Transcription elongation and tissue-specific somatic CAG instability.

The expansion of CAG/CTG repeats is responsible for many diseases, including Huntington's disease (HD) and myotonic dystrophy 1. CAG/CTG expansions are unstable in selective somatic tissues, which accelerates disease progression. The mechanisms underlying repeat instability are complex, and it remains unclear whether chromatin structure and/or transcription contribute to somatic CAG/CTG instability in vivo. To address these issues, we investigated the relationship between CAG instability, chromatin structure, and transcription at the HD locus using the R6/1 and R6/2 HD transgenic mouse lines. These mice express a similar transgene, albeit integrated at a different site, and recapitulate HD tissue-specific instability. We show that instability rates are increased in R6/2 tissues as compared to R6/1 matched-samples. High transgene expression levels and chromatin accessibility correlated with the increased CAG instability of R6/2 mice. Transgene mRNA and H3K4 trimethylation at the HD locus were increased, whereas H3K9 dimethylation was reduced in R6/2 tissues relative to R6/1 matched-tissues. However, the levels of transgene expression and these specific histone marks were similar in the striatum and cerebellum, two tissues showing very different CAG instability levels, irrespective of mouse line. Interestingly, the levels of elongating RNA Pol II at the HD locus, but not the initiating form of RNA Pol II, were tissue-specific and correlated with CAG instability levels. Similarly, H3K36 trimethylation, a mark associated with transcription elongation, was specifically increased at the HD locus in the striatum and not in the cerebellum. Together, our data support the view that transcription modulates somatic CAG instability in vivo. More specifically, our results suggest for the first time that transcription elongation is regulated in a tissue-dependent manner, contributing to tissue-selective CAG instability.

Context is everything: activators can also repress.

Maintenance of genome integrity, cell division and gene expression have all been shown to be regulated by the condensation of DNA into heterochromatin. In a study published in this issue, Bulut-Karslioglu et al. reveal a new heterochromatin function for transcription factors in a mammalian system. They show that instead of activating gene expression, in the context of heterochromatic repeats, specific transcription factors are necessary for the maintenance of transcriptional repression and heterochromatin.

Emi1 regulates the anaphase-promoting complex by a different mechanism than Mad2 proteins.

The anaphase-promoting complex/cyclosome (APC) ubiquitin ligase is activated by Cdc20 and Cdh1 and inhibited by Mad2 and the spindle assembly checkpoint complex, Mad2B, and the early mitotic inhibitor Emi1. Mad2 inhibits APC(Cdc20), whereas Mad2B preferentially inhibits APC(Cdh1). We have examined the mechanism of APC inhibition by Emi1 and find that unlike Mad2 proteins, Emi1 binds and inhibits both APC(Cdh1) and APC(Cdc20). Also unlike Mad2, Emi1 stabilizes cyclin A in the embryo and requires zinc for its APC inhibitory activity. We find that Emi1 binds the substrate-binding region of Cdc20 and prevents substrate binding to the APC, illustrating a novel mechanism of APC inhibition.

Triggering ubiquitination of a CDK inhibitor at origins of DNA replication.

To ensure proper timing of the G1-S transition in the cell cycle, the cyclin E-Cdk2 complex, which is responsible for the initiation of DNA replication, is restrained by the p21(Cip1)/p27(Kip1)/p57(Kip2) family of CDK (cyclin-dependent kinase) inhibitors in humans and by the related p27(Xic1) protein in Xenopus. Activation of cyclin E-Cdk2 is linked to the ubiquitination of human p27(Kip1) or Xenopus p27(Xic1) by SCF (for Skp1-Cullin-F-box protein) ubiquitin ligases. For human p27(Kip1), ubiquitination requires direct phosphorylation by cyclin E-Cdk2. We show here that Xic1 ubiquitination does not require phosphorylation by cyclin E-Cdk2, but it does require nuclear accumulation of the Xic1-cyclin E-Cdk2 complex and recruitment of this complex to chromatin by the origin-recognition complex together with Cdc6 replication preinitiation factors; it also requires an activation step necessitating cyclin E-Cdk2-kinase and SCF ubiquitin-ligase activity, and additional factors associated with mini-chromosome maintenance proteins, including the inactivation of geminin. Components of the SCF ubiquitin-ligase complex, including Skp1 and Cul1, are also recruited to chromatin through cyclin E-Cdk2 and the preinitiation complex. Thus, activation of the cyclin E-Cdk2 kinase and ubiquitin-dependent destruction of its inhibitor are spatially constrained to the site of a properly assembled preinitiation complex.

