The fibroblast growth factor-2 is not essential for melanoma formation in a transgenic mouse model

Fibroblast growth factor 2 (FGF2) has been assigned a role in melanocyte proliferation and in development of human cutaneous melanoma. We have used a transgenic mouse melanoma model in combination with mice lacking mouse FGF2 to analyse the possible implication of FGF2 in melanomagenesis. Tyr::N-rasQ61K transgenic mice which are deficient for FGF2 and the tumor suppressors p16INK4a and p19ARF are hyperpigmented and develop cutaneous metastasizing melanoma, with no difference to mice wildtype for FGF2. We conclude from our data, that FGF2 is not essential for melanoma progression and metastasis.     

The fibroblast growth factor‐2 is not essential for melanoma formation in a transgenic mouse model

Fibroblast growth factor 2 (FGF2) has been assigned a role in melanocyte proliferation and in development of human cutaneous melanoma. We have used a transgenic mouse melanoma model in combination with mice lacking mouse FGF2 to analyse the possible implication of FGF2 in melanomagenesis. Tyr::N‐ras^Q61K transgenic mice which are deficient for FGF2 and the tumor suppressors p16^INK4a and p19^ARF are hyperpigmented and develop cutaneous metastasizing melanoma, with no difference to mice wildtype for FGF2. We conclude from our data, that FGF2 is not essential for melanoma progression and metastasis.     

Frequency, time and type of metastasis of different transplantable tumors in mice

The character of metastasis of 9 strains of transplantable mouse tumours in conventional subcutaneous inoculation was studied. There were differences in the frequency, intensity, and types of metastasis of different tumours. Periods of onset of metastases of Lewis lung carcinoma and RL-67, and also of sarcoma-37 were established. Sarcoma, Lewis and RL-67 lung carcinomas, adenocarcinoma of the colon AKATOL, Cloudman's melanoma and B-16 metastasized most intensively. Sarcoma-37 metastasizing into the regional and remote lymph nodes, Lewis lung carcinoma and melanomas metastasizing into the lungs, RL-67 lung carcinoma metastasizing into the lungs, kidneys, adrenal glands, ovaries, the heart, and also adenocarcinoma of the colon AKATOL metastasizing into the lymph nodes and the liver can be used as models for the research in the field of drug action upon metastases and the metastasis process.     

Development of Cutaneous Amelanotic Melanoma in the Absence of a Functional Tyrosinase

Lack of characteristic pigmentation and a wide range of clinical presentations account for the diagnostic challenge associated with amelanotic malignant melanoma. Experimental studies of this important human cancer have been hampered by the lack of an appropriate animal model. We previously described a transgenic mouse line (TG‐3) that spontaneously develops pigmented cutaneous melanoma. F1 crosses were generated with TG‐3 and several albino strains, and backcrosses were then made with the albinos. In the present report, we describe the restricted development and characterization of cutaneous amelanotic melanoma in these albino transgenic backcrosses. The incidence and behavior of melanoma in these mice were monitored. A high incidence (80–100%) of spontaneous amelanotic melanoma was observed in albino transgenic mice derived from backcrosses with A, AKR, FVB, and SJL strains. The lowest incidence (30%) was obtained in BALB/c‐derived crosses. No tumors were observed in non‐transgenic mice. Immunohistochemical and western blot analyses using antibodies against three melanocyte‐specific markers of the tyrosinase family of proteins confirmed that the tumors were composed of amelanotic melanocytes. Furthermore, the presence of numerous premelanosomes observed by electron microscopy further supported the melanocytic origin of these tumors. Previous in vitro studies on human melanoma have suggested that cutaneous amelanotic melanoma was evolving from pre‐existing pigmented cutaneous melanoma. However, our results indicate that it can occur directly, as evidenced by the appearance of cutaneous amelanotic melanoma in the tyrosinase‐deficient albino mice. These mice represent a potentially valuable model for studying the mechanistic, diagnostic, and therapeutic features of this highly malignant neoplasm.     

