Pancreatic ductal adenocarcinoma (PDAC) is an incurable lethal disease whose incidence rate is growing. There is no effective screening for detection of early stage tumors and, in most cases, PDAC is diagnosed at advanced disease stages, when radical pancreatic resection is not possible. The aggressive nature of pancreatic tumor cells lies in the complex genetic mechanisms behind their uncontrolled capability to grow and metastasize, which involve essential adaptive changes in cellular metabolism, signaling, adhesion and immunoediting. In addition, PDAC cells promote a dense functional stroma that facilitates tumor resistance to chemotherapy and radiation. During the last two decades, gemcitabine has been the reference for the systemic treatment of PDAC. However, recently, a regimen combining fluorouracil, irinotecan, oxaliplatin, and leucovorin (FOLFIRINOX) and another combining albumin-bound paclitaxel with gemcitabine have shown clear therapeutic advantage in advanced PDAC, with survival outcomes of 11.3 and 8.5 mo on phase III trials, respectively, over single-agent gemcitabine. With the pending issue of their higher toxicities, these regimens set the reference for ongoing and future clinical studies in advanced PDAC. In addition, the efficacy of oral fluoropyrimidine (S-1) has been well documented in Asiatic PDAC patients. The development of therapeutic approaches other than cytotoxic drugs has proven difficult in the past, with only one drug (erlotinib) approved to date. Besides, a number of agents targeting signaling pathways in tumor or stroma cells are being investigated. Likewise, immunotherapies that target PDAC in various ways are the subject of a number of clinical trials. The search for reliable biomarkers with diagnostic and prognostic value using genomics and mass spectrometry methods may facilitate monitoring and refinement of therapies. This review focuses on current understanding of the pathogenesis of PDAC and the latest developments in the treatment of advanced PDAC.
A characteristic neuropathological feature of Alzheimer's disease is the cerebral deposition of amyloid plaques. These deposits contain beta A4 amyloid peptide, a cleavage product of the transmembrane protein amyloid protein precursor (APP). Despite numerous studies on the processing of the different APP isoforms in non-neuronal cells, little is known about its sorting and transport in neurons of the central nervous system (CNS). To analyze this question we expressed in cultured rat hippocampal neurons the human APP 695, tagged at its N-terminus with the myc epitope, using the Semliki forest virus (SFV) expression system. APP was first delivered from the cell body to the axon and later appeared also in the dendrites. Inhibition of protein synthesis at the time of axonal expression did not block the late appearance of the protein in the dendrites. An antibody directed against the myc tag, bound to the cell surface at 4 degrees C at the time of axonal APP expression, could be chased to the dendritic domain after subsequent incubation at 37 degrees C. These results suggest that the newly synthesized APP, after initial axonal delivery, may be transported to the dendrites by a transcytotic mechanism. The routing of APP in polarized neurons is different from that of polarized epithelial cells, in which the protein is delivered basolaterally, arguing for neuronal specific sorting and processing mechanisms.
A synthetic E7 gene of human papillomavirus (HPV) type 16 was generated that consists entirely of preferred human codons. Expression analysis of the synthetic E7 gene in human and animal cells showed levels of E7 protein 20-to 100-fold higher than those obtained with wild-type E7. Enhanced expression of E7 protein resulted from highly efficient translation, as well as increased stability of the E7 mRNA due to its codon optimization. Higher levels of E7 protein in cells transfected with synthetic E7 correlated with significant loss of cell viability in various human cell lines. In contrast, lower E7 protein expression driven by the wild-type gene resulted in a slight induction of cell proliferation. Furthermore, mice inoculated with plasmids expressing the synthetic E7 gene produced significantly higher levels of E7 antibodies than littermates injected with wild-type E7, suggesting that synthetic E7 may be useful for DNA immunization studies and the development of genetic vaccines against HPV-16. In view of these results, we hypothesize that HPVs may have retained a pattern of G ؉ C content and codon usage distinct from that of their host cells in response to selective pressure. Thus, the nonhuman codon bias may have been conserved by HPVs to prevent compromising viability of the host cells by excessive viral early protein expression, as well as to evade the immune system.Human papillomaviruses (HPVs) are small double-stranded-DNA viruses that infect stratified epithelia and cause benign and malignant proliferative lesions. A subset of HPVs with mucosal tropism, the so-called "high-risk" HPVs, has been linked to cancers of the uterine cervix (55), which account for about 11% of the global cancer incidence in women. Of these, more than 90% contain HPV DNA, most notably HPV type 16 (HPV-16) and HPV-18, integrated into the host cell genome, where they express two viral early genes, E6 and E7, whose products block p53 and retinoblastoma protein-mediated cell cycle control pathways (38,56). Indeed, the tumorigenic phenotype of HPV relies on continuous expression of the E6 and E7 genes (9). E7 is an oncoprotein which can transform rodent fibroblasts (24), cooperate with activated ras to transform primary cells (34), and, in association with E6, immortalize keratinocytes (10,19,30).Progression from detectable HPV infection to invasive cancer occurs in less than 1% of cases and usually takes more than 2 decades, indicating that additional factors are involved in the process of carcinogenesis. Several lines of evidence suggest that such factors may act by intensifying HPV early gene expression, as illustrated in the following examples. First, disruption or mutation of the viral E2 gene, which is known to repress the HPV early promoter and hence expression of E6 and E7, is observed in cervical carcinogenesis (7,36,42,47,52). Moreover, the site of chromosomal integration of the viral DNA influences expression of viral early genes (48). Second, viral load appears to be a determinant for the development of cervical carcinoma ...
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