Evaluating the sensitivity of newborn rats and newborn hamsters to oncogenic DNA.

To evaluate the risk of residual cellular DNA in vaccines manufactured in tumorigenic cell lines, we have been establishing in vivo assays to quantify the oncogenic activity of DNA. We had generated three oncogene-expression plasmids: pMSV-T24-H-ras, which expresses activated H-ras; pMSV-c-myc, which expresses c-myc; and pMSV-T24-H-ras/MSV-c-myc, which expresses both oncogenes. Tumors were induced in mice by pMSV-T24-H-ras plus pMSV-c-myc or by pMSV-T24-H-ras/MSV-c-myc. Because newborn hamsters and newborn rats have been recommended for oncogenicity testing of the DNA from tumorigenic mammalian cell-substrates used for vaccine production, we evaluated their sensitivity. Newborn hamsters and rats were inoculated with different doses of pMSV-T24-H-ras/MSV-c-myc to determine their sensitivity to tumor induction and with the single-oncogene-expression plasmids to determine whether single oncogenes could induce tumors. Newborn rats were more sensitive than newborn hamsters, and activated H-ras but not c-myc induced tumors in newborns of both rodent species. DNA from four cell lines established from tumors induced by pMSV-T24-H-ras/MSV-c-myc was inoculated into newborn rats. Because no tumors were induced by this cellular DNA, which should be optimal as it contains both oncogenes linked and present in several copies, we conclude that available in vivo models are not sensitive enough to detect the oncogenicity of cellular DNA.

A selective inhibitor of the UFM1-activating enzyme, UBA5.

Protein conjugation with ubiquitin and ubiquitin-like small molecules, such as UFM1, is important for promoting cancer cell survival and proliferation. Herein, the development of the first selective micromolar inhibitor of the UBA5 E1 enzyme that initiates UFM1 protein conjugation is described. This organometallic inhibitor incorporates adenosine and zinc(II)cyclen within its core scaffold and inhibits UBA5 noncompetitively and selectively over other E1 enzymes and a panel of human kinases. Furthermore, this compound selectively impedes the cellular proliferation (above 50µM) of cancer cells containing higher levels of UBA5. This inhibitor may be used to further probe the intracellular role of the UFM1 pathway in disease progression.

GLI1+ perivascular, renal, progenitor cells: The likely source of spontaneous neoplasia that created the AGMK1-9T7 cell line.

The AGMK1-9T7 cell line has been used to study neoplasia in tissue culture. By passage in cell culture, these cells evolved to become tumorigenic and metastatic in immunodeficient mice at passage 40. Of the 20 x 106 kidney cells originally plated, less than 2% formed the colonies that evolved to create this cell line. These cells could be the progeny of some type of kidney progenitor cells. To characterize these cells, we documented their renal lineage by their expression of PAX-2 and MIOX, detected by indirect immunofluorescence. These cells assessed by flow-cytometry expressed high levels of CD44, CD73, CD105, Sca-1, and GLI1 across all passages tested; these markers have been reported to be expressed by renal progenitor cells. The expression of GLI1 was confirmed by immunofluorescence and western blot analysis. Cells from passages 13 to 23 possessed the ability to differentiate into adipocytes, osteoblasts, and chondrocytes; after passage 23, their ability to form these cell types was lost. These data indicate that the cells that formed the AGMK1-9T7 cell line were GLI1+ perivascular, kidney, progenitor cells.

The AGMK1-9T7 cell model of neoplasia: Evolution of DNA copy-number aberrations and miRNA expression during transition from normal to metastatic cancer cells.

To study neoplasia in tissue culture, cell lines representing the evolution of normal cells to tumor cells are needed. To produce such cells, we developed the AGMK1-9T7 cell line, established cell banks at 10-passage intervals, and characterized their biological properties. Here we examine the evolution of chromosomal DNA copy-number aberrations and miRNA expression in this cell line from passage 1 to the acquisition of a tumorigenic phenotype at passage 40. We demonstrated the use of a human microarray platform for DNA copy-number profiling of AGMK1-9T7 cells using knowledge of synteny to 'recode' data from human chromosome coordinates to those of the African green monkey. This approach revealed the accumulation of DNA copy-number gains and losses in AGMK1-9T7 cells from passage 3 to passage 40, which spans the period in which neoplastic transformation occurred. These alterations occurred in the sequences of genes regulating DNA copy-number imbalance of several genes that regulate endothelial cell angiogenesis, survival, migration, and proliferation. Regarding miRNA expression, 195 miRNAs were up- or down-regulated at passage 1 at levels that appear to be biologically relevant (i.e., log2 fold change >2.0 (q<0.05)). At passage 10, the number of up/down-regulated miRNAs fell to 63; this number increased to 93 at passage 40. Principal-component analysis grouped these miRNAs into 3 clusters; miRNAs in sub-clusters of these groups could be correlated with initiation, promotion, and progression, stages that have been described for neoplastic development. Thirty-four of the AGMK1-9T7 miRNAs have been associated with these stages in human cancer. Based on these data, we propose that the evolution of AGMK1-9T7 cells represents a detailed model of neoplasia in vitro.

