Mastermind recruits CycC:CDK8 to phosphorylate the Notch ICD and coordinate activation with turnover

Recording Notch signaling in real time

Notch signaling is a highly conserved signaling pathway, which is critical for many cell fate decisions. Ligand activation of Notch leads to cleavage of the Notch receptor and liberation of the Notch intracellular domain (ICD) from the membrane-tethered receptor. After translocation to the nucleus, the Notch ICD interacts with the DNA-binding protein CSL to activate gene transcription. To better understand the temporal and spatial aspects of Notch signaling, we here describe a fluorescent protein-based reporter assay that allows Notch activation to be followed in real time in individual cells. We have generated a reporter construct composed of 12 CSL-binding motifs linked to fluorescent proteins with different half-lives: a stabler red fluorescent protein (DsRedExpressDR) and a destabilized form of green fluorescent protein (d1EGFP). The fluorescent reporters reflect the activation status of Notch signaling with single-cell resolution. The reporters rapidly respond to various forms of Notch activation, including ligand activation of full-length Notch receptors. Finally, we use this assay to gain insights into the level of Notch signaling in CNS progenitor cells in culture and in vivo.

Target selectivity of vertebrate notch proteins. Collaboration between discrete domains and CSL-binding site architecture determines activation probability

All four mammalian Notch proteins interact with a single DNA-binding protein (RBP-jkappa), yet they are not equivalent in activating target genes. Parallel assays of three Notch-responsive promoters in several cell lines revealed that relative activation strength is dependent on protein module and promoter context more than the cellular context. Each Notch protein reads binding site orientation and distribution on the promoter differently; Notch1 performs extremely well on paired sites, and Notch3 prefers single sites in conjunction with a proximal zinc finger transcription factor. Although head-head sites can elicit a Notch response on their own, use of CBS (CSL binding site) in tail-tail orientation is context-dependent. Bias for specific DNA elements is achieved by interplay between the N-terminal RAM (RBP-jkappa-associated molecule/ankyrin region), which interprets CBS proximity and orientation, and the C-terminal transactivation domain that interacts specifically with the transcription machinery or nearby factors. To confirm the prediction that modular design underscores the evolution of functional divergence between Notch proteins, we generated a synthetic Notch protein (Notch1 ankyrin with Notch3 transactivation domain) that displayed superior signaling strength on the hes5 promoter. Consistent with the prediction that "preferred" targets (Hes1) should respond faster and at lower Notch concentration than other targets, we showed that Hes5-GFP was extinguished fast and recovered slowly, whereas Hes1-GFP was inhibited late and recovered quickly after a pulse of DAPT in metanephroi cultures.

Lasting longer without oxygen: The influence of hypoxia on Notch signaling

Notch signaling has multiple functions during invertebrate and vertebrate development, where it plays important roles in cell fate determination, proliferation, survival, and border formation. The precise function of Notch signaling is context dependent, and one of the unsolved mysteries of Notch signaling is how a relatively stereotyped signal transduction pathway exerts such a wide variety of context-specific responses. Recent data from Gustaffson et al. provide important new information on this topic by showing that hypoxia enhances Notch signaling due to the association of Notch and HIF-1alpha. This interaction may have important consequences for tumor cell growth.

Analysis of transmembrane domain mutants is consistent with sequential cleavage of Notch by gamma-secretase

gamma-Secretase is a lipid-embedded, intramembrane-cleaving aspartyl protease that cleaves its substrates twice within their transmembrane domains (TMD): once near the cytosolic leaflet (at S3/epsilon) and again in the middle of the TMD (at S4/gamma). To address whether this unusual process occurs in two independent or interdependent steps, we investigated how mutations at the S3/epsilon site in Notch1-based substrates impact proteolysis. We demonstrate that such mutations greatly inhibit not only gamma-secretase-mediated cleavage at S3 but also at S4, independent of their impact on NICD stability. These results, together with our previous observations, suggest that hydrolysis at the center of the Notch transmembrane domain (S4/gamma) is dependent on the S3/epsilon cleavage. Notch (and perhaps all gamma-secretase substrates) may be cleaved by sequential proteolysis starting at S3.

The Notch pathway in cancer: differentiation gone awry

The Notch signalling cascade influences several key aspects of normal development by regulating differentiation, proliferation and apoptosis. Its association to human cancer is firmly established in T-cell leukaemia where point mutations or chromosomal translocations lead to constitutive signalling. Accumulating data indicate that deregulated Notch activity is involved also in the genesis of other human cancers, such as pancreatic cancer, medulloblastoma and mucoepidermoid carcinoma. In these tumours, the oncogenic effect of Notch signalling reflects an aberrant recapitulation of the highly tissue-specific function of the cascade during normal development and in tissue homeostasis.

