Changes in the Nuclear Envelope Environment Affect Spindle Pole Body Duplication in Saccharomyces cerevisiae

The Saccharomyces cerevisiae nuclear membrane is part of a complex nuclear envelope environment also containing chromatin, integral and peripheral membrane proteins, and large structures such as nuclear pore complexes (NPCs) and the spindle pole body. To study how properties of the nuclear membrane affect nuclear envelope processes, we altered the nuclear membrane by deleting the SPO7 gene. We found that spo7Δ cells were sickened by the mutation of genes coding for spindle pole body components and that spo7Δ was synthetically lethal with mutations in the SUN domain gene MPS3. Mps3p is required for spindle pole body duplication and for a variety of other nuclear envelope processes. In spo7Δ cells, the spindle pole body defect of mps3 mutants was exacerbated, suggesting that nuclear membrane composition affects spindle pole body function. The synthetic lethality between spo7Δ and mps3 mutants was suppressed by deletion of specific nucleoporin genes. In fact, these gene deletions bypassed the requirement for Mps3p entirely, suggesting that under certain conditions spindle pole body duplication can occur via an Mps3p-independent pathway. These data point to an antagonistic relationship between nuclear pore complexes and the spindle pole body. We propose a model whereby nuclear pore complexes either compete with the spindle pole body for insertion into the nuclear membrane or affect spindle pole body duplication by altering the nuclear envelope environment.THE nuclear envelope is composed of distinct outer and inner nuclear membranes. The outer nuclear membrane is continuous with the endoplasmic reticulum. The inner nuclear membrane is associated with a unique set of proteins, some of which mediate interactions between the nuclear envelope and chromatin (reviewed in Zhao et al. 2009). Nuclear pore complexes traverse both membranes and allow transport of proteins and solutes between the cytoplasm and the nucleus. The inner and outer nuclear membranes fuse in the region surrounding each nuclear pore complex.In animal cells, the nuclear envelope disassembles as cells enter mitosis and reassembles upon mitotic exit. Nuclear envelope breakdown allows the association of chromosomes with spindle microtubules, which are nucleated from centrosomes that reside in the cytoplasm. In contrast, certain types of fungi, such as the budding yeast Saccharomyces cerevisiae, undergo closed mitosis, where the nuclear envelope remains intact throughout the entire cell cycle. Closed mitosis is possible because the yeast centrosome-equivalent, the spindle pole body (SPB), is embedded in the nuclear envelope, allowing the SPB to nucleate both cytoplasmic and nuclear microtubules.SPB duplication requires a mechanism for inserting the new SPB into the nuclear envelope (reviewed in Jaspersen and Winey 2004). The new SPB begins to form in late G₁/early S phase as satellite material deposited on the cytoplasmic face of an electron-dense region of the nuclear envelope, called the half-bridge. The satellite material matures into a duplication plaque, which is then inserted into the nuclear membrane and becomes the daughter SPB. Many genes are known to be required for SPB duplication, and this process has been carefully examined cytologically (Rose and Fink 1987; Winey et al. 1991, 1993; Spang et al. 1995; Bullitt et al. 1997; Adams and Kilmartin 1999; Elliott et al. 1999; Schramm et al. 2000; Jaspersen et al. 2002; Nishikawa et al. 2003; Araki et al. 2006). However, the exact mechanisms by which SPB duplication and insertion occur remain a mystery.Equally unclear is how nuclear pore complexes are inserted into an intact nuclear envelope (reviewed in Hetzer and Wente 2009). For both the SPB and nuclear pore complexes, the inner and outer nuclear membranes must fuse to allow insertion into the nuclear envelope. Yeast and vertebrate nuclear pore complexes each have four pore membrane (POM) nucleoporins containing transmembrane domains. Other nucleoporins have motifs with potential for bending membranes or sensing membrane curvature. Thus, certain nuclear pore complex components may have the ability to alter the nuclear membrane or stabilize particular membrane conformations (Devos et al. 2004, 2006; Alber et al. 2007; Drin et al. 2007). It is interesting to note that, in S. cerevisiae, nuclear pore complexes are enriched in the vicinity of the SPB (Heath et al. 1995; Winey et al. 1997; Adams and Kilmartin 1999), but the significance of this phenomenon is not known. The SPB and nuclear pore complexes share at least two common components, the integral membrane protein Ndc1p and the small calcium-binding protein Cdc31p (Chial et al. 1998; Fischer et al. 2004). Ndc1p is thought to play a role in insertion of both SPBs and nuclear pore complexes into the nuclear membrane.SUN domain proteins are a conserved family of inner nuclear membrane proteins that interact with specific outer nuclear membrane proteins to form a physical bridge across the nuclear envelope (reviewed in Hiraoka and Dernburg 2009; Razafsky and Hodzic 2009). One of the components of the S. cerevisiae SPB is the SUN domain protein Mps3p. The N terminus of Mps3p is in the nucleoplasm, while the C terminus, containing the SUN domain, is found in the space between the inner and outer nuclear membranes. In addition to the SPB, Mps3p localizes to multiple foci at the nuclear periphery, and these two pools of Mps3p have distinct functions (Jaspersen et al. 2002, 2006; Nishikawa et al. 2003). At the SPB, Mps3p is required for half-bridge formation and early steps of SPB duplication, and cells compromised for Mps3p function accumulate in mitosis with a single SPB and a monopolar spindle (Jaspersen et al. 2002; Nishikawa et al. 2003). At the nuclear periphery, Mps3p is involved in tethering telomeres to the nuclear envelope in mitosis and meiosis, sequestering DNA double-strand breaks away from recombination factors, and associating with soluble chromatin proteins (Antoniacci et al. 2004, 2007; Bupp et al. 2007; Conrad et al. 2007, 2008; Oza et al. 2009; Schober et al. 2009).While many structural features of the yeast nucleus have been identified, little is known about how the physical properties of the nuclear membrane contribute to processes that occur at the nuclear envelope. As noted above, resident proteins of the nuclear envelope may affect nuclear membrane properties. In addition, the nuclear membrane is affected by altering lipid biosynthesis, for example, by inactivating the phosphatidic acid (PA) phosphohydrolase Pah1p or by inactivating the phosphates complex, made of Spo7p and Nem1p, which activates Pah1p. In the absence of Spo7p, Nem1p, or Pah1p, cells exhibit nuclear envelope extensions and extensive ER membrane sheets, and they also have altered membrane lipid composition, including a decrease in phosphatidylcholine and an increase in PA, phosphatidylethanolamine, and phosphatidylinositol (Siniossoglou et al. 1998; Santos-Rosa et al. 2005; Campbell et al. 2006; Han et al. 2006). These three proteins are unique among phospholipid biosynthesis proteins in their ability to affect nuclear morphology upon gene disruption (Han et al. 2008). A similar phenotype was seen upon overexpression of DGK1, which counteracts the activity of Pah1p by converting diacylglycerol to PA, leading to an increase in PA levels at the nuclear envelope (Han et al. 2008). Consistent with a conserved role for Pah1p in regulating nuclear envelope processes, deletion of either NEM1 or SPO7 is synthetically lethal with deletions of certain nucleoporin genes (Siniossoglou et al. 1998), and inactivation of the PAH1 homolog in Caenorhabditis elegans, LPIN-1, results in defects in nuclear envelope disassembly and reassembly (Golden et al. 2009; Gorjanacz and Mattaj 2009).To identify processes that are affected by altered nuclear membrane properties, we screened for pathways that are compromised in spo7Δ cells. We found that SPO7 inactivation strongly influences the SPB. By screening for proteins that could alleviate spo7Δ-induced SPB defects, we uncovered an unexpected inhibitory role for nucleoporins in SPB function, revealing that nuclear pore complexes, or components thereof, act antagonistically to the SPB in the nuclear envelope. Taken together, our findings indicate that the nuclear envelope environment is important for the function of protein complexes and biological processes occurring at the nuclear periphery.     

