first time at the cellular level, in a pancreatic-cancer metastatic model.

Color-coded Imaging of the Circulating Tumor Cell Microenvironment.

BACKGROUND/AIM: Circulating tumor cells (CTCs) may initiate metastasis. Some studies show that the number of CTCs and existence of CTC clusters can be prognostic. In the present study, our color-coded imaging nude mouse model of metastatic lymphoma was utilized to investigate the microenvironment of CTC clusters using fluorescent-protein imaging. MATERIALS AND METHODS: EL-4 mouse lymphoma cells expressing red fluorescent protein (RFP) were injected into the spleen of transgenic C57B/6-green fluorescent protein (GFP) mice. Three weeks later, the number of CTCs and CTC clusters both in heart blood and portal blood were quantified and characterized using confocal microscopy for color-coded imaging. RESULTS: There was no significant difference in the number of CTCs between heart and portal blood. CTC clusters comprised 8.8% of CTCs, determined by color-coded imaging. Heterotypic CTC clusters containing other types of cells were distinguishable from homotypic CTCs. Heterotypic CTC clusters comprising cancer cells and fibroblasts were more rare than homotypic ones. Heterotypic CTC clusters with fibroblasts were observed only in portal blood, not in heart blood. CONCLUSION: CTCs can have variable properties depending on the blood source. CTCs can form clusters, which may contain fibroblast that may play a role in promoting CTC metastasis. Our results demonstrate the concept of the CTC microenvironment (CME), which may play a critical role in CTC behavior, including of metastasis.

Color-coded Imaging Distinguishes Cancer Cells, Stromal Cells, and Recombinant Cancer-stromal Cells in the Tumor Microenvironment During Metastasis.

BACKGROUND/AIM: Our laboratory pioneered color-coded imaging of the tumor microenvironment (TME). We observed recruitment of cancer and stromal cells to the TME and recombination between cancer and stromal cells. The aim of the present study was to observe the dynamics of the TME by color-coded imaging during metastasis and in the formation of a pre-metastatic niche. MATERIALS AND METHODS: Red-fluorescent protein (RFP-expressing) mouse colon-cancer 26 cells were initially injected subcutaneously in green-fluorescent protein (GFP) nude mice. The resulting subcutaneous tumors were harvested and cultured. The cultured subcutaneous tumors contained RFP colon cancer cells, GFP stromal cells and recombinant cancer-stromal cells expressing yellow fluorescence. After 14 days culture, the cells were injected into the spleen. RESULTS: After splenic injection, colon-cancer 26 metastases were observed in the liver, ascites, and bone marrow. Using the Olympus FV1000 confocal microscope, the cells cultured from tumors and metastasis in each site were visualized. RFP colon-cancer cells, GFP stromal cells derived from host GFP nude mice, and recombinant yellow-fluorescent cells were observed in each organ. In addition, in the liver, areas with only GFP stromal cells were observed and assumed to be a pre-metastatic niche. CONCLUSION: Color-coded imaging demonstrated the dynamics of colon cancer and stromal cells at different metastatic sites including the formation of recombinant cancer-stromal cells.

Visualizing the Tumor Microenvironment by Color-coded Imaging in Orthotopic Mouse Models of Cancer.

The tumor microenvironment (TME) contains stromal cells in a complex interaction with cancer cells. This relationship has become better understood with the use of fluorescent proteins for in vivo imaging, originally developed by our laboratories. Spectrally-distinct fluorescent proteins can used for color-coded imaging of the complex interaction of the tumor microenvironment in the living state using cancer cells expressing a fluorescent protein of one color and host mice expressing another-color fluorescent protein. Cancer cells engineered in vitro to express a fluorescent protein were orthotopically implanted into transgenic mice expressing a fluorescent protein of a different color. Confocal microscopy was then used for color-coded imaging of the TME. Color-coded imaging of the TME has enabled us to discover that stromal cells are necessary for metastasis. Patient-derived orthotopic xenograft (PDOX) tumors were labeled by first passaging them orthotopically through transgenic nude mice expressing either green, red, or cyan fluorescent protein in order to label the stromal cells of the tumor. The colored stromal cells become stably associated with the PDOX tumors through multiple passages in transgenic colored mice or non-colored mice. The fluorescent protein-expressing stromal cells included cancer-associated fibroblasts and tumor-associated macrophages. The cancer cells in PDOX models can also be labeled with a telomerase-dependent adenovirus containing the gene for green fluorescent protein. Using this model, specific cancer-cell or stromal-cell targeting by potential therapeutics can be visualized. Color-coded imaging enabled the visualization of apparent fusion of cancer and stromal cells. Color-coded imaging is a powerful tool visualizing the interaction of cancer and stromal cells during cancer progression and treatment.

Genetic Recombination Between Stromal and Cancer Cells Results in Highly Malignant Cells Identified by Color-Coded Imaging in a Mouse Lymphoma Model.