In vivo cell electrofusion

In vitro electrofusion of cells brought into contact and exposed to electric pulses is an established procedure. Here we report for the first time the occurrence of fusion of cells within a tissue exposed in vivo to permeabilizing electric pulses. The dependence of electrofusion on the ratio of applied voltage to distance between the electrodes, and thus on the achievement of in vivo cell electropermeabilization (electroporation) is demonstrated in the metastasizing B16 melanoma tumor model. The kinetics of the morphological changes induced by cell electrofusion (appearance of syncytial areas or formation of giant cells) are also described, as well as the kinetics of mitosis and cell death occurrence. Finally, tissue dependence of in vivo cell electrofusion is reported and discussed, since electrofusion has been observed neither in liver nor in another tumor type. Particular microenvironmental conditions, such as the existence of reduced extracellular matrices, could be necessary for electrofusion achievement. Since biomedical applications of in vivo cell electropermeabilization are rapidly developing, we also discuss the influence of cell electrofusion on the efficacy of DNA electrotransfer for gene therapy and of antitumor electrochemotherapy, in which electrofusion could be an interesting advantage to treat metastasizing tumors.     

Development of cutaneous amelanotic melanoma in the absence of a functional tyrosinase.

Lack of characteristic pigmentation and a wide range of clinical presentations account for the diagnostic challenge associated with amelanotic malignant melanoma. Experimental studies of this important human cancer have been hampered by the lack of an appropriate animal model. We previously described a transgenic mouse line (TG-3) that spontaneously develops pigmented cutaneous melanoma. F1 crosses were generated with TG-3 and several albino strains, and backcrosses were then made with the albinos. In the present report, we describe the restricted development and characterization of cutaneous amelanotic melanoma in these albino transgenic backcrosses. The incidence and behavior of melanoma in these mice were monitored. A high incidence (80-100%) of spontaneous amelanotic melanoma was observed in albino transgenic mice derived from backcrosses with A, AKR, FVB, and SJL strains. The lowest incidence (30%) was obtained in BALB/c-derived crosses. No tumors were observed in non-transgenic mice. Immunohistochemical and western blot analyses using antibodies against three melanocyte-specific markers of the tyrosinase family of proteins confirmed that the tumors were composed of amelanotic melanocytes. Furthermore, the presence of numerous premelanosomes observed by electron microscopy further supported the melanocytic origin of these tumors. Previous in vitro studies on human melanoma have suggested that cutaneous amelanotic melanoma was evolving from preexisting pigmented cutaneous melanoma. However, our results indicate that it can occur directly, as evidenced by the appearance of cutaneous amelanotic melanoma in the tyrosinase-deficient albino mice. These mice represent a potentially valuable model for studying the mechanistic, diagnostic, and therapeutic features of this highly malignant neoplasm.     

Small rodent models of hepatitis B and C virus replication and pathogenesis

The narrow host range of infection supporting the long-term propagation of hepatitis B and C viruses is a major limitation that has prevented a more thorough understanding of persistent infection and t...     

Animal models of melanoma: an HGF/SF transgenic mouse model may facilitate experimental access to UV initiating events

Cutaneous malignant melanoma, the most lethal of the skin cancers, known for its intractability to current therapies, continues to increase in incidence, providing a significant public health challenge. There is a consensus that skin cancer is initiated by sunlight exposure. For non-melanoma skin cancer there is substantial evidence that chronic exposure to the ultraviolet B radiation (UVB) (280-320 nm) portion of the sunlight spectrum is responsible. Experimentally, UVB is mutagenic and chronic UVB exposure can cause non-melanoma skin cancer in laboratory animals. Non-melanoma tumors in animals and in humans show characteristic UVB signature lesions in the tumor suppressor p53 and/or in the patched (PTCH) gene. An action spectrum or wavelength dependence for squamous cell carcinoma in the mouse shows a major peak of efficacy in the UVB. For malignant melanoma, however, the situation is unclear and the critical direct target(s) of sunlight in initiating melanoma and even the wavelengths responsible are as yet unidentified. This lack of information is in major part a result of a paucity of animal models for melanoma which recapitulate the role of sunlight in initiating this disease. The epidemiology of melanoma differs significantly from non-melanoma skin cancer. Intense sporadic sunlight exposure in childhood, probably exacerbated by additional adult exposure, is associated with elevated melanoma risk. Melanoma is also a disease of gene-environment interactions with underlying genetic factors playing a significant role. These major differences indicate that extrapolation from information for non-melanoma skin cancer to melanoma is unlikely to be useful. We summarize in this review the experimental information available on the role of UV radiation in melanoma and give an overview of animal melanoma models. A new model derived by neonatal UV irradiation of hepatocyte growth factor/scatter factor (HGF/SF) transgenic mice is described which recapitulates the etiology, the histopathology and molecular pathogenesis of human disease. It is anticipated that the HGF/SF transgenic model will provide a means to access the mechanism(s) by which sunlight initiates this lethal disease and provide an appropriate vehicle for derivation of appropriate therapeutic and preventive strategies.     

