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Using Genetically Engineered Mouse Models of Cancer to Aid Drug Development: An Industry Perspective

Authors' Affiliation: Genentech, Inc., South San Francisco, California

Requests for reprints: Leisa Johnson, Genentech, Inc., Room 12381, 1 DNA Way, South San Francisco, CA 94080. Fax: 1-650-225-6412; E-mail: leisaj{at}gene.com.

	Abstract

Top Abstract What Is a Good... Modeling High-Impact Cancers... Using GEMMs to Inform... Challenges Ahead, What Needs... References

 
Recent developments in the generation and characterization of genetically engineered mouse models of human cancer have resulted in notable improvements in these models as platforms for preclinical target validation and experimental therapeutics. In this review, we enumerate the criteria used to assess the accuracy of various models with respect to human disease and provide some examples of their prognostic and therapeutic utility, focusing on models for cancers that affect the largest populations. Technological advancements that allow greater exploitation of genetically engineered mouse models, such as RNA interference in vivo, are described in the context of target and drug validation. Finally, this review discusses stratagems for, and obstacles to, the application of these models in the drug development process.

	What Is a Good Mouse Model of Cancer? What Are the Tools for Making One?

Top Abstract What Is a Good... Modeling High-Impact Cancers... Using GEMMs to Inform... Challenges Ahead, What Needs... References

 
Somatic alterations in oncogenes and/or tumor suppressor genes in normal tissues are thought to initiate human cancer, followed by a stepwise accumulation of molecular and cellular changes that ultimately result in a malignancy (3). During this progression, tumor cells interact with and co-opt various components of the surrounding microenvironment, including infiltrating immune cells, vascular and lymphatic networks, and the extracellular matrix (4). Modeling the interplay between progressively neoplastic cells and the surrounding tissue microenvironment is essential to accurately test therapeutics targeted at various players that support the tumor infrastructure (5). The correct reproduction of these events within a mouse requires genetic manipulations that faithfully recapitulate somatic events in adult humans in the appropriate population of adult mouse cells. In addition, the neoplastic progression resulting from these genetic perturbations in mice should phenocopy the human cancer at the histopathologic and molecular level, as well as respond similarly to known therapeutics for the disease. Finally, desirable logistical variables for models to serve as preclinical platforms include high disease penetrance and consistent, stepwise progression over a timeframe that is amenable to experimental therapeutics. Although many existing GEMMs do not meet all of these criteria, several of these models remain highly useful platforms for the mechanistic and therapeutic studies of pathway alterations within cancers, even if the evidenced disease does not completely reflect that in the human.

Techniques used for the facile introduction of alterations in the mouse genome range from germline (constitutive) transgenesis and gene knockouts to more common and sophisticated means of exerting temporal and spatial control of gene expression or attenuation (reviewed in refs. 6–8). Viruses offer additional means to mediate both spatial and temporal gene regulation; the two most commonly used are adenoviruses and retroviruses. Adenoviruses expressing Cre recombinase have been used to model lung and colon cancer (9–12). Another approach to deliver genes to somatic cells in vivo uses retroviral transduction via the TVA receptor for subgroup A avian leukosis virus (13, 14). The ability to introduce multiple potentially cooperating genes into a tissue of interest makes the RCAS/TVA system eminently attractive (15). Similarly, lentivirus-mediated transgenesis represents a powerful alternative to conventional technologies for making GEMMs (16). Methods to engender consistent viral infection and integration within embryos present significant challenges; however, the successful use of viruses as tools in vivo requires appropriate delivery to the target tissue or tumor of interest. Efficient viral infection has been shown in readily accessible adult organs, such as the skin, lung, and colon (9–12, 17); surgical techniques are currently emerging for virus delivery to additional internal organs, e.g., prostate (18) and pancreas,¹ thereby expanding the usefulness that these unique, titratable, and highly desirable systems offer.

	Modeling High-Impact Cancers with GEMMs

Top Abstract What Is a Good... Modeling High-Impact Cancers... Using GEMMs to Inform... Challenges Ahead, What Needs... References

 
Lung cancer. The majority of cancer deaths worldwide are due to lung cancer, which remains a relatively intractable disease in terms of both detection and treatment (19). Most lung cancers are associated with tobacco use, albeit the rate of incidence is rising in nonsmokers. Lung cancers are divided into two main classes based on clinical behavior and histologic criteria: non–small cell lung cancer (NSCLC), which afflicts 80% of patients, and small cell lung cancer (SCLC), which accounts for 20% of cases (20). NSCLC is further categorized into three main histologic subtypes: adenocarcinoma, squamous cell carcinoma, and large cell carcinoma. The differences between NSCLC and SCLC may be explained, in part, by the distinct patterns of chromosomal and/or gene alterations associated with each class. Genetic lesions associated with the initiation and promotion of NSCLC include mutations, amplifications, and/or overexpression of K-RAS2 (20-30%), EGFR (20%), c-MYC (8-20%), and CCND1 (40-50%), as well as alterations affecting the tumor-suppressor genes P53 (50%), p16/INK4A (50-75%), and RB (15-30%; ref. 21). The large variation in mutation incidences may reflect differences among histologic subtypes, gender, ethnicity, and/or differences between primary tumors and established cell lines. In contrast, some of the primary players involved in the etiology of SCLC include aberrations in the RB (90%), P53 (80%), p14/ARF (65%), and PTEN (10-20%) tumor suppressors; MYC family DNA amplification (25%); as well as mutations in the c-MET proto-oncogene (12.5%; ref. 21).

Targeted activation of the K-RAS proto-oncogene (9, 12, 22, 23) and simultaneous inactivation of RB and p53 (10) in the mouse lung have resulted in GEMMs that recapitulate many of the characteristics of NSCLC (subtype adenocarcinoma) and SCLC, respectively (Table 1 ; reviewed in ref. 24). Satisfyingly, the RNA expression profile of NSCLC in the K-ras^G12DLA/+ model shows a signature closely resembling that observed in human lung adenocarcinomas (25). These models have made significant strides toward modeling more aggressive lung disease and metastasis and will continue to improve as relevant mutations are analyzed in the appropriate combinations (26). Lung cancers show a high frequency of different histologic subtypes within the same tumor, leading to the hypothesis that these lesions arise from a common progenitor/stem cell–like compartment within the airway epithelium. The recent discovery of the bronchioalveolar stem cell and its role in the development of lung adenocarcinoma in the K-ras^LSLG12D/+ mouse model of NSCLC (27) could prove invaluable in further refining tumor classification and aiding our understanding of lung cancer etiology and biology. In summary, these more refined mouse models of lung cancer fulfill several of the criteria described for GEMMs. What remains to be elucidated in these models are the contributions of other mutations found in the human diseases, the identity of the cell type(s) of origin of SCLC, and the logistics of holding out large-scale RNA interference (RNAi) and preclinical trials examining experimental therapeutics of interest.

