Fbw7 and its counteracting forces in stem cells and cancer: Oncoproteins in the balance.

Fbw7 is well characterised as a stem cell regulator and tumour suppressor, powerfully positioned to control proliferation, differentiation and apoptosis by targeting key transcription factors for ubiquitination and destruction. Evidence in support of these roles continues to accumulate from in vitro studies, mouse models and human patient data. Here we summarise the latest of these findings, highlighting the tumour-suppressive role of Fbw7 in multiple tissues, and the rare circumstances where Fbw7 activity can be oncogenic. We discuss mechanisms that regulate ubiquitination by Fbw7, including ubiquitin-specific proteases such as USP28 that counteract Fbw7 activity and thereby stabilise oncoproteins. Deubiquitination of key Fbw7 substrates to prevent their destruction is beginning to be appreciated as an important pro-tumourigenic mechanism. As the ubiquitin-proteasome system represents a largely untapped field for drug development, the interplay between Fbw7 and its counterpart deubiquitinating enzymes in tumours is likely to attract increasing interest and influence future treatment strategies.

Stem cell and progenitor fate in the mammalian intestine: Notch and lateral inhibition in homeostasis and disease.

The control of cell fate decisions is vital to build functional organs and maintain normal tissue homeostasis, and many pathways and processes cooperate to direct cells to an appropriate final identity. Because of its continuously renewing state and its carefully organised hierarchy, the mammalian intestine has become a powerful model to dissect these pathways in health and disease. One of the signalling pathways that is key to maintaining the balance between proliferation and differentiation in the intestinal epithelium is the Notch pathway, most famous for specifying distinct cell fates in adjacent cells via the evolutionarily conserved process of lateral inhibition. Here, we will review recent discoveries that advance our understanding of how cell fate in the mammalian intestine is decided by Notch and lateral inhibition, focusing on the molecular determinants that regulate protein turnover, transcriptional control and epigenetic regulation.

Extensive DNA damage-induced sumoylation contributes to replication and repair and acts in addition to the mec1 checkpoint.

The cellular response to DNA damage employs multiple dynamic protein modifications to exert rapid and adaptable effects. Substantial work has detailed the roles of canonical checkpoint-mediated phosphorylation in this program. Recent studies have also implicated sumoylation in the DNA damage response; however, a systematic view of the contribution of sumoylation to replication and repair and its interplay with checkpoints is lacking. Here, using a biochemical screen in yeast, we establish that DNA damage-induced sumoylation occurs on a large scale. We identify MRX (Mre11-Rad50-Xrs2) as a positive regulator of this induction for a subset of repair targets. In addition, we find that defective sumoylation results in failure to complete replication of a damaged genome and impaired DNA end processing, highlighting the importance of the SUMO-mediated response in genome integrity. We also show that DNA damage-induced sumoylation does not require Mec1 checkpoint signaling, and the presence of both enables optimal DNA damage resistance.

Sumoylation and the DNA damage response.

The cellular response to DNA damage involves multiple pathways that work together to promote survival in the face of increased genotoxic lesions. Proteins in these pathways are often posttranslationally modified, either by small groups such as phosphate, or by protein modifiers such as ubiquitin or SUMO. The recent discovery of many more SUMO substrates that are modified at higher levels in damage conditions adds weight to the accumulated evidence suggesting that sumoylation plays an important functional role in the DNA damage response. Here we discuss the significance of DNA damage-induced sumoylation, the effects of sumoylation on repair proteins, sumoylation dynamics, and crosstalk with other posttranslational modifications in the DNA damage response.

A genetic screen for anchorage-independent proliferation in mammalian cells identifies a membrane-bound neuregulin.

Anchorage-independent proliferation is a hallmark of oncogenic transformation and is thought to be conducive to proliferation of cancer cells away from their site of origin. We have previously reported that primary Schwann cells expressing the SV40 Large T antigen (LT) are not fully transformed in that they maintain a strict requirement for attachment, requiring a further genetic change, such as oncogenic Ras, to gain anchorage-independence. Using the LT-expressing cells, we performed a genetic screen for anchorage-independent proliferation and identified Sensory and Motor Neuron Derived Factor (SMDF), a transmembrane class III isoform of Neuregulin 1. In contrast to oncogenic Ras, SMDF induced enhanced proliferation in normal primary Schwann cells but did not trigger cellular senescence. In cooperation with LT, SMDF drove anchorage-independent proliferation, loss of contact inhibition and tumourigenicity. This transforming ability was shared with membrane-bound class III but not secreted class I isoforms of Neuregulin, indicating a distinct mechanism of action. Importantly, we show that despite being membrane-bound signalling molecules, class III neuregulins transform via a cell intrinsic mechanism, as a result of constitutive, elevated levels of ErbB signalling at high cell density and in anchorage-free conditions. This novel transforming mechanism may provide new targets for cancer therapy.

Loss of anchorage in checkpoint-deficient cells increases genomic instability and promotes oncogenic transformation.

Mammalian cells generally require both mitogens and anchorage signals in order to proliferate. An important characteristic of many tumour cells is that they have lost this anchorage-dependent cell-cycle checkpoint, allowing them to proliferate without signals provided by their normal microenvironment. In the absence of anchorage signals from the extracellular matrix, many cell types arrest cell-cycle progression in G1 phase as a result of Rb-dependent checkpoints. However, despite inactivation of p53 and Rb proteins, SV40LT-expressing cells retain anchorage dependency, suggesting the presence of an uncharacterised cell-cycle checkpoint, which can be overridden by coexpression of oncogenic Ras. We report here that, although cyclin-CDK complexes persisted in suspension, proliferation was inhibited in LT-expressing cells by the CDK inhibitor p27(Kip1) (p27). Interestingly, this did not induce a stable arrest, but aberrant cell-cycle progression associated with stalled DNA replication, rereplication and chromosomal instability, which was sufficient to increase the frequency of oncogenic transformation. These results firstly indicate loss of anchorage in Rb- and p53-deficient cells as a novel mechanism for promotion of genomic instability; secondly suggest that anchorage checkpoints that protect normal cells from inappropriate proliferation act deleteriously in Rb- and p53-deficient cells to promote tumourigenesis; and thirdly indicate caution in the use of CDK inhibitors for cancer treatment.

NF1 loss disrupts Schwann cell-axonal interactions: a novel role for semaphorin 4F.

Neurofibromatosis type 1 (NF1) patients develop neurofibromas, tumors of Schwann cell origin, as a result of loss of the Ras-GAP neurofibromin. In normal nerves, Schwann cells are found tightly associated with axons, while loss of axonal contact is a frequent and important early event in neurofibroma development. However, the molecular basis of this physical interaction or how it is disrupted in cancer remains unclear. Here we show that loss of neurofibromin in Schwann cells is sufficient to disrupt Schwann cell/axonal interactions via up-regulation of the Ras/Raf/ERK signaling pathway. Importantly, we identify down-regulation of semaphorin 4F (Sema4F) as the molecular mechanism responsible for the Ras-mediated loss of interactions. In heterotypic cocultures, Sema4F knockdown induced Schwann cell proliferation by relieving axonal contact-inhibitory signals, providing a mechanism through which loss of axonal contact contributes to tumorigenesis. Importantly, Sema4F levels were strongly reduced in a panel of human neurofibromas, confirming the relevance of these findings to the human disease. This work identifies a novel role for the guidance-molecules semaphorins in the mediation of Schwann cell/axonal interactions, and provides a molecular mechanism by which heterotypic cell-cell contacts control cell proliferation and suppress tumorigenesis. Finally, it provides a new approach for the development of therapies for NF1.