Issues associated with residual cell-substrate DNA in viral vaccines.

The presence of some residual cellular DNA derived from the production-cell substrate in viral vaccines is inevitable. Whether this DNA represents a safety concern, particularly if the cell substrate is derived from a tumor or is tumorigenic, is unknown. DNA has two biological activities that need to be considered. First, DNA can be oncogenic; second, DNA can be infectious. As part of our studies to assess the risk of residual cell-substrate DNA in viral vaccines, we have established assays that can quantify the biological activities of DNA. From data obtained using these assays, we have estimated the risk of an oncogenic or an infectious event from DNA. Because these estimates were derived from the most sensitive assays identified so far, they likely represent worst-case estimates. In addition, methods that inactivate the biological activities of DNA can be assessed and estimations of risk reduction by these treatments can be made. In this paper, we discuss our approaches to address potential safety issues associated with residual cellular DNA from neoplastic cell substrates in viral vaccines, summarize the development of assays to quantify the oncogenic and infectivity activities of DNA, and discuss methods to reduce the biological activities of DNA.

Quantitative determination of the infectivity of the proviral DNA of a retrovirus in vitro: Evaluation of methods for DNA inactivation.

All viral vaccines contain contaminating residual DNA derived from the production cell substrate. The potential risk of this DNA, particularly when derived from tumorigenic cells, has been debated for over 40 years. While the major risk has been considered to be the oncogenicity of the DNA, another potential risk is that a genome of an infectious virus is present in this DNA. Such a genome might generate an infectious agent that could establish an infection in vaccine recipients. To determine the quantity of a retroviral provirus in cellular DNA that can establish a productive infection in vitro, we developed a transfection/co-culture system capable of recovering infectious virus from 1 pg of cloned HIV DNA and from 2 microg of cellular DNA from HIV-infected cells. We demonstrate that infectivity can be reduced to below detectable levels either by lowering the median size of the DNA to 350 base pairs or by treatment with beta-propiolactone. From the amount of reduction of infectivity, we calculate that clearance values in excess of 10(7) are attainable with respect to the infectivity associated with residual cell-substrate DNA. Thus, the potential risk associated with DNA can be substantially reduced by degradation or by chemical inactivation.

Responsiveness to basement membrane extract as a possible trait for tumorigenicity characterization.

Immortalized cell lines used to produce vaccines are expected to be described in terms of their tumorigenicity. However, current in vivo tumorigenicity assays can be time-consuming and results can be equivocal, especially for weakly tumorigenic cells. Basement membrane extract (BME) derived from the Engelbreth-Holm-Swarm mouse tumor, such as Matrigel and Cultrex, consists of laminin, collagen IV, entactin, heparan sulfate, and proteoglycans, as well as biologically active peptides and growth factors. For nearly three decades, BME has been used in cancer research to enhance tumorigenicity assays (both tumor "take" as well as tumor growth are substantially improved). We assessed the feasibility of using BME to facilitate the evaluation of vaccine cell substrate tumorigenicity. Vero cells (WHO 10-87) were serially passaged and banked at every ten passages beginning with p140; for the present study, low-passage Vero cells (Vero LP, originating from cells banked at p140) and high-passage Vero cells (Vero HP, originating from cells banked at p250) were used. In addition, Vero TPX2 and Vero NM1, cell lines established from tumors formed in nude mice by Vero HP cells, as well as other cell lines relevant to vaccine production (HeLa, MDCK, 293, and ARPE-19), were assessed. Female adult athymic nude mice were injected subcutaneously with cells in the absence or presence of BME. We observed that the tumorigenicity of ARPE-19 cells as well as Vero cells below passage 258 (Vero LP and Vero HP; previously characterized as non-tumorigenic or weakly tumorigenic, respectively) was not enhanced by BME. In contrast, BME shortened the latency and decreased the tumor-producing cell dose of HeLa, 293, and MDCK cells as well as the tumorigenic Vero derivatives TPX2 and NM1. Thus, responsiveness to BME may reflect the status of the neoplastic process and possibly serve as a useful trait for better defining the tumorigenic phenotype of cells.