Several GEMMs for breast cancer have been developed, the majority involving overexpression of oncogenes via the long-terminal repeat of the mouse mammary tumor virus (reviewed in ref. 30). Some of the overexpressed genes in these models are c-Myc, cyclin D1, Her2, and Wnt-1, the latter indicating a role for this pathway in mammary tumorigenesis (31). In particular, tumors overexpressing Wnt-1 seem to show heterogenous ER status, making the model relevant to the study of both ER-positive and ER-negative malignancies (32, 33). Although most GEMMs for breast cancer develop ER-negative tumors, a recent study by Wijnhoven et al. (34) presents evidence that the dominant-negative P53^R270H allele can predispose mice to ER-positive mammary tumors. Some of the challenges in making physiologically relevant GEMMs for mammary cancer are the shortage of endogenous promoters specific to the breast epithelium and the complications introduced by promoters that are hormone and pregnancy regulated. Recent reports by Hu et al. (35) and Welm et al. (36) describe a model that uses the isolation, manipulation, and transplantation of primary mouse epithelial cells; the latter study identified a role for the c-Met oncoprotein in mammary carcinogenesis and showed cooperation with c-Myc in the generation of heterogenous lesions that express early mammary progenitor cell markers (37). This system presents an interesting alternative to the abundance of conventional models, many of which exhibit notable differences in pathology and metastasis from the human disease. Extensive studies have gathered and compared the gene expression patterns in several GEMMs of breast cancer, resulting in a list of tumor signature genes, subclusters of which are specific to particular models or groups of models (38). Several technical hurdles, however, have affected the ability to make meaningful comparisons between microarray-based gene expression profiles from mouse and human mammary tumors. Serial Analysis of Gene Expression analysis of p53-deficient transplant tumors in mice has identified 72 deregulated transcripts that are common between mammary tumors in mice and humans (35). Further comparative analyses are needed to validate existing GEMMs of breast cancer and guide the development of improved models.

Prostate cancer. Cancer of the prostate is the most common malignancy in men and the second leading cause of male cancer deaths (19). The molecular genetics of prostate carcinogenesis has been difficult to define and most data come from the analysis of chromosomal losses and candidate tumor-suppressor genes within these loci. These studies implicate the tumor suppressors PTEN (10%), RB (10%), P27, and P16/INK4A as well as perturbations in the Wnt, Hedgehog, and Notch developmental pathways in tumor initiation and progression (20, 21). Amplification of MYC and overexpression of several fibroblast growth factor family members, including FGF2, FGF7, and FGF10, are associated with progression in humans and mice (28). Acquisition of androgen independence and loss of P53 are found in advanced carcinoma and metastasis; recently, p53-dependent cellular senescence has been shown to restrict tumorigenesis initiated by PTEN loss (39). NKX3.1 is a homeodomain transcription factor that is down-regulated in up to 90% of both preinvasive and invasive prostate cancer cell (40). Prostate-specific inactivation of the mouse orthologue leads to prostatic intraepithelial neoplasia (41), indicating that NKX3.1 may serve as a gatekeeper for prostate cancer analogous to the role of APC in colon carcinogenesis.

The identification of prostate-specific genes coupled with the generation of robust Cre-expressing mouse lines have enabled the prostate-restricted ablation of various tumor suppressors that cannot be fully investigated via conventional knockouts (due to embryonic lethality). As with breast cancer, modeling prostate carcinogenesis in the mouse is complicated by the morphologic differences between the human and mouse organs as well as the challenges involved in detecting and following metastasis, which is the ultimate cause of mortality in most humans. Historically, various transgenic models overexpressing SV40 large T antigen, or various oncogenes (e.g., Myc) and growth factors implicated in prostate cancer, have shown neoplastic initiation (28). Only a subset of these models, however, exhibit progression to invasive carcinogenesis and metastasis, albeit infrequently to the bone, the major site in humans. Recent compound analyses of prostate-specific conditional knockouts of the NKX3.1, PTEN, P27, and P53 tumor suppressors show great promise for improved models of multistage disease and metastasis (39, 42, 43). Although the detailed characterization of these models is ongoing, these developments set the stage for further analyses of various players incriminated in these processes, and for the refinement of methods and markers for the detection of primary and metastatic lesions. Additionally, as in the mammary gland, the importance of the stroma in prostate tumor development (44) begs the need for the identification of means to manipulate this component in vivo.

Colon cancer. Gastrointestinal cancers, particularly those of the colon and rectum, are ranked third in the Western world in terms of annual new occurrences as well as the number of fatalities (19). Several of the common genetic lesions in colon cancer have been extensively mapped and studied (45). The most notable alterations include disruption of Wnt/ß-catenin signaling via mutations in the APC gene found in 90% of familial cancers and 30% to 50% of sporadic tumors, activation of K-RAS (30%), and phosphatidylinositol 3-kinase (20%), as well as loss of P53 function (45%; refs. 20, 21). In addition, mutations in the SMAD family of proteins, particularly DPC4/SMAD4, are also found in 40% of tumors and thought to result in altered transforming growth factor-ß signaling (46). A small subset of hereditary tumors, named hereditary nonpolyposis colon cancers, relies on the loss of DNA replication fidelity as a key driver of the disease (47). Microsatellite instability is a hallmark of this subclass of tumors and is observed in 15% of sporadic colon tumors, which also seem to harbor mutations in the transforming growth factor-ß type II receptor (48). Diet and lifestyle also seem to play a significant role in the susceptibility to gastrointestinal neoplasia (49, 50).

The APC^Min/+ model was the first genetic model of intestinal tumorigenesis and continues to be one of the most used, particularly for chemopreventive studies (reviewed in refs. 51, 52). These and other APC mutant mice develop multiple intestinal adenomas as a result of similar mutations in the APC gene as found in patients that develop familial adenomatous polyposis (53). Key limitations of the mouse model(s), however, include the location of the polyps (predominantly restricted to the small intestine; ref. 54) and the rare occurrence of malignant progression to adenocarcinoma. Most APC mutant strains perish at 14 to 16 weeks of age, afflicted with anemia from multiple polyp bleeds; colonic adenocarcinomas are rarely observed in these mice and metastases are absent. This abrogation of lifespan is thought to prohibit sufficient time for the accumulation of additional genetic lesions that cooperate in promoting later-stage disease. Indeed, the hypomorphic APC^1638N/+ mutant mice, which live beyond 1 year of age, develop fewer initial small intestinal polyps and subsequent malignant adenocarcinoma (55); selective APC attenuation in the large intestine results in adenoma and invasive adenocarcinoma of the colorectum (11). In contrast, the locations of intestinal lesions in mice with alterations in transforming growth factor-ß signaling vary, in particular.