The tumor microenvironment (TME) promotes tumor growth and metastasis. We previously established the color-coded EL4 lymphoma TME model with red fluorescent protein (RFP) expressing EL4 implanted in transgenic C57BL/6 green fluorescent protein (GFP) mice. Color-coded imaging of the lymphoma TME suggested an important role of stromal cells in lymphoma progression and metastasis. In the present study, we used color-coded imaging of RFP-lymphoma cells and GFP stromal cells to identify yellow-fluorescent genetically recombinant cells appearing only during metastasis. The EL4-RFP lymphoma cells were injected subcutaneously in C57BL/6-GFP transgenic mice and formed subcutaneous tumors 14 days after cell transplantation. The subcutaneous tumors were harvested and transplanted to the abdominal cavity of nude mice. Metastases to the liver, perigastric lymph node, ascites, bone marrow, and primary tumor were imaged. In addition to EL4-RFP cells and GFP-host cells, genetically recombinant yellow-fluorescent cells, were observed only in the ascites and bone marrow. These results indicate genetic exchange between the stromal and cancer cells. Possible mechanisms of genetic exchange are discussed as well as its ramifications for metastasis. J. Cell. Biochem. 118: 4216-4221, 2017. © 2017 Wiley Periodicals, Inc.

Use of fluorescent proteins and color-coded imaging to visualize cancer cells with different genetic properties.

Fluorescent proteins are very bright and available in spectrally-distinct colors, enable the imaging of color-coded cancer cells growing in vivo and therefore the distinction of cancer cells with different genetic properties. Non-invasive and intravital imaging of cancer cells with fluorescent proteins allows the visualization of distinct genetic variants of cancer cells down to the cellular level in vivo. Cancer cells with increased or decreased ability to metastasize can be distinguished in vivo. Gene exchange in vivo which enables low metastatic cancer cells to convert to high metastatic can be color-coded imaged in vivo. Cancer stem-like and non-stem cells can be distinguished in vivo by color-coded imaging. These properties also demonstrate the vast superiority of imaging cancer cells in vivo with fluorescent proteins over photon counting of luciferase-labeled cancer cells.

Recruitment of Cancer-Associated Fibroblasts and Blood Vessels by Orthotopic Liver Tumors Imaged in Red Fluorescent Protein (RFP) Transgenic Nude Mice.

BACKGROUND/AIM: The tumor microenvironment (TME) is critical for tumor growth and progression. We report here an imageable model of the TME of orthotopic liver cancer. MATERIALS AND METHODS: The transgenic red fluorescent protein (RFP)-expressing nude mouse was used as the host. The RFP nude mouse expresses RFP in all organs. Non-colored Huh-7 human hepatoma cells were injected in the spleen of RFP nude mice to establish an orthotopic liver cancer model. TME formation resulting from the orthotopic liver tumor was observed using the Olympus OV100 small animal fluorescence imaging system. RESULTS: Non-colored liver cancer cells formed tumor colonies in the liver 28 days after cell transplantation to the spleen. RFP-expressing host cells and blood vessels were recruited by the liver tumors as visualized by fluorescence imaging. A desmin- and sirus-red-positive area increased around and within the liver tumor over time. CONCLUSION: These results indicate cancer-associated fibroblasts (CAFs) were recruited by the liver tumors suggesting that CAFs, along with the angiogenic tumor blood vessels, were necessary for liver-tumor growth and could serve as visible therapeutic targets.

Color-Coded Imaging of Breast Cancer Metastatic Niche Formation in Nude Mice.

We report here a color-coded imaging model in which metastatic niches in the lung and liver of breast cancer can be identified. The transgenic green fluorescent protein (GFP)-expressing nude mouse was used as the host. The GFP nude mouse expresses GFP in all organs. However, GFP expression is dim in the liver parenchymal cells. Mouse mammary tumor cells (MMT 060562) (MMT), expressing red fluorescent protein (RFP), were injected in the tail vein of GFP nude mice to produce experimental lung metastasis and in the spleen of GFP nude mice to establish a liver metastasis model. Niche formation in the lung and liver metastasis was observed using very high resolution imaging systems. In the lung, GFP host-mouse cells accumulated around as few as a single MMT-RFP cell. In addition, GFP host cells were observed to form circle-shaped niches in the lung even without RFP cancer cells, which was possibly a niche in which future metastasis could be formed. In the liver, as with the lung, GFP host cells could form circle-shaped niches. Liver and lung metastases were removed surgically and cultured in vitro. MMT-RFP cells and GFP host cells resembling cancer-associated fibroblasts (CAFs) were observed interacting, suggesting that CAFs could serve as a metastatic niche.

Color-coded imaging of spontaneous vessel anastomosis in vivo.

Vessel anastomosis is important in tumor angiogenesis as well as for vascularization therapy for ischemia and other diseases. We report here the development of a color-coded imaging model that can visualize the anastomosis between blood vessels of red fluorescent protein (RFP)-expressing vessels in vascularized Gelfoam® previously transplanted into RFP transgenic mice and then re-transplanted into nestin-driven green fluorescent protein (ND-GFP) mice where nascent blood vessels express GFP. Gelfoam® was initially transplanted subcutaneously in the flank of transgenic RFP nude mice. Skin flaps were made at 14 days after transplantation of Gelfoam® to allow observation of vascularization of the Gelfoam® using confocal fluorescence imaging. The implanted Gelfoam® became highly vascularized with RFP vessels. Fourteen days after transplantation into RFP transgenic nude mice, the Gelfoam® was removed and re-transplanted into the subcutis on the flank of ND-GFP transgenic nude mice in which nascent blood vessels express GFP. Skin flaps were made and anastomosis between the GFP-expressing nascent blood vessels of ND-GFP transgenic nude mice and RFP blood vessels in the Gelfoam® was imaged 14 and 21 days after re-transplantation. The results presented in this report indicate a possible mechanism for tumor angiogenesis and suggest a new paradigm of therapeutic revascularization of ischemic organs requiring new blood vessels and in other diseases.