A Chemical Probe for Tudor Domain Protein Spindlin1 to Investigate Chromatin Function.

Modifications of histone tails, including lysine/arginine methylation, provide the basis of a "chromatin or histone code". Proteins that contain "reader" domains can bind to these modifications and form specific effector complexes, which ultimately mediate chromatin function. The spindlin1 (SPIN1) protein contains three Tudor methyllysine/arginine reader domains and was identified as a putative oncogene and transcriptional coactivator. Here we report a SPIN1 chemical probe inhibitor with low nanomolar in vitro activity, exquisite selectivity on a panel of methyl reader and writer proteins, and with submicromolar cellular activity. X-ray crystallography showed that this Tudor domain chemical probe simultaneously engages Tudor domains 1 and 2 via a bidentate binding mode. Small molecule inhibition and siRNA knockdown of SPIN1, as well as chemoproteomic studies, identified genes which are transcriptionally regulated by SPIN1 in squamous cell carcinoma and suggest that SPIN1 may have a role in cancer related inflammation and/or cancer metastasis.

A chemical biology toolbox to study protein methyltransferases and epigenetic signaling.

Protein methyltransferases (PMTs) comprise a major class of epigenetic regulatory enzymes with therapeutic relevance. Here we present a collection of chemical probes and associated reagents and data to elucidate the function of human and murine PMTs in cellular studies. Our collection provides inhibitors and antagonists that together modulate most of the key regulatory methylation marks on histones H3 and H4, providing an important resource for modulating cellular epigenomes. We describe a comprehensive and comparative characterization of the probe collection with respect to their potency, selectivity, and mode of inhibition. We demonstrate the utility of this collection in CD4+ T cell differentiation assays revealing the potential of individual probes to alter multiple T cell subpopulations which may have implications for T cell-mediated processes such as inflammation and immuno-oncology. In particular, we demonstrate a role for DOT1L in limiting Th1 cell differentiation and maintaining lineage integrity. This chemical probe collection and associated data form a resource for the study of methylation-mediated signaling in epigenetics, inflammation and beyond.

Chemical Instability and Promiscuity of Arylmethylidenepyrazolinone-Based MDMX Inhibitors.

Targeting the protein-protein interaction between p53 and MDM2/MDMX (MDM4) represents an attractive anticancer strategy for the treatment of p53-competent tumors. Several selective and potent MDM2 inhibitors have been developed and entered the clinic; however, the repertoire of MDMX antagonists is still limited. The arylmethylidenepyrazolinone SJ-172550 has been reported as a selective MDMX antagonist; yet, uncertainties about its mechanism of action have raised doubts about its use as a chemical probe. Here, we show that, in addition to its unclear mode of action, SJ-172550 is unstable in aqueous buffers, giving rise to side products of unknown biological activity. Using an SJ-172550-derived affinity probe, we observed promiscuous binding to cellular proteins whereas cellular thermal shift assays did not reveal a stabilizing effect on MDMX. Overall, our results raise further questions about the interpretation of data using SJ-172550 and related compounds to investigate cellular phenotypes.

Assessment of potential miRNA biomarkers of VERO-cell tumorigenicity in a new line (AGMK1-9T7) of African green monkey kidney cells.

Patterns of microRNA expression appear to delineate the process of spontaneous neoplastic development-transformation (SPNDT) occurring in the African green monkey kidney (AGMK) VERO cell line (Teferedegne et al., 2010). Analysis of microarray data identified 6 microRNAs whose high-level of expression peaked when the World Health Organization 10-87 VERO cells became tumorigenic at passage (p) 190. Six miRNAs were identified as potential biomarkers for the expression of the VERO-cell tumorigenic phenotype (Teferedegne et al., 2014). However, the question remained whether these miRNA biomarkers are specific for VERO cells or can be generalizable to other cells originating from African green monkey kidneys. To examine miRNA expression patterns in AGMK cells at lower passage levels and to re-examine the identified miRNAs as biomarkers associated with tumorigenic phenotype of VERO cells in another independently-derived line, we established a new line of African green monkey kidney cells (AGMK1-9T7) by serially passaging kidney cells from another AGM. The AGMK1-9T7 cells became tumorigenic in nude mice at p40. Evaluation of miRNA expression at intervals from p1 to p40 revealed similarities between the evolution of miRNA expression during SPNDT in the AGMK1-9T7 cells and the 10-87 VERO cells. Four of the 6 potential biomarker miRNAs (miR-376a, miR-654-3p, miR-543, miR-134) in our earlier reports were detected by microarray in the AGMK1-9T7 cells; RT-qPCR analysis detected all 6 miRNAs. All 6 of these miRNAs have been associated with human tumors. Detection of the same miRNAs associated with the tumorigenic p40 AGMK1-9T7 cells and tumorigenic 10-87 VERO cells confirmed our proposal that these miRNA represent biomarkers for the tumor-forming ability of AGMK/VERO cells. The similarities of expression of miRNAs in different AGMK cell lines that were established 50years apart suggest that the process of SPNDT in these non-human primate cells in tissue culture is based upon similar genetic and epigenetic mechanisms.