In ovo exposure to monochromatic green light promotes skeletal muscle cell proliferation and affects myofiber growth in posthatch chicks

Our previous studies demonstrated that illumination of chicken embryos with monochromatic green light results in enhanced body and muscle weight at later posthatch stages. In the present study, we investigated the cellular and molecular basis of this phenomenon. First, we showed that on day 6 posthatch, myofibers were more uniform in the in ovo illuminated group than in the control group incubated in the dark, with respect to the number of myofibers displaying diameter values within the range of the mean value. Second, we tested the hypothesis that in ovo illumination causes an increase in the number of myoblasts; this in turn can promote posthatch muscle growth. Indeed, a significant increase in the number of skeletal muscle cells isolated from pectoralis muscle was observed in the in ovo illuminated group on days 1 and 3 posthatch relative to the control group. This increased cell number was accompanied by higher expression levels of Pax7 and myogenin proteins on posthatch days 1 and 3, respectively. A parallel analysis of proliferating cells in the intact muscle further demonstrated a significant increase in the number of cells positive for proliferating cell nuclear antigen in muscle from the in ovo illuminated group. Third, we demonstrated that the transition from fetal- to adult-type myoblasts, normally occurring in late stages of chicken embryogenesis, is initiated earlier in embryos subjected to in ovo green-light illumination. We suggest that the stimulatory effect of in ovo illumination on posthatch muscle growth is the result of enhanced proliferation and differentiation of adult myoblasts and myofiber synchronization.     

