A model of spontaneous lung metastases visualised in fresh host tissue by green fluorescent protein expression

Animal models of breast cancer for the study of pathogenesis and therapeutic insights

Activation of oncogenes and inactivation of tumour suppressor genes are common events during breast cancer initiation and progression and often determine treatment responsiveness. Indeed, these events need to be recreated in in vitro systems and in mouse cancer models in order to unravel the molecular mechanisms involved in breast cancer initiation and metastasis and assess their possible impact on responses to anticancer drugs. Optical-based imaging models are used to investigate and to follow important tumour progression processes. Moreover, the development of novel anticancer strategies requires more sensitive and less invasive methods to detect and monitor in vivo drug responses in breast cancer models. This review highlights some of the current strategies for modelling breast cancer in vitro and in the mouse, in order to answer biological or translational questions about human breast malignancies.

Hyaluronectin modulation of lung metastasis in nude mice

Hyaluronectin (HN) is a glycoprotein with a high affinity to hyaluronic acid (HA) and known to be a component of the extracellular matrix of tumours. Clinical studies have shown that a low level of HN correlates to tumours with poor prognosis, whereas a high level of HN correlates to tumours with good prognosis. We previously demonstrated in vitro that hyaluronidase activity, which promotes tumour progression and metastatic spread by degradation of HA into angiogenic oligosaccharides, was inhibited or promoted by HN, according to the level of HN-expression. This raises the question of the role played by HN in cancer, and particularly if high and low levels of HN-expression could trigger opposite effects on tumour growth and/or metastatic spread. To address this issue, we used a model of spontaneous lung fluorescent metastases that we characterised previously. We stably transfected the human HN cDNA into fluorescent H460MGFP cells and selected two clones characterised by different levels of HN-expression: HN110 and HN704, with a high and a low level of HN-expression, respectively. In vitro, we demonstrated that HN704 cell migration was significantly increased. Inoculation of clones to nude mice had no significant effect on tumour growth, but clearly revealed opposite effects on metastatic spread: HN110 significantly decreased the number of fluorescent metastases whereas HN704 significantly increased it. We also analysed HN, HA and hyaluronidase contents in sera and tumours. These results demonstrate that HN can play a role as either a suppressor or promoter of metastatic spread.

Establishment of green fluorescent protein-expressing hepatocellular carcinoma cell lines with different metastatic potential: relevant models for in vivo monitoring of metastasis and angiogenesis

PURPOSE

To establish stable green fluorescent protein (GFP)-expressing metastatic human hepatocellular carcinoma (HCC) cell lines with different metastatic potential for long-term in vivo studies of metastasis and angiogenesis.

METHODS

The pIRES2-EGFP vector, which contains an enhanced GFP gene, was transfected into MHCC97-H and MHCC97-L, HCC cell lines with different metastatic potential. The stability of GFP expression, basic biological characteristics, invasion abilities in vitro, and spontaneous metastasis in vivo of the new cell lines (MHCC97-HG and MHCC97-LG) were studied. Microvessel density (MVD) of orthotopic implanted tumors was compared by anti-CD31 immunohistochemical staining, and real-time angiogenesis and metastasis of GFP-transfected tumors were detected by intravital fluorescent microscope.

RESULTS

The GFP-transfected cell lines stably expressed green fluorescence in the absence of G418 over a 36-day period. Compared with the parental cell lines, they exhibited no distinct differences in biological characteristics. MHCC97-HG showed more aggressive invasion and spontaneous metastatic behavior than MHCC97-LG, and even its parental cell line, MHCC97-H (P<0.01). MVD levels induced by MHCC97-HG orthotopic implanted tumors were significantly higher than MHCC97-LG (P<0.01). Real-time angiogenesis and sequential steps of metastasis could be detected clearly under intravital fluorescent microscope.

CONCLUSIONS

These two stable GFP-expressing HCC cell lines with the same genetic background and different metastatic potential were established, which could be useful models for monitoring metastasis and angiogenesis of HCC.

Imaging of luciferase and GFP-transfected human tumours in nude mice

Studies were performed to compare green fluorescent protein (GFP)-transfected and fi re fl y luciferase (Luc)-transfected MCF-7 human breast tumour cells both in vitro and in vivo. For in vitro studies, cells were serially diluted in 96-well microplates and analysed using a NightOwl LB 981 Molecular Light Imager and a Victor multilabel reader. For in vivo studies, nude mice were injected either intraperitoneally, intravenously or subcutaneously with transfected cells and then imaged using the NightOwl Imager after intraperitoneal injection of d-luciferin for Luc tumours, or excitation at 470 nm for GFP tumours. In vitro imaging studies revealed that both GFP and Luc transfectants were quantifiable. However, the Luc-transfected cells were detectable at a significantly lower concentration compared to GFP transfectants. In vivo studies demonstrated that GFP-transfected tumours were detectable as subcutaneous and intraperitoneal tumours but not as deep tissue lesions, whereas Luc-transfected tumours were detectable as subcutaneous and intraperitoneal tumours and as deep tissue lesions resulting from intraperitoneal or intravenous inoculation. These findings demonstrate that GFP-transfected cells may be useful for imaging studies of superficial tumours where both excitation and emission wavelengths are able to penetrate tissues, whereas luciferase-transfected cells appear superior for imaging studies of primary and metastatic tumours in distant sites and deep tissues.