Real-time, quantitative PCR assays for the detection of virus-specific DNA in samples with mixed populations of polyomaviruses.

Mixtures of polyomaviruses can be present in the central nervous system, the gastrointestinal tract, the genitourinary tract, blood, and urban sewage. We have developed 12 primer/probe sets (four per virus) for real-time, quantitative PCR assays (TaqMan) that can specifically detect BKV, JCV, and SV40 genomes present in mixtures of these viruses. The specificities of these primer/probe sets were determined by evaluating their level of interaction with the DNA from other polyomaviruses and their ability to estimate the number of copies of homologous viral DNA in blinded samples of defined mixtures of three polyomaviral DNAs. Three early region and three late region primer/probe sets determined, within a two-fold range, the number of copies of their respective DNAs. Four sets of SV40 primer/probes also detected 1.1-2.4 copies of SV40 DNA per COS-1 cell, cells estimated to contain a single copy of SV40 DNA. Three JCV primer/probe sets detected 3.7-4.2 copies per cell of JCV DNA in the JCV-transformed cell line M1-HR, cells estimated to contain between 0.5 and 1 copy of the JCV genome. We suggest that the virus-specific primer/probe sets in this study be considered sufficiently characterized to initiate the quantification of polyomavirus DNA in biological samples.

E1A oncogene-induced sensitization of human tumor cells to innate immune defenses and chemotherapy-induced apoptosis in vitro and in vivo.

Expression of the adenoviral E1A oncogene induces susceptibility of neoplastic cells from different species to both immune-mediated and chemotherapy-induced cell death. These effects of E1A are easily measured in vitro using cytotoxicity assays. However, conventional in vivo assays of tumor development lack similar precision for measurement of oncogene-induced changes in tumor cell traits. E1A expression in p53 mutant human breast carcinoma cells sensitized them in vitro to diverse immunological injuries and apoptosis triggered by chemotherapeutic agents, as predicted from studies of rodent tumor cells. Nude mice, which possess innate cellular immune defenses against E1A-expressing tumor cells, were used in a quantitative tumor induction assay to test the in vivo correlations of E1A-induced immunosensitivity and chemosensitivity of human tumor cells. Two distinct, E1A-induced breast cancer cell traits could be measured in nude mice: (a) increased tumor latency and (b) reduced efficiency of tumor induction. These results were confirmed in studies of E1A-expressing human fibrosarcoma cells. The results demonstrate that E1A-induced conversion of human cells from a cytolytic resistant to a cytolytic susceptible phenotype, as detected in vitro, translates into reduced tumorigenicity of cells confronted with innate immune defenses and exposed to chemotherapeutic agents in nude mice. However, the data also show that E1A expression does not completely eliminate the tumorigenicity of either established human tumor cells or of cells immortalized by E1A. This experimental approach should be useful for studies of the effects of other oncogene-related tumor cell traits on tumorigenicity and could be used for preclinical studies of different treatment strategies for human tumors.

Signal transducer and activator of transcription 3 (STAT3) inhibitor, S3I-201, acts as a potent and non-selective alkylating agent.

The Signal Transducer and Activator of Transcription 3 (STAT3) oncogene is a master regulator of many human cancers, and a well-recognized target for therapeutic intervention. A well known STAT3 inhibitor, S3I-201 (NSC 74859), is hypothesized to block STAT3 function in cancer cells by binding the STAT3 SH2 domain and disrupt STAT3 protein complexation events. In this study, liquid chromatography tandem mass spectrometry analysis revealed that STAT3, in the presence of S3I-201, showed a minimum of five specific sites of modification, cysteine's 108, 259, 367, 542, and 687. Moreover, a prepared fluorescently labeled chemical probe of S3I-201 (DB-6-055) revealed that S3I-201 non-specifically and globally alkylated intracellular proteins at concentrations consistent with S3I-201's reported IC50. These data are consistent with the hypothesis that S3I-201 is a sub-optimal probe for interrogating STAT3-related cell biology.

