Tumour necrosis factor and cancer

TNF is a cytokine whose diverse actions are dependent on the local microenvironment. As a member of the cytokine network, TNF plays an important role in infection and inflammation, but excessive and deregulated production can contribute to disease processes. Likewise in malignant disease, TNF may have a role in cancer therapy and contribute to host response against tumours, but it may also be involved in the progression and spread of the cancer. In experimental models, recombinant TNF can induce significant haemorrhagic necrosis, localised to the tumour vasculature and specific tumour immunity. Although the historical background and preclinical data are promising, systemic therapy with TNF in human cancer has proved highly toxic and is inactive against all tumour types so far tested. Local therapy, particularly isolated limb perfusion, has resulted in complete and long lasting tumour regressions with necrotic activity confined solely to the tumour vascular bed. However, in several animal models, TNF contributes to malignant progression and there is evidence that TNF may have autocrine or paracrine actions in human ovarian cancer.     

miR-105 Inhibits Prostate Tumour Growth by Suppressing CDK6 Levels

A significant role for micro (mi)RNA in the regulation of gene expression in tumours has been recently established. In order to further understand how miRNA expression may contribute to prostate tumour growth and progression, we evaluated expression of miRNA in two invasive prostate tumour lines, PC3 and DU145, and compared it to that in normal prostate epithelial cells. Although a number of miRNAs were differentially expressed, we focused our analysis on miR-105, a novel miRNA not previously linked to prostate cancer. miR-105 levels were significantly decreased in both tumour cell lines in comparison to normal prostate epithelial cells. To determine its potential role in prostate cancer pathogenesis, we overexpressed miR-105 in both PC3 and DU145 cells and determined its effect on various tumourigenic properties. miR-105 overexpression inhibited tumour cell proliferation, tumour growth in anchorage-independent three-dimensional conditions and tumour invasion in vitro, properties of highly aggressive tumour cells. Of potential clinical significance, miR-105 overexpression inhibited tumour growth in vivo in xenograft models using these cell lines. We further identified CDK6 as a putative target of miR-105 which is likely a main contributor to the inhibition of tumour cell growth observed in our assays. Our results suggest that miR-105 inhibits tumour cell proliferation and hence may represent a novel therapeutically relevant cellular target to inhibit tumour growth or a marker of aggressive tumours in prostate cancer patients.     

Molecular Mimics of the Tumour Antigen MUC1

A key requirement for the development of cancer immunotherapy is the identification of tumour-associated antigens that are differentially or exclusively expressed on the tumour and recognized by the host immune system. However, immune responses to such antigens are often muted or lacking due to the antigens being recognized as “self”, and further complicated by the tumour environment and regulation of immune cells within. In an effort to circumvent the lack of immune responses to tumour antigens, we have devised a strategy to develop potential synthetic immunogens. The strategy, termed mirror image phage display, is based on the concept of molecular mimicry as demonstrated by the idiotype/anti-idiotype paradigm in the immune system. Here as ‘proof of principle’ we have selected molecular mimics of the well-characterised tumour associated antigen, the human mucin1 protein (MUC1) from two different peptide phage display libraries. The putative mimics were compared in structure and function to that of the native antigen. Our results demonstrate that several of the mimic peptides display T-cell stimulation activity in vitro when presented by matured dendritic cells. The mimic peptides and the native MUC1 antigenic epitopes can cross-stimulate T-cells. The data also indicate that sequence homology and/or chemical properties to the original epitope are not the sole determining factors for the observed immunostimulatory activity of the mimic peptides.