SMAD3^–/– mice develop colonic adenocarcinoma and metastases, albeit in an APC-independent manner (56). Interestingly, SMAD4^+/–;APC^716/+ compound mutant mice present with more advanced intestinal lesions, supporting the hypothesis based on human genetic data that these two pathways cooperate during tumor progression (57). The high frequency of APC mutations in both premalignant lesions and sporadic colon cancer cases has implicated APC as a "gatekeeper" gene in gastrointestinal tumor initiation. Furthermore, genetic evidence suggests that the order of gene mutation is important in human colon carcinogenesis, i.e., mutations in K-RAS and P53 cooperate in tumor progression but seem insufficient for tumor initiation (reviewed in ref. 45). Thus, accurate recapitulation of this progression in a GEMM will require careful spatially and temporally controlled introduction of additional genetic lesions onto an APC mutant background. Given the pleiotropic nature of transforming growth factor-ß signaling, it will also be important to reproduce the exact mutations found in human tumors as opposed to complete deletion of the gene(s).

Ovarian cancer. Epithelial ovarian cancer is the deadliest malignancy of the female reproductive tract and ranks fourth in causing female cancer mortality (19). The current lack of means to accurately detect and diagnose ovarian neoplasia makes a strong case for the development of appropriate models for this disease. In the heritable form of ovarian cancer, women with mutations in BRCA1 or BRCA2 show an increased predisposition to ovarian tumors in addition to breast cancer; interestingly, ovarian cancers are also observed in patients with hereditary nonpolyposis colon cancer (see Colon Cancer section; ref. 20). Genetic alterations found in sporadic ovarian cancer include loss of P53 (55%) and PTEN (5%) as well as mutations in K-RAS (15%), B-RAF (15%), and ß-catenin (10%; ref. 21). Overexpression of Her2/Neu, phosphatidylinositol 3-kinase, Akt, and c-Myc are also observed in tumors (28).

Various GEMMs for ovarian cancer generated over the last 2 years exhibit features of one or more of the predominant subtypes of the disease. Orsulic et al. (58) used the RCAS-TVA system to overexpress oncogenes in ovarian epithelial cells ex vivo, followed by implantation within the ovarian bursa. Both this model, and another in which female transgenic mice express the transforming region of SV40 under the control of the Mullerian inhibitory substance type II receptor gene promoter (59), develop poorly differentiated and undifferentiated tumors, with a percentage of serous adenocarcinomas, the major subtype observed in humans. A similar phenotype is observed in a virally induced model of simultaneous, Cre-mediated P53, and RB inactivation (60), and all three models show metastases consistent with human pathology. Recently, Dinulescu et al. (61) have used similar methodology to simultaneously activate and/or inactivate conditional alleles of K-RAS^G12D and PTEN, respectively, within the ovarian surface epithelium. Approximately half of the K-RAS^LSLG12D/+ mice developed peritoneal endometriosis; the ovarian surface of all these mice and 62% of the PTEN^Fl/Fl mice exhibited benign proliferative lesions with typical endometrioid glandular morphology. Importantly, all K-RAS^LSLG12D/+;PTEN^Fl/Fl compound mice developed invasive endometrioid ovarian adenocarcinomas with many of the hallmarks associated with the corresponding human disease, including lung metastases (43%), thus supporting clinical data indicating a role for PTEN in the progression of ovarian endometriosis to endometrioid ovarian carcinoma (62). These last two models fulfill many of the criteria described for ideal GEMMs recapitulating sporadic carcinogenesis in adults and should greatly facilitate our understanding of the etiology and pathology of ovarian cancers.

Pancreatic cancer. Until recently, the dearth of histologically accurate models of pancreatic carcinogenesis represented a major stumbling block in the preclinical investigation of this lethal disease (63). Olive and Tuveson (8) present an overview of mouse models of pancreatic cancer and the GEMMs thereof in this issue; we summarize relevant GEMMs (64–66) in Table 1.

Tumor angiogenesis. One of the most successful molecular therapies to target cancer in the recent past has been the advent of antiangiogenic drugs (67). With the approval of bevacizumab (Avastin) and several other antiangiogenic agents currently in clinical trials, the need for improved models of tumor angiogenesis has become apparent. The most widely used and relatively predictive GEMM for tumor angiogenesis is the RIP1Tag2 model (68), a SV40 T-antigen-driven multistage pancreatic insulinoma model that has also served as a prototype for the design and execution of preclinical trials in the setting of multistep tumor progression (69). Similar principles have been applied to the testing of antiangiogenic drug candidates in an industry setting.² Studies conducted in the RIP1-Tag2 model set the precedent for the design of preclinical trials that yield valuable information on pharmacodynamics, pharmacokinetics, and the mechanism(s) of drug action in the endogenous tumor microenvironment.

	Using GEMMs to Inform and Facilitate Clinical Drug Development

Top Abstract What Is a Good... Modeling High-Impact Cancers... Using GEMMs to Inform... Challenges Ahead, What Needs... References

 
Target and drug validation, mechanisms of action. The last decade has seen increased investigation of hitherto unexplored cancer pathways and the identification of an assortment of novel candidate target molecules for therapeutic intervention (3). GEMMs that accurately model the perturbation of such pathways can be used to fully explore the scope and consequences of these disruptions on the tumor cells and the surrounding milieu (5). These models also afford the unique ability to analyze the expression and role of a given cancer target/pathway at different stages of neoplastic progression.

Cell lines derived from tumors that arise in GEMMs present a unique opportunity to study the parallels and differences that arise in a tissue culture environment. Historically, it has not been possible to determine the relative contributions of tumor heterogeneity vis-a-vis the in vitro environment to the divergence of the genotypes and phenotypes in human tumor-derived cell lines. Because the GEMM tumor from which any line is derived is readily accessible, the genotype and phenotype of such cells can be constantly monitored for divergence from in vivo behavior. Also, tumor heterogeneity can potentially be recapitulated in vitro with the ability to derive multiple cell lines from a given model. Logistically, cell lines that preserve the pathway alterations found in vivo and consequent phenotypes in vitro can be used as first-pass screening tools to select and study candidate targets, pathways, and drugs for the more time- and labor-intensive in vivo experiments (Fig. 1 ). The use of RNAi, both in vitro and in vivo, is a significant advancement in the functional analysis of candidate genes involved in neoplasia (70). Short hairpin RNA (shRNA)–mediated gene knockdown can be used to interrogate the relevance of a target(s) or other pathway members of interest in tumor initiation, promotion, and survival, as well as interactions with other pathways. As depicted in Fig. 1, this validation can occur first in relevant tumor cell lines, if available, followed by analysis in vivo.

