Indirect cholinergic activation slows down pancreatic cancer growth and tumor-associated inflammation.

BACKGROUND: Nerve-cancer interactions are increasingly recognized to be of paramount importance for the emergence and progression of pancreatic cancer (PCa). Here, we investigated the role of indirect cholinergic activation on PCa progression through inhibition of acetylcholinesterase (AChE) via clinically available AChE-inhibitors, i.e. physostigmine and pyridostigmine. METHODS: We applied immunohistochemistry, immunoblotting, MTT-viability, invasion, flow-cytometric-cell-cycle-assays, phospho-kinase arrays, multiplex ELISA and xenografted mice to assess the impact of AChE inhibition on PCa cell growth and invasiveness, and tumor-associated inflammation. Survival analyses were performed in a novel genetically-induced, surgically-resectable mouse model of PCa under adjuvant treatment with gemcitabine+/-physostigmine/pyridostigmine (n = 30 mice). Human PCa specimens (n = 39) were analyzed for the impact of cancer AChE expression on tumor stage and survival. RESULTS: We discovered a strong expression of AChE in cancer cells of human PCa specimens. Inhibition of this cancer-cell-intrinsic AChE via pyridostigmine and physostigmine, or administration of acetylcholine (ACh), diminished PCa cell viability and invasion in vitro and in vivo via suppression of pERK signaling, and reduced tumor-associated macrophage (TAM) infiltration and serum pro-inflammatory cytokine levels. In the novel genetically-induced, surgically-resectable PCa mouse model, adjuvant co-therapy with AChE blockers had no impact on survival. Accordingly, survival of resected PCa patients did not differ based on tumor AChE expression levels. Patients with higher-stage PCa also exhibited loss of the ACh-synthesizing enzyme, choline-acetyltransferase (ChAT), in their nerves. CONCLUSION: For future clinical trials of PCa, direct cholinergic stimulation of the muscarinic signaling, rather than indirect activation via AChE blockade, may be a more effective strategy.

Virotherapy Research in Germany: From Engineering to Translation.

Virotherapy is a unique modality for the treatment of cancer with oncolytic viruses (OVs) that selectively infect and lyse tumor cells, spread within tumors, and activate anti-tumor immunity. Various viruses are being developed as OVs preclinically and clinically, several of them engineered to encode therapeutic proteins for tumor-targeted gene therapy. Scientists and clinicians in German academia have made significant contributions to OV research and development, which are highlighted in this review paper. Innovative strategies for "shielding," entry or postentry targeting, and "arming" of OVs have been established, focusing on adenovirus, measles virus, parvovirus, and vaccinia virus platforms. Thereby, new-generation virotherapeutics have been derived. Moreover, immunotherapeutic properties of OVs and combination therapies with pharmacotherapy, radiotherapy, and especially immunotherapy have been investigated and optimized. German investigators are increasingly assessing their OV innovations in investigator-initiated and sponsored clinical trials. As a prototype, parvovirus has been tested as an OV from preclinical proof-of-concept up to first-in-human clinical studies. The approval of the first OV in the Western world, T-VEC (Imlygic), has further spurred the involvement of investigators in Germany in international multicenter studies. With the encouraging developments in funding, commercialization, and regulatory procedures, more German engineering will be translated into OV clinical trials in the near future.

A telomerase-dependent conditionally replicating adenovirus for selective treatment of cancer.

The catalytic component of human telomerase reverse transcriptase (hTERT) is not expressed in most primary somatic human cells, whereas the majority of cancer cells reactivate telomerase by transcriptional up-regulation of hTERT. Several studies demonstrated that the hTERT promoter can be used to restrict gene expression of E1-deleted replication defective adenoviral vectors to telomerase-positive cancer cells. In this study, a conditionally replicating adenovirus (hTERT-Ad) expressing E1A genes under control of a 255-bp hTERT-promoter was constructed. Additionally, an internal ribosomal entry site-enhanced green fluorescent protein cassette was inserted downstream of the E1B locus to monitor viral replication in vivo. Adenoviral replication of hTERT-Ad and enhancement of enhanced green fluorescent protein expression could be observed in all investigated telomerase-positive tumor cell lines. In contrast, hTERT-Ad infection of telomerase-negative primary human hepatocytes did not result in significant replication. The capability of hTERT-Ad to induce cytopathic effects in tumor cells was comparable with that of adenovirus wild type and significantly higher compared with ONYX-015, regardless of the p53 status of the tumor cells. Single application of low-dose hTERT-Ad to tumor xenografts led to significant inhibition of tumor growth, confirming the potential therapeutic value of conditionally replicative adenoviral vectors. These in vivo experiments also revealed that hTERT-Ad-mediated oncolysis was more efficient than ONYX-015 treatment. These results demonstrate that expression of E1A under transcriptional control of the hTERT promoter is sufficient for effective telomerase-dependent adenovirus replication as a promising perspective for the treatment of the majority of epithelial tumors.