Despite metastasis as an important cause of death in colorectal cancer patients, current animal models of this disease are scarcely metastatic. We evaluated whether direct orthotopic cell microinjection, between the mucosa and the muscularis layers of the cecal wall of nude mice, drives tumor foci to the most relevant metastatic sites observed in humans and/or improves its yield as compared with previous methods. We injected eight animals each tested human colorectal cancer cell line (HCT-116, SW-620, and DLD-1), using a especially designed micropipette under binocular guidance, and evaluated the take rate, local growth, pattern and rate of dissemination, and survival time. Take rates were in the 75 to 88% range. Tumors showed varying degrees of mesenteric and retroperitoneal lymphatic foci (57 to 100%), hematogenous dissemination to liver (29 to 67%) and lung (29 to 100%), and peritoneal carcinomatosis (29 to 100%). Tumor staging closely correlated with animal survival. Therefore, the orthotopic cell microinjection procedure induces tumor foci in the most clinically relevant metastatic sites: colon-draining lymphatics, liver, lung, and peritoneum. The replication of the clinical pattern of dissemination makes it a good model for advanced colorectal cancer. Moreover, this procedure also enhances the rates of hematogenous and lymphatic dissemination at relevant sites, as compared with previously described methods that only partially reproduce this pattern. Colorectal cancer cases represents 15% of all cancer types. Its poor prognosis and the consequence of its metastatic spread makes colorectal cancer the second most common cause of cancer death in western countries.1 However, genetically modified mouse models of colorectal cancer are scarcely or not metastatic.2,3 Moreover, more metastatic cancer models, such as surgical orthotopic implantation (SOI), experimental or spontaneous metastasis assays, and orthotopic cell injection also show limitations. Thus, although SOI of human colorectal cancer in nude mice yields liver metastasis, 4,5 it does not generate lung metastasis, nor mesenteric or retroperitoneal lymphatic metastasis, 6 and requires the previous expansion of the tumor in subcutaneous xenografts, [7][8][9] which may alter its growth and dissemination capacities. 10 On the other hand, the experimental metastasis assay or spontaneous metastasis assay, consisting of cell injection into the tail vein or footpad, are less physiological and usually generate tumor foci only at one single site. [11][12][13][14][15][16] Moreover, injection of colorectal cancer cells in the ileocolic vein or in the apical lymphoid follicle 12,17,18 limits metastases to liver and lymphatics, varying widely in their rate.We tested whether direct orthotopic cell microinjection (OCMI), between the mucosa and the muscularis externa
Summary:Iron overload is associated with free radical generation and tissue damage. Our main objective was to ascertain the frequency and severity of iron overload in a group of 59 patients who died after conventional-intensity autologous (n ¼ 24) or allogeneic (n ¼ 35) haematopoietic stem cell transplantation (HSCT). A second objective was to investigate associations between liver-iron concentration and causes of transplant-related mortality. The median age was 41 years (range, 19-66), 41 were males and 18 females. In total, 26 patients had acute leukaemia or MDS, 10 CML, 17 lymphoma, four myeloma and two aplastic anaemia. The median hepatic iron concentration (HIC) was 138 lmol/g dry weight (7.7 mg/g; range 31-631 lmol/g). In total, 4/32 (12%) patients with HIC o150 lmol/g and 10/27 (37%) with hepatic iron X150 lmol/g showed invasive aspergillosis at autopsy (P ¼ 0.035). This was significant in multivariate analysis (RR 9.0; 95% CI 1.6-50.3, P ¼ 0.012). In conclusion, severe iron overload is frequent in patients who die following HSCT and is associated with invasive aspergillosis.
p53 mutations alone or in combination with K-ras mutations are correlated with a worse outcome. However, the routine use of these mutations as prognostic markers in the clinical setting is not recommended.