View larger version (60K): [in this window] [in a new window]   Fig. 1. Platforms for assessing and prioritizing target validation and mechanism of action in vitro and in vivo. Tumors from GEMMs can be used to generate cell lines and were analyzed directly via a number of diverse methodologies to examine target and pathway status. When a good correlation exists between the tumor cell lines and the endogenous tumors from which they are derived, these lines can be used in vitro to facilitate target validation, via RNAi and/or therapeutic response. In this manner, these lines can accelerate the target validation process by prioritizing which targets are pursued in the more cumbersome and labor-intensive efforts in vivo. PD, pharmacodynamic; IHC, immunohistochemistry; LCM, laser capture microscopy.

View larger version (65K): [in this window] [in a new window]   Fig. 2. Viral-mediated tumorigenesis and target validation. Adenoviruses have been successfully used to infect tissues of interest and deliver recombinases (e.g., Cre) to activate and/or inactivate LoxP-regulated alleles that mediate tumorigenesis. To support target validation efforts, the resulting tumor-bearing mice can subsequently be infected with lentiviruses expressing various shRNAs directed against targets of interest as shown on the left; however, efficient downstream PD and efficacy analyses will be hindered by mosaic shRNA delivery and subsequent expression throughout the tumor(s). One possible means to address this issue is through the development of novel viral vectors designed to coexpress the activating recombinase(s) and an inducible shRNA(s) (right). This would require the use of integrating viruses (e.g., lentivirus) such that the initial infected cell(s) would be "flagged" and the resulting tumor cell population would, in theory, all carry the same inducible shRNA events. This, in turn, would result in an increased likelihood of homogeneous shRNA expression throughout the tumor, thereby facilitating downstream validation efforts. End, endogenous; Adeno, adenovirus; Lenti, lentivirus; Ind, inducible.

Although the predictive power and usefulness of GEMMs for oncology has become evident in the last decade, integrating these models into the drug discovery and development process remains a challenge faced by the translational research community. A schematic for this process is outlined in Fig. 3 , with GEMMs being used to facilitate lead validation and mechanism of action studies. The throughput offered by xenograft and orthotopic models serves a valuable role in funneling the selection between various candidate drugs in the lead-optimization process before putting them through the higher bar of an endogenous microenvironment. A limitation of this systematic screening approach, however, is the possibility of missing candidates that would only be discovered by screening through a GEMM. Short-term pharmacodynamic assays in GEMMs can provide key insights into the specificity and mechanism of action of candidate molecules in the appropriate tumor milieu by identifying and distinguishing between various targeted cell populations, while simultaneously delineating tumor stage-specific effects of a particular therapeutic regimen (74). For example, experiments with small-molecule kinase inhibitors in the RIP1-Tag2 model have identified the contributions of at least two different cell types to the antiangiogenic effects of these agents (75).²

View larger version (47K): [in this window] [in a new window]   Fig. 3. Proposed roles for GEMMs in supporting the drug development process. The flow chart depicts the establishment of GEMMs carrying the mutation(s) identified in the human cancer they are designed to emulate and their application thereof. Following their generation and validation, these models can be used to further validate cancer targets/pathways as well as identify new targets. They ultimately provide a more solid foundation for aiding the downstream preclinical assessment of later-stage drugs (e.g., development candidates, DC) and could prove invaluable in defining both target and drug mechanism of action (MOA). Should they prove to be better prognostic indicators of clinical success than currently accepted modes of testing (e.g., xenografts), these models have the potential to significantly aid and inform the clinical process and ultimately alter current drug discovery paradigms used in the pursuit of novel therapeutics and appropriate drug combinations.

GEMMs can vastly facilitate the discovery of tumor biomarkers that will serve as prognostic indicators as well as markers to monitor drug pharmacodynamics and efficacy. For example, the K-ras^LSLG12D/+ model of pancreatic cancer has been used to identify potential biomarkers of oncogene activation using a mass spectrometry–based serum proteomics approach (65). An alternative and equally interesting approach to biomarker identification is multianalyte profile testing, a technology consisting of a high-density immunoassay panel that is applied to serum/plasma followed by multivariate analysis of the profiles (76). Microarray profile data indicating that cathepsins are activated in two different GEMMs, lung adenocarcinomas in K-ras^LSLG12D/+ mice (77) and pancreatic insulinomas in the RIP1-Tag2 model (78), have inspired the use of activated cathepsin probes to optically label tumors that overexpress and activate these enzymes. Such approaches that couple molecular tumor signatures with powerful diagnostic tools can be used to sample tumor heterogeneity in vivo and guide tailored, patient- and tumor-specific therapeutic strategies in the clinic.

Sophisticated imaging modalities are needed to measure tumor growth within internal organs as opposed to traditional caliper measurements used in s.c. xenografts. Recent developments in small-animal imaging modalities have resulted in novel means to detect tumor markers and monitor preclinical trials in progress (79). Bioluminescent and fluorescent reporter mice are currently available for various tissues of interest, allowing the noninvasive imaging of both tumor growth as well as therapeutic response (reviewed in ref. 80). Such reporter mice can potentially provide significant savings in the time and cost of preclinical trials by providing faster readouts and reducing the number of animals needed. The disadvantages of such mice lie in the need to add one more genetic cross to already complex GEMM genotypes as well as the heterogeneity of reporter response and/or activation in different tissue and tumor types (81). The combination of multiple readouts using bioluminescence can increase the content of information gained, particularly in the case of pharmacodynamic reporters such as E2F1 for proliferation in ref. (82). The wider availability of small animal–adapted instruments for various imaging tools used within the clinic, such as micro–positron emission tomography, ultrasound (including Doppler ultrasound to monitor blood flow and tumor angiogenesis), magnetic resonance imaging, and in vivo X-ray micro–computed tomography, have great potential to inform the monitoring process in humans (83). Improved software programs are needed, however, for the quantitative analysis of small-animal imaging data in a high-throughput fashion, e.g., algorithms for tumor recognition and tumor burden calculation in X-ray images.