Synphilin suppresses α-synuclein neurotoxicity in a Parkinson's disease Drosophila model

Parkinson's disease (PD) is the second most common neurodegenerative disorder in humans. It affects 1% of the population over 65-years old. Its causes are environmental and genetic. As the world population ages, there is an urgent need for better and more detailed animal models for this kind of disease. In this work we show that the use of transgenic Drosophila is comparable to more complicated and costly animal models such as mice. The Drosophila model behaves very similar to the equivalent transgenic mice model. We show that both Synphilin-1 and α-synuclein are toxic by themselves, but when co-expressed, they suppress their toxicity reciprocally. Importantly, the symptoms induced in the fly can be treated and partially reverted using standard PD pharmacological treatments. This work showcases Drosophila as a detailed and multifaceted model for Parkinson's disease, providing a convenient platform in which to study and find new genetic modifiers of PD. genesis 49:392-402, 2011.     

Localized Modeling of Biochemical and Flow Interactions during Cancer Cell Adhesion

This work focuses on one component of a larger research effort to develop a simulation tool to model populations of flowing cells. Specifically, in this study a local model of the biochemical interactions between circulating melanoma tumor cells (TC) and substrate adherent polymorphonuclear neutrophils (PMN) is developed. This model provides realistic three-dimensional distributions of bond formation and attendant attraction and repulsion forces that are consistent with the time dependent Computational Fluid Dynamics (CFD) framework of the full system model which accounts local pressure, shear and repulsion forces. The resulting full dynamics model enables exploration of TC adhesion to adherent PMNs, which is a known participating mechanism in melanoma cell metastasis. The model defines the adhesion molecules present on the TC and PMN cell surfaces, and calculates their interactions as the melanoma cell flows past the PMN. Biochemical rates of reactions between individual molecules are determined based on their local properties. The melanoma cell in the model expresses ICAM-1 molecules on its surface, and the PMN expresses the β-2 integrins LFA-1 and Mac-1. In this work the PMN is fixed to the substrate and is assumed fully rigid and of a prescribed shear-rate dependent shape obtained from micro-PIV experiments. The melanoma cell is transported with full six-degrees-of-freedom dynamics. Adhesion models, which represent the ability of molecules to bond and adhere the cells to each other, and repulsion models, which represent the various physical mechanisms of cellular repulsion, are incorporated with the CFD solver. All models are general enough to allow for future extensions, including arbitrary adhesion molecule types, and the ability to redefine the values of parameters to represent various cell types. The model presented in this study will be part of a clinical tool for development of personalized medical treatment programs.     

Mammalian genes expressed in Drosophila: a transgenic model for the study of mechanisms of chemical mutagenesis and metabolism.

Mammalian cytochrome P450s provide our first line of defence against the toxic effects of environmental chemicals. Ironically these enzymes also convert some compounds to their ultimate toxic or mutagenic species. Our knowledge of these mammalian enzymes and the role they play in chemical toxicity and mutagenesis has stemmed mostly from in vitro studies. In order to establish the role of specific enzymes in the toxicological response in vivo we have generated transgenic Drosophila which express mammalian cytochrome CYP2B1, which is a member of a large gene family encoding several important drug metabolising enzymes. The gene was fused to a Drosophila promoter which confers expression in the larval fat body. Using the Somatic Mutation And Recombination Test (SMART) we have demonstrated that transgenic larvae expressing the P450 are hypersensitive to the anticancer drug cyclophosphamide, a procarcinogenic substrate which is activated by the enzyme. This work demonstrates the potential of such transgenic Drosophila strains as an in vivo model for studying the role of specific mammalian drug metabolising enzymes in the pathways and metabolic cascades associated with the action of cytotoxic and carcinogenic chemicals, and also the chemical properties of specific classes of mutagen to be determined.     