Emi1 is a mitotic regulator that interacts with Cdc20 and inhibits the anaphase promoting complex.

We have discovered an early mitotic inhibitor, Emi1, which regulates mitosis by inhibiting the anaphase promoting complex/cyclosome (APC). Emi1 is a conserved F box protein containing a zinc binding region essential for APC inhibition. Emi1 accumulates before mitosis and is ubiquitylated and destroyed in mitosis, independent of the APC. Emi1 immunodepletion from cycling Xenopus extracts strongly delays cyclin B accumulation and mitotic entry, whereas nondestructible Emi1 stabilizes APC substrates and causes a mitotic block. Emi1 binds the APC activator Cdc20, and Cdc20 can rescue an Emi1-induced block to cyclin B destruction. Our results suggest that Emi1 regulates progression through early mitosis by preventing premature APC activation, and may help explain the well-known delay between cyclin B/Cdc2 activation and cyclin B destruction.

Cyclin E uses Cdc6 as a chromatin-associated receptor required for DNA replication.

Using an in vitro chromatin assembly assay in Xenopus egg extract, we show that cyclin E binds specifically and saturably to chromatin in three phases. In the first phase, the origin recognition complex and Cdc6 prereplication proteins, but not the minichromosome maintenance complex, are necessary and biochemically sufficient for ATP-dependent binding of cyclin E--Cdk2 to DNA. We find that cyclin E binds the NH(2)-terminal region of Cdc6 containing Cy--Arg-X-Leu (RXL) motifs. Cyclin E proteins with mutated substrate selection (Met-Arg-Ala-Ile-Leu; MRAIL) motifs fail to bind Cdc6, fail to compete with endogenous cyclin E--Cdk2 for chromatin binding, and fail to rescue replication in cyclin E--depleted extracts. Cdc6 proteins with mutations in the three consensus RXL motifs are quantitatively deficient for cyclin E binding and for rescuing replication in Cdc6-depleted extracts. Thus, the cyclin E--Cdc6 interaction that localizes the Cdk2 complex to chromatin is important for DNA replication. During the second phase, cyclin E--Cdk2 accumulates on chromatin, dependent on polymerase activity. In the third phase, cyclin E is phosphorylated, and the cyclin E--Cdk2 complex is displaced from chromatin in mitosis. In vitro, mitogen-activated protein kinase and especially cyclin B--Cdc2, but not the polo-like kinase 1, remove cyclin E--Cdk2 from chromatin. Rebinding of hyperphosphorylated cyclin E--Cdk2 to interphase chromatin requires dephosphorylation, and the Cdk kinase-directed Cdc14 phosphatase is sufficient for this dephosphorylation in vitro. These three phases of cyclin E association with chromatin may facilitate the diverse activities of cyclin E--Cdk2 in initiating replication, blocking rereplication, and allowing resetting of origins after mitosis.

The lore of the RINGs: substrate recognition and catalysis by ubiquitin ligases.

Recently, many new examples of E3 ubiquitin ligases or E3 enzymes have been found to regulate a host of cellular processes. These E3 enzymes direct the formation of multiubiquitin chains on specific protein substrates, and - typically - the subsequent destruction of those proteins. We discuss how the modular architecture of E3 enzymes connects one of two distinct classes of catalytic domains to a wide range of substrate-binding domains. In one catalytic class, a HECT domain transfers ubiquitin directly to substrate bound to a non-catalytic domain. Members of the other catalytic class, found in the SCF, VBC and APC complexes, use a RING finger domain to facilitate ubiquitylation. The separable substrate-recognition domains of E3 enzymes provides a flexible means of linking a conserved ubiquitylation function to potentially thousands of ubiquitylated substrates in eukaryotic cells.