	Challenges Ahead, What Needs to be Done

Top Abstract What Is a Good... Modeling High-Impact Cancers... Using GEMMs to Inform... Challenges Ahead, What Needs... References

 
Xenograft models, the current workhorses of the oncology drug development process, are the most widely used platform for testing the efficacy and mechanism of action of drug candidates in vivo before their examination in humans in clinical trials (other mammals are used to inform dose tolerance and toxicity). These xenograft implants have several limitations as in vivo models of tumor progression, including the lack of an intact immune system, the inability to model premalignant neoplastic stages, and imperfect recapitulation of the interactions between tumor cells and the surrounding stroma (84). Although these models are clearly a step forward from in vitro experiments on cell lines that have been adapted to grow in culture, there remains room for improvement in the usefulness and predictive effect of in vivo models used for preclinical assessment of cancer therapeutics. Although GEMMs have this kind of usefulness and the potential to have significant predictive and economic effect on the process of anticancer drug discovery, these models are not extensively used in preclinical trials and have not gained wide acceptance in industry. Here, we list the barriers to the use of GEMMs in oncology drug development (Table 2 ).

Second, the current generation of GEMMs on mixed and varied genetic strain backgrounds pose significant increases to the timelines associated with backcrossing these lines into a desirable, homogenous, inbred background before being able to apply them in the most meaningful and consistent manner in preclinical trials. Although accelerated backcrossing through speed congenics can help streamline these efforts, multiallele models can be subject to significant delays in application. Importantly, there is the potential for significant risk in changing the tumor phenotype and/or penetrance as lines are backcrossed into a common, inbred background. This lack of consistent strain backgrounds presents marked logistical and economic hurdles to moving a GEMM into the preclinical testing realm. Furthermore, in many cases, differences in barrier status at individual animal facilities, and the need to have mice free from specific pathogens (e.g., Helicobacter spp.), result in additional costs and time for embryo rederivation of GEMM lines. Institutional core facilities are equipped with the means to address these issues by taking on the generation and cryopreservation of single and multiallele embryonic stem cells and/or embryos from GEMMs in commonly used strain backgrounds. The Mouse Models of Human Cancer Consortium is carrying out an admirable job of collating a resource for information on GEMMs as well as providing some strains to the community; we strongly encourage the expansion of these efforts. Although such an enterprise may require specifically allocated funding, the savings in time and effort afforded by such a bank are worth the consideration of the scientific community.

Third, once a model is established as genetically and phenotypically homogenous, it must be thoroughly characterized and validated internally before being applied to preclinical trials. Initial published characterizations of models often lack the association of disease stages with relevant therapeutic windows, i.e., a GEMM usually has to be reexamined with the goal of identifying the appropriate intervals and end point(s) for simulating human clinical trials.

Last, preclinical experiments clearly require large numbers of mice to be readily and consistently available. The need for rapid expansion of mice can be partially addressed by in vitro fertilization, which, in turn, necessitates additional resources and access to the appropriate technologies. Taken together, the major barriers to bringing GEMMs into an industry setting are as follows: (a) a common strain background for GEMMs, (b) the presence of complicating pathogens in various colonies, (c) a lack of model validation with an eye to preclinical trials, and (d) the framework for large-scale production colonies. Addressing these challenges within the scientific community would go a long way toward promoting a more rapid and broader implementation of these models in the drug discovery process.

Within the pharmaceutical world, the infrastructure for conducting large-scale preclinical experiments with GEMMs is still in evolution (85). One hurdle to a wider audience for GEMMs in the industry setting is a dearth of preclinical data using current therapeutic standards. There is a strong need for the validation of these models using conventional cytostatic and cytotoxic drugs, i.e., current standards of care, thus testing whether the responses observed in a given GEMM reflect those observed in humans when undergoing the same treatment(s). The examination of novel drugs, either alone or in relevant combinations, in GEMMs with naïve disease is highly informative for discerning and understanding drug activity. In the clinic, however, new agents are typically first tested as either monotherapies or in combination with the current standards of care against refractory or resistant disease. Thus, for these models to mirror the clinical process, the ideal GEMM would be one that would respond similarly to humans when treated with the current standards of care, and, in certain cases, develop resistant or refractory disease that subsequently enables the testing of appropriate combinations with investigational therapies. Furthermore, minimal data exist as to the metabolism of various experimental agents in the immunocompetent strains used to generate GEMMs. Thorough studies are warranted to assess whether notable differences exist between drug absorption, distribution, metabolism, and excretion, and pharmacokinetic variables in the immunocompromised mice typically used to grow xenografts and test cancer therapeutics versus different genetic strains of immunocompetent GEMMs. The authors strongly encourage the support and expansion of the Mouse Models of Human Cancer Consortium enterprise to include a database of preclinical trials and baseline data with conventional drugs and current standards of care in GEMMs.

An importunate consideration of using the mouse as a model for drug action is whether the target/pathway(s) is conserved at the molecular level. Whereas many small-molecule drugs (e.g., kinase inhibitors) cross-react with the mouse target, biologics present a unique challenge to assessing experimental therapeutics in GEMMs in that antibody specificity often does not cross the species barrier. A classic example is that of bevacizumab (Avastin), an antibody that binds and blocks human vascular endothelial growth factor-A signaling and is one of the most successful molecularly targeted anticancer drugs in recent years. Yet, it has not been possible to study bevacizumab in GEMMs as the drug does not bind mouse vascular endothelial growth factor-A. Cases like this have inspired some industry groups to consider the use of appropriate surrogate antibodies or the creation of humanized mouse knock-ins of the gene of interest. Knock-ins of human orthologues in mouse models raise, however, the specter of additional mouse lines and colonies to manage as well as the possibility that the human protein will not interact with the full spectrum of partners required for activity in the mouse. Ideally, the design of the anticancer drug development process would allow for the early testing and selection for biologics and small molecules that exhibit species cross-reactivity. Altogether, establishing the infrastructure to adequately support and conduct preclinical trials that fully evaluate both drug pharmacology and efficacy in GEMMs is no small feat and is very much a work in progress.

Finally, improved reagents and technological advancements are needed to expedite high-throughput data acquisition and downstream analysis of histopathologic data from preclinical testing in GEMMs. This is the most rate-limiting step once preclinical trials have initiated; the need for reliable diagnostic markers and assays is of course not confined to GEMMs, albeit the models face additional challenges in reagent availability and development, e.g., antibodies to phospho-epitopes that cross-react to mouse proteins. Although some automated microscopy systems and robotics for image acquisition are emerging onto the market, significant improvements are still needed. In addition, methods for the quantitation of histologic data show significant variation in the literature, illustrating a need for consensus standards for the numerical representation of histopathologic assays.