Transgenic mouse models for tumors of melanocytes and retinal pigment epithelium

Cutaneous and ocular melanomas are due to malignant transformation of neural crest-derived melanocytes. The rising incidence of this tumor in humans has stimulated experiments to devise suitable mouse models. In the past years, transgenic mouse lines have been generated using different oncogenes - Ha-ras, SV40 T antigen (Tag), ret - which develop benign lesions of melanocytes, melanoma, and/or eye tumors. Pigment cell tumors in humans, although rather rare, can also develop from the retinal pigment epithelium (RPE), a cell layer of neuroectodermal origin. We, therefore, established transgenic models for this ocular tumor. Regulated by the promoter of tyrosinase-related protein-1 (TRP-1), two oncogenes, ret and SV40 Tag, were targeted to the developing RPE in transgenic mice. The TRP-1/ret transgenic mice displayed microphthalmia and benign tumors of the RPE. Expression of SV40 T antigen (TRP-1/Tag) led to malignant tumors, which were invasive and metastasized to inguinal lymph node and spleen.     

Proliferation and Neoplastic Transformation of Pigment Cells in Metallothionein/ret Transgenic Mice

Although melanoma is a common human disease, there were few animal models in which melanoma developed at high incidence. To date, the Xiphophorus fish has been used as a model system to study melanoma formation. Studies on this fish showed the presence of a dominant oncogene, Tu, which encodes a transmembrane, tyrosine kinase of epidermal growth factor receptor type (Wittbrodt et al., Nature, 341:415–421, 1989). Recently, we succeeded in establishing novel transgenic mouse lines in which melanosis and melanocytic tumors developed stepwise by introducing another transmembrane tyrosine kinase oncogene, ret (Iwamoto et al., EMBO J., 10:3167–3175, 1991). In our transgenic mice, high levels of expression of the ret transgene induced proliferation and neoplastic transformation of melanin-producing cells. In addition, crossbreeding experiments between transgenic mice and W^v mice showed that the ret oncogene can also induce melanogenesis and melanocyte development in W^v/W^v mice.     

Two-photon microscopy of host–pathogen interactions: acquiring a dynamic picture of infection in vivo

Two-photon (2P) microscopy has become increasingly popular among immunologists for analysing single-cell dynamics in tissues. Researchers are now taking 2P microscopy beyond the study of model antigen systems (e.g. ovalbumin immunization) and are applying the technique to examine infection in vivo . With the appropriate fluorescent probes, 2P imaging can provide high-resolution spatio-temporal information regarding cell behaviour, monitor cell functions and assess various outcomes of infection, such as host cell apoptosis or pathogen proliferation. Imaging of transgenic and knockout mice can be used to probe molecular mechanisms governing the host response to infection. From the microbe side, imaging genetically engineered mutant strains of a pathogen can test the roles of specific virulence factors in pathogenesis. Here, we discuss recent work that has applied 2P microscopy to study models of infection and highlight the tremendous potential that this approach has for investigating host–pathogen interactions.     

Inflammation in transgenic mouse models of neurodegenerative disorders

Much evidence is available that inflammation contributes to the development of neurodegenerative diseases such as Alzheimer's disease, Parkinson's disease and Huntington's disease. Our review investigates how well current mouse models reflect this aspect of the pathogenesis.Transgenic models of AD have been available for several years and are the most extensively studied. Modulation of cytokine levels, activation of microglia and, to a lesser extent, activation of the complement system have been reported. Mouse models of PD and HD so far show less evidence for the involvement of inflammation.An increasing number of transgenic mouse strains is being created to model human neurodegenerative diseases. A perfect model should reflect all aspects of a disease. It is important to evaluate continuously the models for their match with the human disease and reevaluate them in light of new findings in human patients.Although none of the transgenic mouse models recapitulates all aspects of the human disorder they represent, all models have provided valuable information on basic molecular pathways. In particular, the mouse models of Alzheimer disease have also led to the development of new therapeutic strategies such as vaccination and modulation of microglial activity.     

Self-tolerance and autoimmunity

Studies of self-tolerance and autoimmunity have moved rapidly into new arenas. These include the definition of at least two mechanisms for tolerance induction in both T and B cells, the creation of new disease-susceptible strains such as the HLA-B27 transgenic rats, the creation of new disease-resistant strains such as I-E or I-Ak NOD transgenic mice, and the precise definition of both antigen and antigen receptor for pathogenic lymphocytes in some models. More effective therapies for autoimmune disease should result from the knowledge gained.     