Regulation of cancer metastasis by stress pathways

The presence of activated oncogenes and/or inactivated tumor suppressor genes may result in constitutive activation of multiple transcription factors. This may be especially true in the early stages of tumor development. At advanced stages, however, uncontrolled tumor growth and the consequent development of a stress microenvironment, such as hypoxia, acidosis, and free radical overproduction, may further alter the activity of these transcription factors. Abnormal activation of and interplay between these factors lead to aberrant expression of multiple metastasis-related proteins and confer a tremendous survival and growth advantage to emerging metastatic variants. Understanding the expression and regulation of these molecules may shed more light on the biology of cancer metastasis as well as suggest new preventive and therapeutic approaches.

Establishment of red fluorescent protein-tagged HeLa tumor metastasis models: determination of DsRed2 insertion effects and comparison of metastatic patterns after subcutaneous, intraperitoneal, or intravenous injection

Metastasis is the leading cause of death in patients with cervical cancer. In this report, we establish novel fluorescent HeLa tumor metastasis models to determine whether HeLa transfected with the enhanced red fluorescent protein (DsRed2) gene in vitro and xenotransplanted through subcutaneous, intraperitoneal, or intravenous route into SCID mice would permit the detection of tumor micro-metastasis in vivo. Our results showed that DsRed2 insertions did not interfere the tumorigenic properties of HeLa cells. We also demonstrated that DsRed2-transduced HeLa cells maintained stable high-level DsRed2 expressions during their growth in vivo. DsRed2 fluorescence clearly demarcated the primary seeding place and readily allowed for the visualization of distant micro-metastasis and local invasion at the single-cell level. Lung metastasis, the major cause of cervical carcinoma related death, was found in all three models. However, intravenous injections of the HeLa-DsRed2 cells established tumor foci in the lung, while subcutaneous and intraperitoneal injections only established lung metastasis at single-cell levels. The DsRed2 tagged HeLa cancer model allowed detection and investigation of physiologically relevant patterns of cancer invasion and metastasis in vivo.

Green fluorescent protein imaging of tumour growth, metastasis, and angiogenesis in mouse models

We have developed a way of imaging metastases in mice by use of tumour cells expressing green fluorescent protein (GFP) that can be used to examine fresh tissue, both in situ and externally. These mice present many new possibilities for research including real-time studies of tumour progression, metastasis, and drug-response evaluations. We have now also introduced the GFP gene, cloned from bioluminescent organisms, into a series of human and rodent cancer-cell lines in vitro, which stably express GFP after transplantation to rodents with metastatic cancer. Techniques were also developed for transduction of tumours by GFP in vivo. With this fluorescent tool, single cells from tumours and metastases can be imaged. GFP-expressing tumours of the colon, prostate, breast, brain, liver, lymph nodes, lung, pancreas, bone, and other organs have also been visualised externally by use of quantitative transcutaneous whole-body fluorescence imaging. GFP technology has also been used for real-time imaging and quantification of angiogenesis.

Establishment of fluorescent lung carcinoma metastasis model and its real-time microscopic detection in SCID mice

Lung cancer is the most prevalent malignant tumor in the world. Metastasis of the disease causes death in lung cancer patients. Recent study has shown that multiple cascades of gene defects occur in lung cancer. In this report, we established a novel H1299/EGFP tumor model to determine whether H1299 transfected with the enhanced green fluorescent protein (EGFP) gene in vitro and xenotransplanted into SCID mouse lung would permit the detection of lung cancer micrometastasis in vivo. We demonstrated that EGFP-transduced H1299 cells maintained stable high-level EGFP expressions during their growth in vivo. EGFP fluorescence clearly demarcated the primary seeding place and readily allowed for the visualization of distant micrometastasis and local invasion at the single-cell level. Small metastatic and locally invasive foci, including those immediately adjacent to the tumor's leading invasive edge, were almost undetectable by routine hematoxylin and eosin staining and immunohistochemistry. The GFP tagged lung cancer model is superior for the detection and study of physiologically relevant patterns of lung cancer invasion and metastasis in vivo.

Inhibition of tumor growth and metastatic spreading by overexpression of inter-alpha-trypsin inhibitor family chains

The inter-alpha trypsin inhibitor (ITI) family is a group of proteins built up from different combinations of I light chain (ITI-L) and 3 highly homologous heavy chains (ITI-HI, -H2 and -H3). To investigate a potential role of the ITI family chains in cancer and metastasis spreading, we engineered human H460M cell lines expressing both the green fluorescent protein (GFP) and one of these chains. These clones were subcutaneously injected in athymic nude mice, and lung metastasis number and primary tumor weight were determined after 28 days. Expression of the ITI-L chain considerably decreased tumor weight and fluorescent lung metastasis number. ITI-HI and ITI-H3 chain expression induced a significant decrease of metastasis number, whereas no decrease of tumor weight could be detected. In vitro, ITI-L expression significantly decreased chemotaxis and ITI-HI and ITI-H3 expression increased cell attachment. These results argue for the antitumoral or antimetastatic properties of ITI-L, -HI and -H3 chains.