Mediator expression profiling epistasis reveals a signal transduction pathway with antagonistic submodules and highly specific downstream targets

Mediator is an evolutionarily conserved coregulator of RNA polymerase II transcription. Microarray structure-function analysis of S. cerevisiae Mediator reveals functional antagonism between the cyclin-dependent kinase (Cdk) submodule and components from the Tail (Med15, Med2, Med3), Head (Med20, Med18), and Middle (Med31). Certain genes exhibit increased or decreased expression, depending on which subunit is deleted. Epistasis analysis with expression-profile phenotypes shows that MED2 and MED18 are downstream of CDK8. Strikingly, Cdk8-mediated modification of a single amino acid within Mediator represses the regulon of a single transcription factor, Rcs1/Aft1. Highly specific gene regulation is thought to be determined by activators and combinatorial use of cofactors. Here, subtle modification of the general transcription machinery through one of its own components is shown to determine highly specific expression patterns. Expression profiling can therefore precisely map regulatory cascades, and our findings support a role for Mediator as a direct processor of signaling pathways for determining specificity.

Notch signaling in the mammalian central nervous system: insights from mouse mutants

The Notch pathway, although originally identified in fruit flies, is now among the most heavily studied in mammalian biology. In mice, loss-of-function and gain-of-function work has demonstrated that Notch signaling is essential both during development and in the adult in a multitude of tissues. Prominent among these is the CNS, where Notch has been implicated in processes ranging from neural stem cell regulation to learning and memory. Here we review the role of Notch in the mammalian CNS by focusing specifically on mutations generated in mice. These mutations have provided critical insight into Notch function in the CNS and have led to the identification of promising new directions that are likely to generate important discoveries in the future.

The mammalian Mediator complex and its role in transcriptional regulation

Mediator is an essential component of the RNA polymerase II general transcriptional machinery and plays a crucial part in the activation and repression of eukaryotic mRNA synthesis. The Saccharomyces cerevisiae Mediator was the first to be defined and is a high molecular mass complex composed of >20 distinct subunits that performs multiple activities in transcription. Recent studies have defined the subunit composition and associated activities of mammalian Mediator, and revealed a striking evolutionary conservation of Mediator structure and function from yeast to man.

Structure of the Mediator Subunit Cyclin C and its Implications for CDK8 Function

Cyclin C binds the cyclin-dependent kinases CDK8 and CDK3, which regulate mRNA transcription and the cell cycle, respectively. The crystal structure of cyclin C reveals two canonical five-helix repeats and a specific N-terminal helix. In contrast to other cyclins, the N-terminal helix is short, mobile, and in an exposed position that allows for interactions with proteins other than the CDKs. A model of the CDK8/cyclin C pair reveals two regions in the interface with apparently distinct roles. A conserved region explains promiscuous binding of cyclin C to CDK8 and CDK3, and a non-conserved region may be responsible for discrimination of CDK8 against other CDKs involved in transcription. A conserved and cyclin C-specific surface groove may recruit substrates near the CDK8 active site. Activation of CDKs generally involves phosphorylation of a loop at a threonine residue. In CDK8, this loop is longer and the threonine is absent, suggesting an alternative mechanism of activation that we discuss based on a CDK8-cyclin C model.

Regulation of lymphoid development, differentiation, and function by the Notch pathway

The Notch pathway is gaining increasing recognition as a key regulator of developmental choices, differentiation, and function throughout the hematolymphoid system. Notch controls the generation of hematopoietic stem cells during embryonic development and may affect their subsequent homeostasis. Commitment to the T cell lineage and subsequent stages of early thymopoiesis is critically regulated by Notch. Recent data indicate that Notch can also direct the differentiation and activity of peripheral T and B cells. Thus, the full spectrum of Notch effects is just beginning to be understood. In this review, we discuss this explosion of knowledge as well as current controversies and challenges in the field.