Altered surface glycoproteins in melanoma cell variants with reduced metastasizing capacity selected for resistance to wheat germ agglutinin

Variants of B 16-F 1 mouse melanoma cells selected for resistance to wheat germ agglutinin (WGA) toxicity $\text{in}\text{vitro}$ were found to have undergone a stable surface change correlated both to lectin resistance and reduced metastasizing potential. The surface alteration, as indicated by the increased electrophoretic mobilities of several lactoperoxidase-iodinated cell surface proteins in SDS-PAGE, was restricted to polypeptides able to interact with WGA. The availability of lectin-resistant melanoma cell variants having altered metastasizing behavior provides a promising approach to studies of the role of specific cell surface components in the metastasizing process.     

Recent advances in sunlight-induced carcinogenesis using the Xiphophorus melanoma model

Unlike breast and prostate cancers, the nature and sequence of critical genetic and epigenetic events involved in the initiation and progression of melanoma are not well understood. A contributing factor to this dilemma, especially given our current understanding of the importance of UV light in melanoma etiology, is the lack of quality UV-inducible melanoma animal models. In this study we elaborate on the capability of UV light to induce cutaneous malignant melanomas (CMM) in Xiphophorus fishes, which were previously found to develop melanomas after acute neonatal UVB irradiation. In two separate tumorigenesis experiments, we exposed adult Xiphophorus hybrids to either acute UVB irradiations (5 consecutive daily treatments) or chronic solar irradiations (continuous UVA/UVB treatment for 9 months). Acute adult UVB irradiation resulted in the significant induction of melanomas, and moreover, this induction rate is equivalent to that of animals exposed to acute neonatal UVB irradiation. This study represents the first evidence that acute adult UVB irradiation, in the absence of any early life exposures, induces CMM. Similar to the findings conducted on other divergent melanoma models, including HGF/SF transgenic mice and Monodelphis domestica, prolonged chronic solar UV was not a factor in melanomagenesis.     

memA/DRS, a putative mediator of multiprotein complexes, is overexpressed in the metastasizing human melanoma cell lines BLM and MV3

memA was isolated by subtractive hybridization in which the mRNA repertoire was compared in a panel of human melanoma cell lines with different metastasizing potential. Expression of memA mRNA is elevated in the highly metastasizing human melanoma cell lines and derived xenografts, as compared with the non-metastasizing ones. In a collection of human tumor cell lines and melanoma metastasis lesions, memA mRNA expression could be detected in the A-431 (epidermoid carcinoma), HT-1080 (fibrosarcoma), JEG-3 and JAR (choriocarcinomas) cell lines and in three out of 11 melanoma metastasis lesions. The distribution of memA mRNA in a collection of healthy human organs is also tissue restricted. Sequence analysis revealed that the MEMA protein is identical with a 160 kDa nuclear 'domain rich in serines' (DRS) protein occurring free in the nucleoplasm and in U2-ribonucleoprotein structures. MEMA is also homologous to pinin, a 140 kDa protein associated with the desmosome-intermediate filament complex, and to a 32 kDa porcine neutrophilic protein that was copurified with components of the NADPH-oxidase enzyme complex. The encoded amino acid sequence predicts that the MEMA protein has three coiled-coil domains, one glycine loop domain, is very hydrophilic and contains regions rich in glutamine/proline, glutamic acid and serine residues.     

Radiosensitivity of murine and human melanoma cells: a comparative study with different models

The in vitro radiosensitivity of one murine melanoma cell line (Cloudman S91 CCL 53.1) and three human melanoma cell strains (C8146C, C8161, and R83-4) were studied. Cells were irradiated by single dose X-rays and plated either in agar or on plastic. The survival curves were fitted by the single-hit multitarget, two-hit multitarget, and quadratic models. Multiple comparisons of the residual sum of squares suggested that the two-hit model was clearly inferior to the single-hit and quadratic models. No statistically significant difference was suggested for either the single-hit or quadratic models. Furthermore, on examination of the differences in correlations between the observed and predicted values, the residual plots (observed minus predicted over dose) failed to suggest a clear advantage of either the single-hit multitarget or the quadratic models. Either model could be recommended for analysis of in vitro radiation data.