Patient-derived xenografts effectively capture responses to oncology therapy in a heterogeneous cohort of patients with solid tumors.

BACKGROUND: While patient-derived xenografts (PDXs) offer a powerful modality for translational cancer research, a precise evaluation of how accurately patient responses correlate with matching PDXs in a large, heterogeneous population is needed for assessing the utility of this platform for preclinical drug-testing and personalized patient cancer treatment. PATIENTS AND METHODS: Tumors obtained from surgical or biopsy procedures from 237 cancer patients with a variety of solid tumors were implanted into immunodeficient mice and whole-exome sequencing was carried out. For 92 patients, responses to anticancer therapies were compared with that of their corresponding PDX models. RESULTS: We compared whole-exome sequencing of 237 PDX models with equivalent information in The Cancer Genome Atlas database, demonstrating that tumorgrafts faithfully conserve genetic patterns of the primary tumors. We next screened PDXs established for 92 patients with various solid cancers against the same 129 treatments that were administered clinically and correlated patient outcomes with the responses in corresponding models. Our analysis demonstrates that PDXs accurately replicate patients' clinical outcomes, even as patients undergo several additional cycles of therapy over time, indicating the capacity of these models to correctly guide an oncologist to treatments that are most likely to be of clinical benefit. CONCLUSIONS: Integration of PDX models as a preclinical platform for assessment of drug efficacy may allow a higher success-rate in critical end points of clinical benefit.

TRIM3, a tumor suppressor linked to regulation of p21(Waf1/Cip1.).

The TRIM family of genes is largely studied because of their roles in development, differentiation and host cell antiviral defenses; however, roles in cancer biology are emerging. Loss of heterozygosity of the TRIM3 locus in ∼20% of human glioblastomas raised the possibility that this NHL-domain containing member of the TRIM gene family might be a mammalian tumor suppressor. Consistent with this, reducing TRIM3 expression increased the incidence of and accelerated the development of platelet-derived growth factor -induced glioma in mice. Furthermore, TRIM3 can bind to the cdk inhibitor p21(WAF1/CIP1). Thus, we conclude that TRIM3 is a tumor suppressor mapping to chromosome 11p15.5 and that it might block tumor growth by sequestering p21 and preventing it from facilitating the accumulation of cyclin D1-cdk4.

Intestinal adenoma formation and MYC activation are regulated by cooperation between MYB and Wnt signaling.

Aberrant Wnt signaling mediated by mutations affecting APC (adenomatous polyposis coli) or beta-catenin initiates the majority of human colorectal cancers (CRC) and drives tumorigenesis through the activation of specific genes such as MYC. We report here a novel association whereby another oncogenic transcription factor, MYB/c-Myb, is necessary for intestinal adenoma development directed by activated Wnt signaling. APC(Min/+) mice in which c-myb is haploinsufficient survive longer than wild-type APC(Min/+) animals due to a delay in adenoma formation. Intestinal adenomas from APC(Min/+) mice were assessed and found to have high levels of c-myc gene expression. We explored the relationship between activated Wnt signaling and MYB in regulating MYC and found activated beta-catenin in combination with MYB induces robust upregulation of MYC promoter activity, as well as endogenous MYC mRNA and protein expression, in human cells. This cooperation occurred through independent binding of MYB and beta-catenin to the MYC promoter. These data highlight a cooperative function for MYB in the context of activated Wnt signaling and provide a molecular basis for the expression of MYC in CRC.

Transcriptional regulation of cyclo-oxygenase expression: three pillars of control.

Blocking cyclo-oxygenase (COX) isoform activities with non-steroidal anti-inflammatory drugs (NSAIDS) is widely employed in the treatment of arthritis. These agents also hold great promise in the context of pre and post-neoplastic diseases such as colorectal cancer (CRC). Nevertheless, issues of isoform specificity and delivery necessitate the exploration of other strategies to specifically block expression of the COX genes. Approaches that target gene transcription may complement enzyme inhibition. Thus, understanding the regulation of COX isoform transcription may improve the specific inhibition of expression. Three tiers of transcriptional regulation are evident: initiation, alternative splicing and messenger RNA stability. Transcription factors that activate COX-2 expression are elevated in certain disease states and emergency responses such as infection and are therefore potential targets. These factors include C/EBP-beta, phospho- CREB, NF-IL6, AP1, NFkB, and TCF-4/LEF-1. In this review we highlight another factor, c-MYB as a key COX-2 regulator in CRC. Alternative exon usage is another tier of regulation that has not received much attention. For instance, COX-1 splice variants (also known as COX-3 and PCOX-1a) may broaden the spectrum of COX activities in disease. Similarly, whilst mRNA stability is clearly modulated by steroids in the case of COX-2, the wider implications of targeting mRNA stability have not been afforded the same attention. Finally, it seems that some NSAIDS exert part of their action directly on COX-2 transcriptional regulation explaining why such agents display greater effects on this isoform than enzyme inhibition data would suggest.