Nuclear accumulation of cyclin E/Cdk2 triggers a concentration-dependent switch for the destruction of p27Xic1.

The action of cyclin-dependent kinases (CDKs) is regulated by phosphorylation, cyclin levels, the abundance of CDK inhibitors, and, as recently has been shown for cyclin B/cdc2, their localization. It is unclear how localization regulates the action of cyclin E/Cdk2 and its inhibitors. Here, we show that the closest known Xenopus laevis homolog of mammalian Cdk2 inhibitors p27(Kip1) and p21(CIP1), Xic1, is concentrated, ubiquitinated, and destroyed in the nucleus. Furthermore, Xic1 destruction requires nuclear import, but not nuclear export, and requires the formation of a transport-competent nuclear envelope, but not interactions between the lamina and chromatin. We show that (i) cyclin E/Cdk2 and Xic1 are transported into the nucleus as a complex and that Xic1 destruction requires the activity of cyclin E, (ii) that phosphorylation of Xic1 by cyclin E/Cdk2 bypasses the requirement for nuclear formation, and (iii) that the phosphorylation of Xic1 by cyclin E/Cdk2 is concentration dependent and likely realized through second-order interactions between stable cyclin E/Cdk2/Xic1 ternary complexes. Based on these results we propose a model wherein nuclear accumulation of the cyclin E/Cdk2/Xic1 complex triggers a concentration-dependent switch that promotes the phosphorylation of Xic1 and, consequently, its ubiquitination and destruction, thus allowing subsequent activation of cyclin E/Cdk2.

Budding yeast Cdc6p induces re-replication in fission yeast by inhibition of SCF(Pop)-mediated proteolysis.

In fission yeast, overexpression of the replication initiator protein Cdc18p induces re-replication, a phenotype characterized by continuous DNA synthesis in the absence of cell division. In contrast, overexpression of Cdc6p, the budding yeast homolog of Cdc18p, does not cause re-replication in S. cerevisiae. However, we have found that Cdc6p has the ability to induce rereplication in fission yeast. Cdc6p cannot functionally replace Cdc18p, but instead interferes with the proteolysis of both Cdc18p and Rum1p, the inhibitor of the protein kinase Cdc2p. This activity of Cdc6p is entirely contained within a short N-terminal peptide, which forms a tight complex with Cdc2p and the F-box/WD-repeat protein Sud1p/Pop2p, a component of the SCF(Pop) ubiquitin ligase in fission yeast. These interactions are mediated by two distinct regions within the N-terminal region of Cdc6p and depend on the integrity of its Cdc2p phosphorylation sites. The data suggest that disruption of re-replication control by overexpression of Cdc6p in fission yeast is a consequence of sequestration of Cdc2p and Pop2p, two factors involved in the negative regulation of Rum1p, Cdc18p and potentially other replication proteins.

Components of an SCF ubiquitin ligase localize to the centrosome and regulate the centrosome duplication cycle.

Centrosomes organize the mitotic spindle to ensure accurate segregation of the chromosomes in mitosis. The mechanism that ensures accurate duplication and separation of the centrosomes underlies the fidelity of chromosome segregation, but remains unknown. In Saccharomyces cerevisiae, entry into S phase and separation of spindle pole bodies each require CDC4 and CDC34, which encode components of an SCF (Skp1-cullin-F-box) ubiquitin ligase, but a direct (SCF) connection to the spindle pole body is unknown. Using immunofluorescence microscopy, we show that in mammalian cells the Skp1 protein and the cullin Cul1 are localized to interphase and mitotic centrosomes and to the cytoplasm and nucleus. Deconvolution and immunoelectron microscopy suggest that Skp1 forms an extended pericentriolar structure that may function to organize the centrosome. Purified centrosomes also contain Skp1, and Cul1 modified by the ubiquitin-like molecule NEDD8, suggesting a role for NEDD8 in targeting. Using an in vitro assay for centriole separation in Xenopus extracts, antibodies to Skp1 or Cul1 block separation. Proteasome inhibitors block both centriole separation in vitro and centrosome duplication in Xenopus embryos. We identify candidate centrosomal F-box proteins, suggesting that distinct SCF complexes may direct proteolysis of factors mediating multiple steps in the centrosome cycle.

