David V. Hansen

Mouse Emi2 is required to enter meiosis II by reestablishing cyclin B1 during interkinesis

During interkinesis, a metaphase II (MetII) spindle is built immediately after the completion of meiosis I. Oocytes then remain MetII arrested until fertilization. In mouse, we find that early mitotic inhibitor 2 (Emi2), which is an anaphase-promoting complex inhibitor, is involved in both the establishment and the maintenance of MetII arrest. In MetII oocytes, Emi2 needs to be degraded for oocytes to exit meiosis, and such degradation, as visualized by fluorescent protein tagging, occurred tens of minutes ahead of cyclin B1. Emi2 antisense morpholino knockdown during oocyte maturation did not affect polar body (PB) extrusion. However, in interkinesis the central spindle microtubules from meiosis I persisted for a short time, and a MetII spindle failed to assemble. The chromatin in the oocyte quickly decondensed and a nucleus formed. All of these effects were caused by the essential role of Emi2 in stabilizing cyclin B1 after the first PB extrusion because in Emi2 knockdown oocytes a MetII spindle was recovered by Emi2 rescue or by expression of nondegradable cyclin B1 after meiosis I.

The Evi5 Oncogene Regulates Cyclin Accumulation by Stabilizing the Anaphase-Promoting Complex Inhibitor Emi1

The anaphase-promoting complex/cyclosome (APC/C) inhibitor Emi1 controls progression to S phase and mitosis by stabilizing key APC/C ubiquitination substrates, including cyclin A. Examining Emi1 binding proteins, we identified the Evi5 oncogene as a regulator of Emi1 accumulation. Evi5 antagonizes SCF(betaTrCP)-dependent Emi1 ubiquitination and destruction by binding to a site adjacent to Emi1s DSGxxS degron and blocking both degron phosphorylation by Polo-like kinases and subsequent betaTrCP binding. Thus, Evi5 functions as a stabilizing factor maintaining Emi1 levels in S/G2 phase. Evi5 protein accumulates in early G1 following Plk1 destruction and is degraded in a Plk1- and ubiquitin-dependent manner in early mitosis. Ablation of Evi5 induces precocious degradation of Emi1 by the Plk/SCF(betaTrCP) pathway, causing premature APC/C activation; cyclin destruction; cell-cycle arrest; centrosome overduplication; and, finally, mitotic catastrophe. We propose that the balance of Evi5 and Polo-like kinase activities determines the timely accumulation of Emi1 and cyclin, ensuring mitotic fidelity.

A rare mutation in UNC5C predisposes to late-onset Alzheimer's disease and increases neuronal cell death

We have identified a rare coding mutation, T835M (rs137875858), in the UNC5C netrin receptor gene that segregated with disease in an autosomal dominant pattern in two families enriched for late-onset Alzheimers disease and that was associated with disease across four large case-control cohorts (odds ratio = 2.15, Pmeta = 0.0095). T835M alters a conserved residue in the hinge region of UNC5C, and in vitro studies demonstrate that this mutation leads to increased cell death in human HEK293T cells and in rodent neurons. Furthermore, neurons expressing T835M UNC5C are more susceptible to cell death from multiple neurotoxic stimuli, including β-amyloid (Aβ), glutamate and staurosporine. On the basis of these data and the enriched hippocampal expression of UNC5C in the adult nervous system, we propose that one possible mechanism in which T835M UNC5C contributes to the risk of Alzheimers disease is by increasing susceptibility to neuronal cell death, particularly in vulnerable regions of the Alzheimers disease brain.

Control of Emi2 activity and stability through Mos-mediated recruitment of PP2A.

Before fertilization, vertebrate eggs are arrested in meiosis II by cytostatic factor (CSF), which holds the anaphase-promoting complex (APC) in an inactive state. It was recently reported that Mos, an integral component of CSF, acts in part by promoting the Rsk-mediated phosphorylation of the APC inhibitor Emi2/Erp1. We report here that Rsk phosphorylation of Emi2 promotes its interaction with the protein phosphatase PP2A. Emi2 residues adjacent to the Rsk phosphorylation site were important for PP2A binding. An Emi2 mutant that retained Rsk phosphorylation but lacked PP2A binding could not be modulated by Mos. PP2A bound to Emi2 acted on two distinct clusters of sites phosphorylated by Cdc2, one responsible for modulating its stability during CSF arrest and one that controls binding to the APC. These findings provide a molecular mechanism for Mos action in promoting CSF arrest and also define an unusual mechanism, whereby protein phosphorylation recruits a phosphatase for dephosphorylation of distinct sites phosphorylated by another kinase.

