MCC inhibits beta-catenin transcriptional activity by sequestering DBC1 in the cytoplasm.

The mutated in colorectal cancer (MCC) is a multifunctional gene showing loss of expression in colorectal and liver cancers. MCC mutations can drive colon carcinogenesis in the mouse and in vitro experiments suggest that loss of MCC function promotes cancer through several important cellular pathways. In particular, the MCC protein is known to regulate beta-catenin (ß-cat) signaling, but the mechanism is poorly understood. Here we show that the ß-cat repressor function of MCC is strongly impaired by the presence of a disease-associated mutation. We also identify deleted in breast cancer 1 (DBC1) as a new MCC interacting partner and regulator of ß-cat signaling. RNA interference experiments show that DBC1 promotes ß-cat transcriptional activity and that the presence of DBC1 is required for MCC-mediated ß-cat repression. In contrast to all other DBC1 interacting partners, MCC does not interact through the DBC1 Leucine Zipper domain but with a glutamic-acid rich region located between the Nudix and EF-hand domains. Furthermore, MCC overexpression relocalizes DBC1 from the nucleus to the cytoplasm and reduces ß-cat K49 acetylation. Treatment of cells with the SIRT1 inhibitor Nicotinamide reverses MCC-induced deacetylation of ß-cat K49. These data suggest that the cytoplasmic MCC-DBC1 interaction sequesters DBC1 away from the nucleus, thereby removing a brake on DBC1 nuclear targets, such as SIRT1. This study provides new mechanistic insights into the DBC1-MCC axis as a new APC independent ß-cat inhibitory pathway.

Exposure to inflammatory cytokines IL-1ß and TNFα induces compromise and death of astrocytes; implications for chronic neuroinflammation.

BACKGROUND: Astrocytes have critical roles in the human CNS in health and disease. They provide trophic support to neurons and are innate-immune cells with keys roles during states-of-inflammation. In addition, they have integral functions associated with maintaining the integrity of the blood-brain barrier. METHODS: We have used cytometric bead arrays and xCELLigence technology to monitor the to monitor the inflammatory response profiles and astrocyte compromise in real-time under various inflammatory conditions. Responses were compared to a variety of inflammatory cytokines known to be released in the CNS during neuroinflammation. Astrocyte compromise measured by xCELLigence was confirmed using ATP measurements, cleaved caspase 3 expression, assessment of nuclear morphology and cell death. RESULTS: Inflammatory activation (IL-1ß or TNFα) of astrocytes results in the transient production of key inflammatory mediators including IL-6, cell surface adhesion molecules, and various leukocyte chemoattractants. Following this phase, the NT2-astrocytes progressively become compromised, which is indicated by a loss of adhesion, appearance of apoptotic nuclei and reduction in ATP levels, followed by DEATH. The earliest signs of astrocyte compromise were observed between 24-48 h post cytokine treatment. However, significant cell loss was not observed until at least 72 h, where there was also an increase in the expression of cleaved-caspase 3. By 96 hours approximately 50% of the astrocytes were dead, with many of the remaining showing signs of compromise too. Numerous other inflammatory factors were tested, however these effects were only observed with IL-1ß or TNFα treatment. CONCLUSIONS: Here we reveal direct sensitivity to mediators of the inflammatory milieu. We highlight the power of xCELLigence technology for revealing the early progressive compromise of the astrocytes, which occurs 24-48 hours prior to substantive cell loss. Death induced by IL-1ß or TNFα is relevant clinically as these two cytokines are produced by various peripheral tissues and by resident brain cells.

Loss of heterozygosity of the Mutated in Colorectal Cancer gene is not associated with promoter methylation in non-small cell lung cancer.

'Mutated in Colorectal Cancer' (MCC) is emerging as a multifunctional protein that affects several cellular processes and pathways. Although the MCC gene is rarely mutated in colorectal cancer, it is frequently silenced through promoter methylation. Previous studies have reported loss of heterozygosity (LOH) of the closely linked MCC and APC loci in both colorectal and lung cancers. APC promoter methylation is a marker of poor survival in non-small cell lung cancer (NSCLC). However, MCC methylation has not been previously studied in lung cancer. Therefore, we wanted to determine if MCC is silenced through promoter methylation in lung cancer and whether this methylation is associated with LOH of the MCC locus or methylation of the APC gene. Three polymorphic markers for the APC/MCC locus were analysed for LOH in 64 NSCLC specimens and matching normal tissues. Promoter methylation of both genes was determined using methylation specific PCR in primary tumours. LOH of the three markers was found in 41-49% of the specimens. LOH within the MCC locus was less common in adenocarcinoma (ADC) (29%) than in squamous cell carcinoma (SCC) (72%; P=0.006) or large cell carcinoma (LCC) (75%; P=0.014). However, this LOH was not accompanied by MCC promoter methylation, which was found in only two cancers (3%). In contrast, 39% of the specimens showed APC methylation, which was more common in ADC (58%) than in SCC (13%). Western blotting revealed that MCC was expressed in a subset of lung tissue specimens but there was marked variation between patients rather than between cancer and matching non-cancer tissue specimens. In conclusion, we have shown that promoter methylation of the APC gene does not extend to the neighbouring MCC gene in lung cancer, but LOH is found at both loci. The variable levels of MCC expression were not associated with promoter methylation and may be regulated through other cellular mechanisms.

The PDZ-binding motif of MCC is phosphorylated at position -1 and controls lamellipodia formation in colon epithelial cells.

In this study, we describe a new post-translational modification at position -1 of the PDZ-binding motif in the mutated in colorectal cancer (MCC) protein and its role in lamellipodia formation. Serine 828 at position -1 of this motif is phosphorylated, which is predicted to increase MCC binding affinity with the polarity protein Scrib. We show that endogenous MCC localizes at the active migratory edge of cells, where it interacts with Scrib and the non-muscle motor protein Myosin-IIB. Expression of MCC harboring a phosphomimetic mutation MCC-S828D strongly impaired lamellipodia formation and resulted in accumulation of Myosin-IIB in the membrane cortex fraction. We propose that MCC regulates lamellipodia formation by binding to Scrib and its downstream partner Myosin-IIB in a multiprotein complex. Importantly, we propose that the function of this complex is under the regulation of a newly described phosphorylation of the PDZ-binding motif at position -1.