F-box/WD-repeat proteins pop1p and Sud1p/Pop2p form complexes that bind and direct the proteolysis of cdc18p.

Ubiquitin-dependent proteolysis plays an important role in cell-cycle control [1] [2]. In budding yeast, the protein Skp1p, the cullin-family member Cdc53p, and the F-box/WD-repeat protein Cdc4p form the SCFCdc4p ubiquitin ligase complex, which targets the cyclin-dependent kinase (Cdk) inhibitor Sic1p for proteolysis [3] [4] [5] [6] [7] [8]. Sic1p is recruited to the SCFCdc4p complex by binding to the WD-repeat region of Cdc4p [5] [6], while Skp1p binds to the F-box of Cdc4p [9]. In fission yeast, two distinct Cdc4p-related proteins, Pop1p/Ste16p [10] [11] and the recently identified Sud1p/Pop2p [12], regulate the stability of the replication initiator Cdc18p and the Cdk inhibitor Rum1p. We show here that, despite their structural and functional similarities, the pop1 and pop2 genes fail to complement each other's deletion phenotypes, indicating that they perform non-redundant, but potentially interdependent, functions in proteolysis. Consistent with this hypothesis, Pop1p and Pop2p formed heterooligomeric complexes when overexpressed, and binding of Cdc18p to Pop2p was dependent on Pop1p. The Pop1p-Pop2p interaction was mediated by the amino-terminal domain of Pop2p which, when fused to full-length Pop1p, rescued the phenotype of a Deltapop1Deltapop2 double mutant. Thus, close physical proximity of two distinct F-box/WD-repeat proteins directs proteolysis mediated by the SCFPop ubiquitin ligase complex.

Cyclin-dependent kinase control of centrosome duplication.

Centrosomes nucleate microtubules and duplicate once per cell cycle. This duplication and subsequent segregation in mitosis results in maintenance of the one centrosome/cell ratio. Centrosome duplication occurs during the G1/S transition in somatic cells and must be coupled to the events of the nuclear cell cycle; failure to coordinate duplication and mitosis results in abnormal numbers of centrosomes and aberrant mitoses. Using both in vivo and in vitro assays, we show that centrosome duplication in Xenopus laevis embryos requires cyclin/cdk2 kinase activity. Injection of the cdk (cyclin-dependent kinase) inhibitor p21 into one blastomere of a dividing embryo blocks centrosome duplication in that blastomere; the related cdk inhibitor p27 has a similar effect. An in vitro system using Xenopus extracts carries out separation of the paired centrioles within the centrosome. This centriole separation activity is dependent on cyclin/cdk2 activity; depletion of either cdk2 or of the two activating cyclins, cyclin A and cyclin E, eliminates centriole separation activity. In addition, centriole separation is inhibited by the mitotic state, suggesting a mechanism of linking the cell cycle to periodic duplication of the centrosome.

Cell cycle: oiling the gears of anaphase.

The anaphase-promoting complex (APC) or cyclosome directs the ubiquitination and destruction of proteins that control specific steps in mitosis. Recent studies show that APC activity requires WD40 domain proteins, and that one of these proteins is part of the checkpoint control that ensures accurate chromosome segregation.

Cell cycle: cull and destroy.

A newly discovered family of proteins homologous to yeast Cdc53, called cullins, may play a key role in the targeting of cell-cycle regulators, such as cyclins, for destruction by ubiquitin-dependent proteolysis.