TREM2, Microglia, and Neurodegenerative Diseases

Alzheimers disease (AD) is the most common form of dementia and the 6th leading cause of death in the US. The neuropathological hallmarks of the disease are extracellular amyloid-β (Aβ) plaques and intraneuronal hyperphosphorylated tau aggregates. Genetic variants of TREM2 (triggering receptor expressed on myeloid cells 2), a cell-surface receptor expressed selectively in myeloid cells, greatly increase the risk of AD, implicating microglia and the innate immune system as pivotal factors in AD pathogenesis. Recent studies have advanced our understanding of TREM2 biology and microglial activities in aging and neurodegenerative brains, providing new insights into TREM2 functions in amyloid plaque maintenance, microglial envelopment of plaque, microglia viability, and the identification of novel TREM2 ligands. Our increased understanding of TREM2 and microglia has opened new avenues for therapeutic intervention to delay or prevent the progression of AD.

Cdc2 and Mos Regulate Emi2 Stability to Promote the Meiosis I–Meiosis II Transition

The transition of oocytes from meiosis I (MI) to meiosis II (MII) requires partial cyclin B degradation to allow MI exit without S phase entry. Rapid reaccumulation of cyclin B allows direct progression into MII, producing a cytostatic factor (CSF)-arrested egg. It has been reported that dampened translation of the anaphase-promoting complex (APC) inhibitor Emi2 at MI allows partial APC activation and MI exit. We have detected active Emi2 translation at MI and show that Emi2 levels in MI are mainly controlled by regulated degradation. Emi2 degradation in MI depends not on Ca(2+)/calmodulin-dependent protein kinase II (CaMKII), but on Cdc2-mediated phosphorylation of multiple sites within Emi2. As in MII, this phosphorylation is antagonized by Mos-mediated recruitment of PP2A to Emi2. Higher Cdc2 kinase activity in MI than MII allows sufficient Emi2 phosphorylation to destabilize Emi2 in MI. At MI anaphase, APC-mediated degradation of cyclin B decreases Cdc2 activity, enabling Cdc2-mediated Emi2 phosphorylation to be successfully antagonized by Mos-mediated PP2A recruitment. These data suggest a model of APC autoinhibition mediated by stabilization of Emi2; Emi2 proteins accumulate at MI exit and inhibit APC activity sufficiently to prevent complete degradation of cyclin B, allowing MI exit while preventing interphase before MII entry.

Translational unmasking of Emi2 directs cytostatic factor arrest in meiosis II.

Cytostatic factor (CSF) arrests unfertilized vertebrate eggs in metaphase of meiosis II by inhibiting the anaphase-promoting complex/cyclosome (APC/C) from mediating cyclin destruction. The APC/C inhibitor Emi2/XErp1 satisfies a number of historical criteria for the molecular identification of CSF, but the mechanism by which CSF is activated selectively in meiosis II is the remaining unexplained criterion. Here we provide an explanation by showing that Emi2 is expressed specifically in meiosis II through translational de-repression or “unmasking” of its mRNA. We find that Emi2 protein is undetectable in immature, G2/prophase-arrested Xenopus oocytes and accumulates ~90 minutes after germinal vesicle breakdown. The 3’ untranslated region of Emi2 mRNA contains cytoplasmic polyadenylation elements that directly bind the CPEB protein and confer temporal regulation of Emi2 polyadenylation and translation. Our results demonstrate that cytoplasmic polyadenylation and translational unmasking of Emi2 directs meiosis II-specific CSF arrest.

Control of the centriole and centrosome cycles by ubiquitination enzymes.