Identification of Bidentate Salicylic Acid Inhibitors of PTP1B.

PTP1B is a master regulator in the insulin and leptin metabolic pathways. Hyper-activated PTP1B results in insulin resistance and is viewed as a key factor in the onset of type II diabetes and obesity. Moreover, inhibition of PTP1B expression in cancer cells dramatically inhibits cell growth in vitro and in vivo. Herein, we report the computationally guided optimization of a salicylic acid-based PTP1B inhibitor 6, identifying new and more potent bidentate PTP1B inhibitors, such as 20h, which exhibited a > 4-fold improvement in activity. In CHO-IR cells, 20f, 20h, and 20j suppressed PTP1B activity and restored insulin receptor phosphorylation levels. Notably, 20f, which displayed a 5-fold selectivity for PTP1B over the closely related PTPσ protein, showed no inhibition of PTP-LAR, PRL2 A/S, MKPX, or papain. Finally, 20i and 20j displayed nanomolar inhibition of PTPσ, representing interesting lead compounds for further investigation.

MicroRNAs as potential biomarkers for VERO cell tumorigenicity.

MicroRNA expression appears to capture the process of neoplastic development in vitro in the VERO line of African green monkey kidney (AGMK) cells (Teferedegne et al. PLoS One 2010;5(12):e14416). In that study, specific miRNA signatures were correlated with the transition, during serial tissue-culture passage, of low-density passaged 10-87 VERO cells from a non-tumorigenic phenotype at passage (p) 148 to a tumorigenic phenotype at p256. In the present study, six miRNAs (miR-376a, miR-654-3p, miR-543, miR-299-3p, miR-134 and miR-369-3p) were chosen from the identified signature miRNAs for evaluation of their use as potential biomarkers to track the progression of neoplastic development in VERO cells. Cells from the 10-87 VERO cell line at passage levels from p148 to p256 were inoculated into newborn and adult athymic nude mice. No tumors were observed in animals inoculated with cells from p148 to p186. In contrast, tumor incidences of 20% developed only in newborn mice that received 10-87 VERO cells at p194, p234 and p256. By qPCR profiling of the signature miRNAs of 10-87 VERO cells from these cell banks, we identified p194 as the level at which signature miRNAs elevated concurrently with the acquisition of tumorigenic phenotype with similar levels expressed beyond this passage. In wound-healing assays at 10-passage intervals between p150 to p250, the cells displayed a progressive increase in migration from p165 to p186; beginning at p194 and higher passages thereafter, the cells exhibited the highest rates of migration. By qPCR analysis, the same signature miRNAs were overexpressed with concomitant acquisition of the tumorigenic phenotype in another lineage of 10-87 VERO cells passaged independently at high density. Correlation between the passages at which the cells expressed a tumorigenic phenotype and the passages representing peaks in expression levels of signature miRNAs indicates that these miRNAs are potential biomarkers for the expression of the VERO cell tumorigenic phenotype.

A mouse strain defective in both T cells and NK cells has enhanced sensitivity to tumor induction by plasmid DNA expressing both activated H-Ras and c-Myc.

As part of safety studies to evaluate the risk of residual cellular DNA in vaccines manufactured in tumorigenic cells, we have been developing in vivo assays to detect and quantify the oncogenic activity of DNA. We generated a plasmid expressing both an activated human H-ras gene and murine c-myc gene and showed that 1 µg of this plasmid, pMSV-T24-H-ras/MSV-c-myc, was capable of inducing tumors in newborn NIH Swiss mice. However, to be able to detect the oncogenicity of dominant activated oncogenes in cellular DNA, a more sensitive system was needed. In this paper, we demonstrate that the newborn CD3 epsilon transgenic mouse, which is defective in both T-cell and NK-cell functions, can detect the oncogenic activity of 25 ng of the circular form of pMSV-T24-H-ras/MSV-c-myc. When this plasmid was inoculated as linear DNA, amounts of DNA as low as 800 pg were capable of inducing tumors. Animals were found that had multiple tumors, and these tumors were independent and likely clonal. These results demonstrate that the newborn CD3 epsilon mouse is highly sensitive for the detection of oncogenic activity of DNA. To determine whether it can detect the oncogenic activity of cellular DNA derived from four human tumor-cell lines (HeLa, A549, HT-1080, and CEM), DNA (100 µg) was inoculated into newborn CD3 epsilon mice both in the presence of 1 µg of linear pMSV-T24-H-ras/MSV-c-myc as positive control and in its absence. While tumors were induced in 100% of mice with the positive-control plasmid, no tumors were induced in mice receiving any of the tumor DNAs alone. These results demonstrate that detection of oncogenes in cellular DNA derived from four human tumor-derived cell lines in this mouse system was not possible; the results also show the importance of including a positive-control plasmid to detect inhibitory effects of the cellular DNA.