Although the intellectual property rights surrounding GEMMs hinder the application of these models in industry, the patents held by the biotechnology and pharmaceutical corporations limit access to novel antitumor agents for preclinical trials. Such regulations prevent the use of the full gamut of clinical competitors and present marked barriers in the design of meaningful preclinical studies in which therapeutic agents can be compared directly with competing clinical entities. Studies of this nature would have a significant effect upon informing the choices of clinicians and aiding the identification of appropriate patient populations for clinical trials. The recent Merck versus Integra ruling addressing this issue potentially opens the way to diminishing these impediments (86). Interestingly, because the Food and Drug Administration does not mandate preclinical efficacy in GEMMs as part of investigational new drug applications, the pharmaceutical industry does not always see the case for using these models, particularly given the time and cost of therapeutic experiments in these systems. Although some progress in addressing all of these issues has been made, the wider acceptance and application of GEMMs in the cancer drug discovery process requires a fundamental cultural change in the interactions between academia and industry regarding the use and application of GEMMs (87). Such a paradigmatic switch, perhaps facilitated by organizations like the Mouse Models of Human Cancer Consortium, could, in turn, accelerate the translation of valuable research in these models into improved therapies for cancer patients.

	Acknowledgments

 
We thank Ching Ching Leow, Andrew Polson, and Ellen Filvaroff for useful discussions and comments.

	Footnotes

 
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ M. Singh et al., unpublished data.

² M. Singh et al., in preparation.

Received 2/23/06; revised 6/19/06; accepted 6/27/06.

	References

Top Abstract What Is a Good... Modeling High-Impact Cancers... Using GEMMs to Inform... Challenges Ahead, What Needs... References

 