A human splicing factor, SKIP, associates with P-TEFb and enhances transcription elongation by HIV-1 Tat

HIV-1 Tat binds human CyclinT1 and recruits the CDK9/P-TEFb complex to the viral TAR RNA in a step that links RNA polymerase II (RNAPII) C-terminal domain (CTD) Ser 2 phosphorylation with transcription elongation. Previous studies have suggested a connection between Tat and pre-mRNA splicing factors. Here we show that the splicing-associated c-Ski-interacting protein, SKIP, is required for Tat transactivation in vivo and stimulates HIV-1 transcription elongation, but not initiation, in vitro. SKIP associates with CycT1:CDK9/P-TEFb and Tat:P-TEFb complexes in nuclear extracts and interacts with recombinant Tat:P-TEFb:TAR RNA complexes in vitro, indicating that it may act through nascent RNA to overcome pausing by RNAPII. SKIP also associates with U5snRNP proteins and tri-snRNP110K in nuclear extracts, and facilitates recognition of an alternative Tat-specific splice site in vivo. The effects of SKIP on transcription elongation, binding to P-TEFb, and splicing are mediated through the SNW domain. HIV-1 Tat transactivation is accompanied by the recruitment of P-TEFb, SKIP, and tri-snRNP110K to the integrated HIV-1 promoter in vivo, whereas the U5snRNPs associate only with the transcribed coding region. These findings suggest that SKIP plays independent roles in transcription elongation and pre-mRNA splicing.

Notch signaling controls the generation and differentiation of early T lineage progenitors

Signaling by the transmembrane receptor Notch is critical for T lineage development, but progenitor subsets that first receive Notch signals have not been defined. Here we identify an immature subset of early T lineage progenitors (ETPs) in the thymus that expressed the tyrosine kinase receptor Flt3 and had preserved B lineage potential at low progenitor frequency. Notch signaling was active in ETPs and was required for generation of the ETP population. Additionally, Notch signals contributed to the subsequent differentiation of ETPs. In contrast, multipotent hematopoietic progenitors circulated in the blood even in the absence of Notch signaling, suggesting that critical Notch signals during early T lineage development are delivered early after thymic entry.

Dynamic regulation of pol II transcription by the mammalian Mediator complex

Mammalian Mediator is a key coactivator that enables transcriptional activators to regulate transcription by RNA polymerase II (pol II). Like the yeast complex to which it is phylogenetically related, it contains up to 30 subunits. These subunits are organized as a tightly associated core sub-complex, which associates with several groups of subunits that might constitute distinct modules. Although the complex seems to be universally required at all genes, specific subunits are dedicated to regulation of distinct expression programs via interactions with relevant gene-specific transcriptional activators. These interactions, in conjunction with dynamic effects of the core complex on pol II and the general transcription factors, lead to activation of transcription at the target gene. In addition, the compositional complexity of the Mediator allows for assimilation of other diverse signals such as those emanating from repressors and other coactivators.

Genome-wide surveys for phosphorylation-dependent substrates of SCF ubiquitin ligases

The SCF (Skp1-Cullin-F-box) family of ubiquitin ligases target numerous substrates for ubiquitin-dependent proteolysis, including cell cycle regulators, transcription factors, and signal transducers. Substrates are recruited to an invariant core SCF complex through one of a large family of substrate-specific adapter subunits called F-box proteins, each of which binds multiple specific substrates, often in a phosphorylation-dependent manner. The identification of substrates for SCF complexes has proven difficult, especially given the requirement of often complex phosphorylation events for substrate recognition. The archetype for such interactions is the binding of the yeast F-box protein Cdc4 to its various substrates by means of multiple motifs that weakly match an optimal consensus called the Cdc4 phosphodegron (CPD), which is phosphorylated by cyclin-dependent kinases (CDKs) and possibly other kinases. Provided phosphodegron recognition motifs and/or the targeting kinases for SCF substrates are delineated, it is possible to use genome-wide methods to identify new substrates. Here we describe two methods for the systematic retrieval of SCF substrates based on membrane arrays of synthetic phosphopeptides and on genome-wide kinase substrate profiles. In the first approach, which identifies substrates with strong matches to the CPD, a search of the predicted yeast proteome with the optimal CPD motif identified approximately 1100 matches. A phosphopeptide membrane array corresponding to each of these sequences is then probed with recombinant Cdc4, thereby identifying potential substrates. In the second approach, which identifies substrates that lack strong CPD motifs, a genome-wide set of recombinant CDK substrates is phosphorylated and directly assayed for binding to Cdc4. The proteins corresponding to these hits from each approach can then be subjected to the more stringent criteria of phosphorylation-dependent binding to Cdc4, ubiquitination by SCF(Cdc4)in vitro, and Cdc4-dependent protein instability in vivo. Both methods have identified novel substrates of Cdc4 and may, in principle, be used to identify numerous new substrates of other SCF and SCF-like complexes from yeast to humans.