A series of polymeric biomaterials, including poly(methyl acrylate), chitosan, poly(ethyl acrylate) (PEA), poly(hydroxyethyl acrylate) (PHEA), and a series of random copolymers containing ethyl acrylate, hydroxyethyl acrylate, and methyl acrylate were tested in vitro as culture substrates and compared for their effect on the differentiation of neural stem cells (NSCs) obtained from the subventricular zone of postnatal rats. Immunocytochemical assay for specific markers and scanning electron microscopy techniques were employed to determine the adhesion of the cultured NSCs to the different biomaterials and the respective neuronal differentiation. The functional properties and the membrane excitability of differentiated NSCs were investigated using a patch-clamp. The results show that the substrate's surface chemistry influences cell attachment and neuronal differentiation, probably through its influence on adsorbed laminin, and that copolymers based on PEA and PHEA in a narrow composition window are suitable substrates to promote cell attachment and differentiation of adult NSCs into functional neurons and glia.
Different mutant amino acids in the Ras proteins lead to distinct transforming capacities and different aggressiveness in human tumors. K-Ras Asp12 (K12D) is more prevalent in benign than in malignant human colorectal tumors, whereas K-Ras Val12 (K12V) associates with more advanced and metastatic carcinomas, higher recurrence and decreased survival. Here, we tested, in a nude mouse xenograft model, whether different human K-Ras oncogenes mutated at codon 12 to Val, Asp or Cys would confer NIH3T3 fibroblasts distinct oncogenic phenotypes. We studied tumor histology and growth, apoptotic and mitotic rates, activation of signal transduction pathways downstream of Ras and regulation of the cell cycle and apoptotic proteins in tumors derived from the implanted transformants. We found that the K12V oncogene induces a more aggressive tumorigenic phenotype than the K12D oncogene, whereas K12C does not induce tumors in this model. Thus, K12V mutant tumors proliferate about seven times faster, and have higher cellularity and mitotic rates than the K12D mutant tumors. A molecular analysis of the induced tumors shows that the K12V mutant protein interacts with Raf-1 and transduces signals mainly through the Erk pathway. Unexpectedly, in tumors induced by the K12D oncogene, the K-Ras mutant protein does not interact with Raf-1 nor activates the Erk canonical pathway. Instead, it transduces signals through the PI3K/Akt, JNK, p38 and FAK pathways. Finally, the higher growth rate of the K12V tumors associates with enhanced Rb phosphorylation, and PCNA and cyclin B upregulation, consistent with faster G1/S and G2/M transitions, without alteration of apoptotic regulation.
Celecoxib, a selective cyclooxygenase-2 (COX-2) inhibitor, is effective as chemopreventive against colon cancer and it is the only nonsteoroidal antiinflammatory drug approved by the FDA for adjuvant therapy in patients with familial adenomatous polyposis. It is also being evaluated, within Phase II and III clinical trials, in combination with standard chemotherapy to treat sporadic colorectal cancer. Nevertheless, its antitumor mechanism of action is still not fully understood. In this study, we have evaluated the in vitro growth inhibitory effect of celecoxib in colon carcinoma cells and analyzed its mechanism of action. We report that the deregulation of the focal adhesion assembly protein Crk-associated substrate 130 kDa (p130Cas) by celecoxib plays a relevant role in the cytotoxic effect of this drug. Thus, celecoxib induces the proteolysis of p130Cas and the nuclear translocation of the 31 kDa generated fragment leading to apoptosis. Furthermore, overexpression of wild-type p130Cas reverts, in part, the growth inhibitory effect of celecoxib. In contrast, FAK and AKT do not appear to be involved in this activity. Our data suggest, for the first time, that the antitumor mechanism of action of celecoxib includes the induction of anoikis, an effect that is not related to COX-2 inhibition. Besides providing new insights into the antitumor effect of celecoxib, this novel mechanism of action holds potential relevance in drug development. Indeed, our results open the possibility to develop new celecoxib derivatives that induce anoikis without COX-2 inhibition so as to avoid the cardiovascular toxicity recently described for the COX-2 inhibitors. ' 2005 Wiley-Liss, Inc.
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