The cytostatic function of c-Abl is controlled by multiple nuclear localization signals and requires the p53 and Rb tumor suppressor gene products.

c-Abl is a non-receptor protein-tyrosine kinase lacking a clear physiological role. A clue to its normal function is suggested by overexpression of Abl in fibroblasts, which leads to inhibition of cell growth. This effect requires tyrosine kinase activity and the Abl C-terminus. c-Abl is localized to the cell nucleus, where it can bind DNA, and interacts with the retinoblastoma protein, a potential mediator of the growth-inhibitory effect. Nuclear localization of Abl can be directed by a pentalysine nuclear localization signal in the Abl C-terminus. Here, we have identified two additional basic motifs in the Abl C-terminus, either of which can function independently of the pentalysine signal to localize Abl to the nucleus. Using a quantitative transfection assay, we show that both c-Abl and transforming Abl proteins inhibit entry into S phase and this effect is absolutely dependent on nuclear localization. Further, we demonstrate that the Abl cytostatic effect requires both the Rb and p53 tumor suppressor gene products. These results indicate that Abl inhibits cell proliferation by interacting with central elements of the cell cycle control apparatus in the nucleus, and suggest a direct connection between p53 and Rb in this growth-inhibitory pathway.

Early events in DNA replication require cyclin E and are blocked by p21CIP1.

Using immunodepletion of cyclin E and the inhibitor protein p21WAF/CIP1, we demonstrate that the cyclin E protein, in association with Cdk2, is required for the elongation phase of replication on single-stranded substrates. Although cyclin E/Cdk2 is likely to be the major target by which p21 inhibits the initiation of sperm DNA replication, p21 can inhibit single-stranded replication through a mechanism dependent on PCNA. While the cyclin E/Cdk2 complex appears to have a role in the initiation of DNA replication, another Cdk kinase, possibly cyclin A/Cdk, may be involved in a later step controlling the switch from initiation to elongation. The provision of a large maternal pool of cyclin E protein shows that regulators of replication are constitutively present, which explains the lack of a protein synthesis requirement for replication in the early embryonic cell cycle.

Cell cycle arrest by tyrosine kinase Abl involves altered early mitogenic response.

Activated forms of the nuclear and cytoplasmic tyrosine kinase c-Abl are completely cytoplasmic and oncogenic. The overexpression of c-Abl, and in certain fibroblast cell lines even of v-Abl, leads to a cell cycle arrest revealing an alternative Abl function. To facilitate the analysis of this growth inhibitory function we have taken advantage of regulable Abl-estrogen receptor (ABL:ER) fusion proteins. Oncogenic in the presence of estrogen, they are reversibly switched to inhibit cell proliferation upon removal of hormone. Using this system, we demonstrate that inhibition is effected by Abl derivatives which we have previously shown to be hypo-phosphorylated and to have low kinase activity. Since an almost exclusively cytoplasmic ABL:ER protein is fully growth inhibitory, relevant interactions may occur in the cytoplasm. We identify the cell cycle arrest as an early G1 or G0-like block. Interestingly, growth inhibition correlates with an altered expression pattern of early serum response genes; c-Jun mRNA and c-Fos protein levels are elevated in Abl-blocked cells. In view of the two functional modes of overexpressed Abl proteins, one can speculate that normal c-Abl may be involved in relaying growth regulatory signals from the membrane to the nucleus.

Separate domains of p21 involved in the inhibition of Cdk kinase and PCNA.

The protein p21 (WAF1, CIP1 or sdi1), induced by the tumour-suppressor protein p53, interacts with and inhibits two different targets essential for cell-cycle progression. One of these is the cyclin-Cdk family of kinases and the other is the essential DNA replication factor, proliferating-cell nuclear antigen (PCNA). We report here that separate domains of p21 are responsible for interacting with and inhibiting the two targets. An amino-terminal domain inhibits cyclin-Cdk kinases and a carboxy-terminal domain inhibits PCNA. Using these separated domains, we have determined that p21 inhibits different biological systems through different targets. The PCNA-binding domain is sufficient for inhibition of DNA replication based on simian virus 40, whereas the Cdk2-binding domain is sufficient for inhibition of DNA replication based on Xenopus egg extract and for growth suppression in transformed human cells.