MicroRNA-146a controls functional plasticity in γδ T cells by targeting NOD1.

γδ T cells are major providers of proinflammatory cytokines. They are preprogrammed in the mouse thymus into distinct subsets producing either interleukin-17 (IL-17) or interferon-γ (IFN-γ), which segregate with CD27 expression. In the periphery, CD27 γδ (γδ27) T cells can be induced under inflammatory conditions to coexpress IL-17 and IFN-γ; the molecular basis of this functional plasticity remains to be determined.

Telomere dysfunction is related to the intrinsic radio-resistance of human oral cancer cells.

Evidence from telomerase-deficient mice strongly suggests that dysfunctional short telomeres affect cellular radio-sensitivity but this idea has yet to be extensively tested in relevant human cancer types such as oral squamous cell carcinomas (OSCCs), which are frequently treated by radiotherapy. The OSCC line BICR7 has low levels of telomerase activity, short telomeres and high levels of telomere dysfunction (judged by a high level of anaphase bridges); whereas the BICR6 line has high levels of telomerase and is more radio-resistant. Ectopic expression of the human TElomerase Reverse Transcriptase (hTERT) reduced telomere dysfunction and increased radio-resistance in BICR7 cells, but not BICR6.

Analysis of telomerase activity and telomere function in cancer.

Telomeres are the structures at the ends of chromosomes, composed of repetitive sequences and associated proteins, which cap chromosome ends to maintain genomic stability. These structures are maintained by the enzyme complex telomerase in germ cells and some stem cells, but are absent in the majority of somatic cells. The consequence of this lack of telomerase in normal somatic cells is the shortening of the telomeric repeat, which results in a limited replicative life span.

Senescing oral dysplasias are not immortalized by ectopic expression of hTERT alone without other molecular changes, such as loss of INK4A and/or retinoic acid receptor-beta: but p53 mutations are not necessarily required.

Our previous work showed that acquisition of immortality at the dysplasia stage of oral cancer progression was consistently associated with four changes: loss of retinoic acid receptor (RAR)-beta and p16INK4A expression, p53 mutations and activation of telomerase. One atypical dysplasia (D17) that underwent delayed senescence after an extended lifespan showed loss of RAR-beta and p16INK4A/p14ARF expression, but retained functional wild-type p53 and telomerase was not activated. We now demonstrate that retroviral delivery of hTERT results in telomere lengthening and immortalization of D17 without loss of functional wild-type p53 activity.

High levels of telomere dysfunction bestow a selective disadvantage during the progression of human oral squamous cell carcinoma.

Human epithelial cells experience multiple barriers to cellular immortality in culture (mortality mechanisms 0, 1, and 2). Mortality mechanism 2 (M2) is termed crisis and involves telomere dysfunction due to lack of telomerase. However, proliferating normal keratinocytes in vivo can express telomerase, so it is unclear whether human squamous cell carcinomas (SCCs), which usually have high telomerase levels, develop from preexisting telomerase-positive precursors or by the activation of telomerase in telomerase-deficient somatic cells.

Functional evidence for a squamous cell carcinoma mortality gene(s) on human chromosome 4.

Squamous cell carcinoma (SCC) immortality is associated with p53 and INK4A dysfunction, high levels of telomerase and loss of heterozygosity (LOH) of other chromosomes, including chromosome 4. To test for a functional cancer mortality gene on human chromosome 4 we introduced a complete or fragmented copy of the chromosome into SCC lines by microcell-mediated chromosome transfer (MMCT). Human chromosome 4 caused a delayed crisis, specifically in SCC lines with LOH on chromosome 4, but chromosomes 3, 6, 11 and 15 were without effect.

Telomerase inhibition and the future management of head-and-neck cancer.

Telomeres are tandem repeats of DNA associated with specific proteins. These structures cap eukaryotic chromosomes and maintain the integrity of the chromosome ends. In the germline, telomeres are maintained by the enzyme telomerase, but in normal somatic cells the enzyme's activity is low or undetectable.