1. Van Dyke T, Jacks T. Cancer modeling in the modern era: progress and challenges. Cell 2002;108:135–44.[CrossRef][Medline]
2. Suggitt M, Bibby MC. 50 years of preclinical anticancer drug screening: empirical to target-driven approaches. Clin Cancer Res 2005;11:971–81.[Abstract/Free Full Text]
3. Vogelstein B, Kinzler KW. Cancer genes and the pathways they control. Nat Med 2004;10:789–99.[CrossRef][Medline]
4. Hanahan D, Weinberg RA. The hallmarks of cancer. Cell 2000;100:57–70.[CrossRef][Medline]
5. Joyce JA. Therapeutic targeting of the tumor microenvironment. Cancer Cell 2005;7:513–20.[CrossRef][Medline]
6. Jonkers J, Berns A. Conditional mouse models of sporadic cancer. Nat Rev Cancer 2002;2:251–65.[CrossRef][Medline]
7. Tuveson DA, Jacks T. Technologically advanced cancer modeling in mice. Curr Opin Genet Dev 2002;12:105–10.[CrossRef][Medline]
8. Olive K, Tuveson D. The use of targeted mouse models for preclinical testing of novel cancer therapeutics. Clin Cancer Res 2006;12: this issue.
9. Jackson EL, Willis N, Mercer K, et al. Analysis of lung tumor initiation and progression using conditional expression of oncogenic K-ras. Genes Dev 2001;15:3243–8.[Abstract/Free Full Text]
10. Meuwissen R, Linn SC, Linnoila RI, Zevenhoven J, Mooi WJ, Berns A. Induction of small cell lung cancer by somatic inactivation of both Trp53 and Rb1 in a conditional mouse model. Cancer Cell 2003;4:181–9.[CrossRef][Medline]
11. Shibata H, Toyama K, Shioya H, et al. Rapid colorectal adenoma formation initiated by conditional targeting of the Apc gene. Science 1997;278:120–3.[Abstract/Free Full Text]
12. Meuwissen R, Linn SC, van der Valk M, Mooi WJ, Berns A. Mouse model for lung tumorigenesis through Cre/lox controlled sporadic activation of the K-Ras oncogene. Oncogene 2001;20:6551–8.[CrossRef][Medline]
13. Orsulic S. An RCAS-TVA-based approach to designer mouse models. Mamm Genome 2002;13:543–7.[CrossRef][Medline]
14. Fomchenko El, Holland EC. CCR focus: mouse models of brain tumors and their applications in preclinical trials. Clin Cancer Res 2006;12: this issue.
15. Hu X, Pandolfi PP, Li Y, Koutcher JA, Rosenblum M, Holland EC. mTOR promotes survival and astrocytic characteristics induced by Pten/AKT signaling in glioblastoma. Neoplasia 2005;7:356–68.[CrossRef][Medline]
16. Sandy P, Ventura A, Jacks T. Mammalian RNAi: a practical guide. Biotechniques 2005;39:215–24.[Medline]
17. Lewin AS, Glazer PM, Milstone LM. Gene therapy for autosomal dominant disorders of keratin. J Investig Dermatol Symp Proc 2005;10:47–61.[CrossRef][Medline]
18. Leow CC, Wang XD, Gao WQ. Novel method of generating prostate-specific Cre-LoxP gene switching via intraductal delivery of adenovirus. Prostate 2005;65:1–9.[CrossRef][Medline]
19. Edwards BK, Brown ML, Wingo PA, et al. Annual report to the nation on the status of cancer, 1975-2002, featuring population-based trends in cancer treatment. J Natl Cancer Inst 2005;97:1407–27.[Abstract/Free Full Text]
20. Atlas of genetics and cytogenetics in hematology and oncology. Available from: http://www.infobiogen.fr/services/chromcancer/index.html.
21. Catalog of somatic mutations in cancer. Available from: http://www.sanger.ac.uk/genetics/CGP/cosmic/.
22. Guerra C, Mijimolle N, Dhawahir A, et al. Tumor induction by an endogenous Kras oncogene is highly dependent on cellular context. Cancer Cell 2003;4:111–20.[CrossRef][Medline]
23. Johnson L, Mercer K, Greenbaum D, et al. Somatic activation of the K-ras oncogene causes early onset lung cancer in mice. Nature 2001;410:1111–6.[CrossRef][Medline]
24. Meuwissen R, Berns A. Mouse models for human lung cancer. Genes Dev 2005;19:643–64.[Abstract/Free Full Text]
25. Sweet-Cordero A, Mukherjee S, Subramanian A, et al. An oncogenic KRAS2 expression signature identified by cross-species gene-expression analysis. Nat Genet 2005;37:48–55.[Medline]
26. Jackson EL, Olive KP, Tuveson DA, et al. The differential effects of mutant p53 alleles on advanced murine lung cancer. Cancer Res 2005;65:10280–8.[Abstract/Free Full Text]
27. Kim CF, Jackson EL, Woolfenden AE, et al. Identification of bronchioalveolar stem cells in normal lung and lung cancer. Cell 2005;121:823–35.[CrossRef][Medline]
28. The Mouse Models of Human Cancers Consortium (http://emice.nci.nih.gov/mouse_models/).
29. Brenton JD, Carey LA, Ahmed AA, Caldas C. Molecular classification and molecular forecasting of breast cancer: ready for clinical application? J Clin Oncol 2005;23:7350–60.[Abstract/Free Full Text]
30. Shen Q, Brown PH. Transgenic mouse models for the prevention of breast cancer. Mutat Res 2005;576:93–110.[Medline]
31. Li Y, Hively WP, Varmus HE. Use of MMTV-Wnt-1 transgenic mice for studying the genetic basis of breast cancer. Oncogene 2000;19:1002–9.[CrossRef][Medline]
32. Donehower LA, Godley LA, Aldaz CM, et al. Deficiency of p53 accelerates mammary tumorigenesis in Wnt-1 transgenic mice and promotes chromosomal instability. Genes Dev 1995;9:882–95.[Abstract/Free Full Text]
33. Zhang X, Podsypanina K, Huang S, et al. Estrogen receptor positivity in mammary tumors of Wnt-1 transgenic mice is influenced by collaborating oncogenic mutations. Oncogene 2005;24:4220–31.[CrossRef][Medline]
34. Wijnhoven SW, Zwart E, Speksnijder EN, et al. Mice expressing a mammary gland-specific R270H mutation in the p53 tumor suppressor gene mimic human breast cancer development. Cancer Res 2005;65:8166–73.[Abstract/Free Full Text]
35. Hu Y, Sun H, Drake J, et al. From mice to humans: identification of commonly deregulated genes in mammary cancer via comparative SAGE studies. Cancer Res 2004;64:7748–55.[Abstract/Free Full Text]
36. Welm AL, Kim S, Welm BE, Bishop JM. MET and MYC cooperate in mammary tumorigenesis. Proc Natl Acad Sci U S A 2005;102:4324–9.[Abstract/Free Full Text]
37. Li Y, Welm B, Podsypanina K, et al. Evidence that transgenes encoding components of the Wnt signaling pathway preferentially induce mammary cancers from progenitor cells. Proc Natl Acad Sci U S A 2003;100:15853–8.[Abstract/Free Full Text]
38. Green JE, Desai K, Ye Y, Kavanaugh C, Calvo A, Huh JI. Genomic approaches to understanding mammary tumor progression in transgenic mice and responses to therapy. Clin Cancer Res 2004;10:385–90S.
39. Chen Z, Trotman LC, Shaffer D, et al. Crucial role of p53-dependent cellular senescence in suppression of Pten-deficient tumorigenesis. Nature 2005;436:725–30.[CrossRef][Medline]
40. Asatiani E, Huang WX, Wang A, et al. Deletion, methylation, and expression of the NKX3.1 suppressor gene in primary human prostate cancer. Cancer Res 2005;65:1164–73.[Abstract/Free Full Text]
41. Kim MJ, Bhatia-Gaur R, Banach-Petrosky WA, et al. Nkx3.1 mutant mice recapitulate early stages of prostate carcinogenesis. Cancer Res 2002;62:2999–3004.[Abstract/Free Full Text]
42. Gao H, Ouyang X, Banach-Petrosky W, et al. A critical role for p27kip1 gene dosage in a mouse model of prostate carcinogenesis. Proc Natl Acad Sci U S A 2004;101:17204–9.[Abstract/Free Full Text]
43. Wang S, Gao J, Lei Q, et al. Prostate-specific deletion of the murine Pten tumor suppressor gene leads to metastatic prostate cancer. Cancer Cell 2003;4:209–21.[CrossRef][Medline]
44. Olumi AF, Grossfeld GD, Hayward SW, Carroll PR, Tlsty TD, Cunha GR. Carcinoma-associated fibroblasts direct tumor progression of initiated human prostatic epithelium. Cancer Res 1999;59:5002–11.[Abstract/Free Full Text]