Nanomolar-Potency Small Molecule Inhibitor of STAT5 Protein.

We herein report the design and synthesis of the first nanomolar binding inhibitor of STAT5 protein. Lead compound 13a, possessing a phosphotyrosyl-mimicking salicylic acid group, potently and selectively binds to STAT5 over STAT3, inhibits STAT5-SH2 domain complexation events in vitro, silences activated STAT5 in leukemic cells, as well as STAT5's downstream transcriptional targets, including MYC and MCL1, and, as a result, leads to apoptosis. We believe 13a represents a useful probe for interrogating STAT5 function in cells as well as being a potential candidate for advanced preclinical trials.

Development of a neutralization assay for influenza virus using an endpoint assessment based on quantitative reverse-transcription PCR.

A microneutralization assay using an ELISA-based endpoint assessment (ELISA-MN) is widely used to measure the serological response to influenza virus infection and vaccination. We have developed an alternative microneutralization assay for influenza virus using a quantitative reverse transcription PCR-based endpoint assessment (qPCR-MN) in order to improve upon technical limitations associated with ELISA-MN. For qPCR-MN, infected MDCK-London cells in 96-well cell-culture plates are processed with minimal steps such that resulting samples are amenable to high-throughput analysis by downstream one-step quantitative reverse transcription PCR (qRT-PCR; SYBR Green chemistry with primers targeting a conserved region of the M1 gene of influenza A viruses). The growth curves of three recent vaccine strains demonstrated that the qRT-PCR signal detected at 6 hours post-infection reflected an amplification of at least 100-fold over input. Using ferret antisera, we have established the feasibility of measuring virus neutralization at 6 hours post-infection, a duration likely confined to a single virus-replication cycle. The neutralization titer for qPCR-MN was defined as the highest reciprocal serum dilution necessary to achieve a 90% inhibition of the qRT-PCR signal; this endpoint was found to be in agreement with ELISA-MN using the same critical reagents in each assay. qPCR-MN was robust with respect to assay duration (6 hours vs. 12 hours). In addition, qPCR-MN appeared to be compliant with the Percentage Law (i.e., virus neutralization results appear to be consistent over an input virus dose ranging from 500 to 12,000 TCID(50)). Compared with ELISA-MN, qPCR-MN might have inherent properties conducive to reducing intra- and inter-laboratory variability while affording suitability for automation and high-throughput uses. Finally, our qRT-PCR-based approach may be broadly applicable to the development of neutralization assays for a wide variety of viruses.

Failure-to-thrive syndrome associated with tumor formation by Madin-Darby canine kidney cells in newborn nude mice.

Tumors that formed in newborn nude mice that were inoculated with 10(7) Madin-Darby canine kidney (MDCK) cells were associated with a failure-to-thrive (FTT) syndrome consisting of growth retardation, lethargy, weakness, and dehydration. Scoliosis developed in 41% of affected pups. Pups were symptomatic by week 2; severely affected pups became moribund and required euthanasia within 3 to 4 wk. Mice with FTT were classified into categories of mild, moderate, and severe disease by comparing their weight with that of age-matched normal nude mice. The MDCK-induced tumors were adenocarcinomas that invaded adjacent muscle, connective tissue, and bone; 6 of the 26 pups examined had lung metastases. The induction of FTT did not correlate with cell-line aggressiveness as estimated by histopathology or the efficiency of tumor formation (tumor-forming dose 50% endpoint range = 10(2.8) to 10(7.5)); however, tumor invasion of the paravertebral muscles likely contributed to the scoliosis noted. In contrast to the effect of MDCK cells, tumor formation observed in newborn mice inoculated with highly tumorigenic, human-tumor-derived cell lines was not associated with FTT development. We suggest that tumor formation and FTT are characteristics of these MDCK cell inocula and that FTT represents a new syndrome that may be similar to the cachexia that develops in humans with cancer or other diseases.