The role of the centriole in organizing the cell’s cytoskeleton and its mechanism of duplication have been long-standing puzzles for cell biologists. Whereas the semi-conservative replication of chromosomes was established by Meselson and Stahl (1958), the likely parallels for semi-conservative duplication of the centrioles remain fuzzy. Further considering this parallel, molecular studies of chromosomal replication have begun to uncover how cell cycle regulators including cyclin-dependent kinases and ubiquitin ligases ensure that chromosomes replicate once-and-only-once per cell cycle (Blow and Hodgson, 2002; Dutta and Bell, 1997). The obvious need to maintain accurate control of centrosome number and thereby ensure spindle bipolarity would suggest that a similar once-and-only once control restricts the centrosome cycle. Studies over the last decade on the budding and fission yeast spindle pole bodies (SPB) and the animal cell centrosome have defined a growing parts list of conserved components, as well as those specific to fungi or animals. The functional connection between the centrosome duplication cycle and the regulatory mechanisms controlling the chromosome duplication cycle suggested that semi-conservative replication for both centrosomes and chromosomes might be linked by these global timing mechanisms. In 1999, a series of studies demonstrated that cyclin-dependent kinases and both the SCF and APC ubiquitin ligases – cell cycle regulators already well established in control of the chromosome replication cycle – also had fundamental roles in controlling the centrosome cycle (Freed et al., 1999; Hinchcliffe et al., 1999; Lacey et al., 1999; Meraldi et al., 1999; Vidwans et al., 1999). Since then, a number of other cell cycle regulators have been directly implicated in the centrosome cycle, many of which are described in the accompanying reviews. Here we will focus on the role of ubiquitin ligases in controlling the centrosome cycle, considering both those known or postulated core centrosomal factors that are directly ubiquitinated, as well as ubiquitination of specific cell cycle regulators – including kinases and ubiquitin ligases themselves – that more globally control the centrosome cycle. First, we will review the biochemistry of ubiquitin ligases, and then return to the role of these enzymes in the various phases of the centrosome cycle.

Microglia in Alzheimer’s disease

Proliferation and activation of microglia in the brain, concentrated around amyloid plaques, is a prominent feature of Alzheimer’s disease (AD). Human genetics data point to a key role for microglia in the pathogenesis of AD. The majority of risk genes for AD are highly expressed (and many are selectively expressed) by microglia in the brain. There is mounting evidence that microglia protect against the incidence of AD, as impaired microglial activities and altered microglial responses to &bgr;-amyloid are associated with increased AD risk. On the other hand, there is also abundant evidence that activated microglia can be harmful to neurons. Microglia can mediate synapse loss by engulfment of synapses, likely via a complement-dependent mechanism; they can also exacerbate tau pathology and secrete inflammatory factors that can injure neurons directly or via activation of neurotoxic astrocytes. Gene expression profiles indicate multiple states of microglial activation in neurodegenerative disease settings, which might explain the disparate roles of microglia in the development and progression of AD pathology.

Emi2 at the crossroads: where CSF meets MPF.

Vertebrate eggs arrest at metaphase of meiosis II due to an activity known as cytostatic factor (CSF). CSF antagonizes the ubiquitin ligase activity of the anaphase-promoting complex/cyclosome (APC/C), preventing cyclin B destruction and meiotic exit until fertilization occurs. A puzzling feature of CSF arrest is that APC/C inhibition is leaky. Ongoing cyclin B synthesis is counterbalanced by a limited amount of APC/C-mediated cyclin B destruction; thus, cyclin B/Cdc2 activity remains at steady state. How the APC/C can be slightly active toward cyclin B, and yet restrained from ubiquitinating cyclin B altogether, is unknown. Emi2/XErp1 is the critical CSF component directly responsible for APC/C inhibition during CSF arrest. Fertilization triggers the Ca2+-dependent destruction of Emi2, releasing the APC/C to ubiquitinate the full pool of cyclin B and initiate completion of meiosis. Previously, we showed that a phosphatase maintains Emi2’s APC/C-inhibitory activity in CSF-arrested Xenopus egg extracts. Here, we demonstrate that phosphatase inhibition permits Emi2 phosphorylation at thr-545 and -551, which inactivates Emi2. Furthermore, we provide evidence that adding excess cyclin B to CSF extracts stimulates Cdc2 phosphorylation of these same residues, antagonizing Emi2-APC/C association. Our findings suggest a model wherein the pool of Emi2 acts analogously to a rheostat by integrating Cdc2 and phosphatase activities to prevent cyclin B overaccumulation and Cdc2 hyperactivity during the indefinite period of time between arrival at metaphase II and eventual fertilization. Finally, we propose that inactivation of Emi2 by Cdc2 permits mitotic progression during early embryonic cleavage cycles.