45. Kinzler KW, Vogelstein B. Lessons from hereditary colorectal cancer. Cell 1996;87:159–70.[CrossRef][Medline]
46. Salovaara R, Roth S, Loukola A, et al. Frequent loss of SMAD4/DPC4 protein in colorectal cancers. Gut 2002;51:56–9.[Abstract/Free Full Text]
47. de la Chapelle A, Peltomaki P. The genetics of hereditary common cancers. Curr Opin Genet Dev 1998;8:298–303.[CrossRef][Medline]
48. Lu SL, Kawabata M, Imamura T, et al. HNPCC associated with germline mutation in the TGF-ß type II receptor gene. Nat Genet 1998;19:17–8.[Medline]
49. Bruce WR. Counterpoint: From animal models to prevention of colon cancer. Criteria for proceeding from preclinical studies and choice of models for prevention studies. Cancer Epidemiol Biomarkers Prev 2003;12:401–4.[Abstract/Free Full Text]
50. Martinez ME. Primary prevention of colorectal cancer: lifestyle, nutrition, exercise. Recent Results Cancer Res 2005;166:177–211.[Medline]
51. Green JE, Hudson T. The promise of genetically engineered mice for cancer prevention studies. Nat Rev Cancer 2005;5:184–98.[CrossRef][Medline]
52. Hursting SD, Nunez NP, Patel AC, Perkins SN, Lubet RA, Barrett JC. The utility of genetically altered mouse models for nutrition and cancer chemoprevention research. Mutat Res 2005;576:80–92.[Medline]
53. Fodde R, Smits R. Disease model: familial adenomatous polyposis. Trends Mol Med 2001;7:369–73.[CrossRef][Medline]
54. Haigis KM, Hoff PD, White A, Shoemaker AR, Halberg RB, Dove WF. Tumor regionality in the mouse intestine reflects the mechanism of loss of Apc function. Proc Natl Acad Sci U S A 2004;101:9769–73.[Abstract/Free Full Text]
55. Yang K, Edelmann W, Fan K, et al. A mouse model of human familial adenomatous polyposis. J Exp Zool 1997;277:245–54.[CrossRef][Medline]
56. Zhu Y, Richardson JA, Parada LF, Graff JM. Smad3 mutant mice develop metastatic colorectal cancer. Cell 1998;94:703–14.[CrossRef][Medline]
57. Takaku K, Oshima M, Miyoshi H, Matsui M, Seldin MF, Taketo MM. Intestinal tumorigenesis in compound mutant mice of both Dpc4 (Smad4) and Apc genes. Cell 1998;92:645–56.[CrossRef][Medline]
58. Orsulic S, Li Y, Soslow RA, Vitale-Cross LA, Gutkind JS, Varmus HE. Induction of ovarian cancer by defined multiple genetic changes in a mouse model system. Cancer Cell 2002;1:53–62.[CrossRef][Medline]
59. Connolly DC, Bao R, Nikitin AY, et al. Female mice chimeric for expression of the simian virus 40 TAg under control of the MISIIR promoter develop epithelial ovarian cancer. Cancer Res 2003;63:1389–97.[Abstract/Free Full Text]
60. Flesken-Nikitin A, Choi KC, Eng JP, Shmidt EN, Nikitin AY. Induction of carcinogenesis by concurrent inactivation of p53 and Rb1 in the mouse ovarian surface epithelium. Cancer Res 2003;63:3459–63.[Abstract/Free Full Text]
61. Dinulescu DM, Ince TA, Quade BJ, Shafer SA, Crowley D, Jacks T. Role of Kras and Pten in the development of mouse models of endometriosis and endometrioid ovarian cancer. Nat Med 2005;11:63–70.[CrossRef][Medline]
62. Obata K, Morland SJ, Watson RH, et al. Frequent PTEN/MMAC mutations in endometrioid but not serous or mucinous epithelial ovarian tumors. Cancer Res 1998;58:2095–7.[Abstract/Free Full Text]
63. Bardeesy N, Sharpless NE, DePinho RA, Merlino G. The genetics of pancreatic adenocarcinoma: a roadmap for a mouse model. Semin Cancer Biol 2001;11:201–18.[CrossRef][Medline]
64. Aguirre AJ, Bardeesy N, Sinha M, et al. Activated Kras and Ink4a/Arf deficiency cooperate to produce metastatic pancreatic ductal adenocarcinoma. Genes Dev 2003;17:3112–26.[Abstract/Free Full Text]
65. Hingorani SR, Petricoin EF, Maitra A, et al. Preinvasive and invasive ductal pancreatic cancer and its early detection in the mouse. Cancer Cell 2003;4:437–50.[CrossRef][Medline]
66. Hingorani SR, Wang L, Multani AS, et al. Trp53R172H and KrasG12D cooperate to promote chromosomal instability and widely metastatic pancreatic ductal adenocarcinoma in mice. Cancer Cell 2005;7:469–83.[CrossRef][Medline]
67. Neri D, Bicknell R. Tumour vascular targeting. Nat Rev Cancer 2005;5:436–46.[CrossRef][Medline]
68. Hanahan D. Heritable formation of pancreatic ß-cell tumours in transgenic mice expressing recombinant insulin/simian virus 40 oncogenes. Nature 1985;315:115–22.[CrossRef][Medline]
69. Bergers G, Javaherian K, Lo KM, Folkman J, Hanahan D. Effects of angiogenesis inhibitors on multistage carcinogenesis in mice. Science 1999;284:808–12.[Abstract/Free Full Text]
70. Willingham AT, Deveraux QL, Hampton GM, Aza-Blanc P. RNAi and HTS: exploring cancer by systematic loss-of-function. Oncogene 2004;23:8392–400.[CrossRef][Medline]
71. Al-Hajj M, Becker MW, Wicha M, Weissman I, Clarke MF. Therapeutic implications of cancer stem cells. Curr Opin Genet Dev 2004;14:43–7.[CrossRef][Medline]
72. Hemann MT, Fridman JS, Zilfou JT, et al. An epi-allelic series of p53 hypomorphs created by stable RNAi produces distinct tumor phenotypes in vivo. Nat Genet 2003;33:396–400.[CrossRef][Medline]
73. Roberts RB, Arteaga CL, Threadgill DW. Modeling the cancer patient with genetically engineered mice: prediction of toxicity from molecule-targeted therapies. Cancer Cell 2004;5:115–20.[CrossRef][Medline]
74. Hanke JH, Webster KR, Ronco LV. Protein biomarkers and drug design for cancer treatments. Eur J Cancer Prev 2004;13:297–305.[CrossRef][Medline]
75. Bergers G, Song S, Meyer-Morse N, Bergsland E, Hanahan D. Benefits of targeting both pericytes and endothelial cells in the tumor vasculature with kinase inhibitors. J Clin Invest 2003;111:1287–95.[CrossRef][Medline]
76. Anderson NL, Anderson NG. The human plasma proteome: history, character, and diagnostic prospects. Mol Cell Proteomics 2002;1:845–67.[Abstract/Free Full Text]
77. Grimm J, Kirsch DG, Windsor SD, et al. Use of gene expression profiling to direct in vivo molecular imaging of lung cancer. Proc Natl Acad Sci U S A 2005;102:14404–9.[Abstract/Free Full Text]
78. Joyce JA, Baruch A, Chehade K, et al. Cathepsin cysteine proteases are effectors of invasive growth and angiogenesis during multistage tumorigenesis. Cancer Cell 2004;5:443–53.[CrossRef][Medline]
79. Contag PR. Whole-animal cellular and molecular imaging to accelerate drug development. Drug Discov Today 2002;7:555–62.[CrossRef][Medline]
80. McCaffrey A, Kay MA, Contag CH. Advancing molecular therapies through in vivo bioluminescent imaging. Mol Imaging 2003;2:75–86.[CrossRef][Medline]
81. Lyons SK, Meuwissen R, Krimpenfort P, Berns A. The generation of a conditional reporter that enables bioluminescence imaging of Cre/loxP-dependent tumorigenesis in mice. Cancer Res 2003;63:7042–6.[Abstract/Free Full Text]
82. Momota H, Holland EC. Bioluminescence technology for imaging cell proliferation. Curr Opin Biotechnol 2005;16:681–6.[CrossRef][Medline]
83. Pomper MG, Lee JS. Small animal imaging in drug development. Curr Pharm Des 2005;11:3247–72.[CrossRef][Medline]
84. Becher OJ, Holland EC. Genetically engineered models have advantages over xenografts for preclinical studies. Cancer Res 2006;66:3355–8; discussion 8–9.[Abstract/Free Full Text]
85. Weiss B, Shannon K. Mouse cancer models as a platform for performing preclinical therapeutic trials. Curr Opin Genet Dev 2003;13:84–9.[CrossRef][Medline]
86. Raubicheck C, White BS, Kowalski TJ, Brown DG, Leahy A, Fekete P. Integra v. Merck: a mixed bag for research tool patents. Nat Biotechnol 2003;21:1099–101.[CrossRef][Medline]
87. Olds JL. Intellectual property conundrum for the biological sciences. Anat Rec B New Anat 2004;277:5–9.[CrossRef][Medline]