Yeast nuclear envelope subdomains with distinct abilities to resist membrane expansion

Little is known about what dictates the round shape of the yeast Saccharomyces cerevisiae nucleus. In spo7Delta mutants, the nucleus is misshapen, exhibiting a single protrusion. The Spo7 protein is part of a phosphatase complex that represses phospholipid biosynthesis. Here, we report that the nuclear protrusion of spo7Delta mutants colocalizes with the nucleolus, whereas the nuclear compartment containing the bulk of the DNA is unaffected. Using strains in which the nucleolus is not intimately associated with the nuclear envelope, we show that the single nuclear protrusion of spo7Delta mutants is not a result of nucleolar expansion, but rather a property of the nuclear membrane. We found that in spo7Delta mutants the peripheral endoplasmic reticulum (ER) membrane was also expanded. Because the nuclear membrane and the ER are contiguous, this finding indicates that in spo7Delta mutants all ER membranes, with the exception of the membrane surrounding the bulk of the DNA, undergo expansion. Our results suggest that the nuclear envelope has distinct domains that differ in their ability to resist membrane expansion in response to increased phospholipid biosynthesis. We further propose that in budding yeast there is a mechanism, or structure, that restricts nuclear membrane expansion around the bulk of the DNA.     

Shaping the nucleus: factors and forces

Take a look at a textbook illustration of a cell and you will immediately be able to locate the nucleus, which is often drawn as a spherical or ovoid shaped structure. But not all cells have such nuclei. In fact, some disease states are diagnosed by the presence of nuclei that have an abnormal shape or size. What defines nuclear shape and nuclear size, and how does nuclear geometry affect nuclear function? While the answer to the latter question remains largely unknown, significant progress has been made towards understanding the former. In this review, we provide an overview of the factors and forces that affect nuclear shape and size, discuss the relationship between ER structure and nuclear morphology, and speculate on the possible connection between nuclear size and its shape. We also note the many interesting questions that remain to be explored. J. Cell. Biochem. 113: 2813–2821, 2012. © 2012 Wiley Periodicals, Inc.     

Poor Cerebral Inflammatory Response in eIF2B Knock-In Mice: Implications for the Aetiology of Vanishing White Matter Disease

Background

Mutations in any of the five subunits of eukaryotic translation initiation factor 2B (eIF2B) can lead to an inherited chronic-progressive fatal brain disease of unknown aetiology termed leucoencephalopathy with vanishing white matter (VWM). VWM is one of the most prevalent childhood white matter disorders, which markedly deteriorates after inflammation or exposure to other stressors. eIF2B is a major housekeeping complex that governs the rate of global protein synthesis under normal and stress conditions. A previous study demonstrated that Eif2b5^R132H/R132H mice suffer delayed white matter development and fail to recover from cuprizone-induced demyelination, although eIF2B enzymatic activity in the mutant brain is reduced by merely 20%.

Principal Findings

Poor astrogliosis was observed in Eif2b5^R132H/R132H mice brain in response to systemic stress induced by peripheral injections of lipopolysaccharide (LPS). Even with normal rates of protein synthesis under normal conditions, primary astrocytes and microglia isolated from mutant brains fail to adequately synthesise and secrete cytokines in response to LPS treatment despite proper induction of cytokine mRNAs.

Conclusions

The mild reduction in eIF2B activity prevents the appropriate increase in translation rates upon exposure to the inflammatory stressor LPS. The data underscore the importance of fully-functional translation machinery for efficient cerebral inflammatory response upon insults. It highlights the magnitude of proficient translation rates in restoration of brain homeostasis via microglia-astrocyte crosstalk. This study is the first to suggest the involvement of microglia in the pathology of VWM disease. Importantly, it rationalises the deterioration of clinical symptoms upon exposure of VWM patients to physiological stressors and provides possible explanation for their high phenotypic variability.     

In vivo acetylation of CheY, a response regulator in chemotaxis of Escherichia coli

CheY, the excitatory response regulator in the chemotaxis system of Escherichia coli, can be modulated by two covalent modifications: phosphorylation and acetylation. Both modifications have been detected in vitro only. The role of CheY acetylation is still obscure, although it is known to be involved in chemotaxis and to occur in vitro by two mechanisms—acetyl-CoA synthetase-catalyzed transfer of acetyl groups from acetate to CheY and autocatalyzed transfer from AcCoA. Here, we succeeded in detecting CheY acetylation in vivo by three means—Western blotting with a specific anti-acetyl-lysine antibody, mass spectrometry, and radiolabeling with [¹⁴C]acetate in the presence of protein-synthesis inhibitor. Unexpectedly, the level and rate of CheY acetylation in vivo were much higher than that in vitro. Thus, before any treatment, 9-13% of the lysine residues were found acetylated, depending on the growth phase, meaning that, on average, essentially every CheY molecule was acetylated in vivo. This high level was mainly the outcome of autoacetylation. Addition of acetate caused an incremental increase in the acetylation level, in which acetyl-CoA synthetase was involved too. These findings may have far-reaching implications for the structure-function relationship of CheY.     

A Point Mutation in Translation Initiation Factor 2B Leads to a Continuous Hyper Stress State in Oligodendroglial-Derived Cells

Background

Mutations in eukaryotic translation initiation factor 2B (eIF2B) cause Childhood Ataxia with CNS Hypomyelination (CACH), also known as Vanishing White Matter disease (VWM). The disease is manifested by loss of brain myelin upon physiological stress. In a previous study, we showed that fibroblasts isolated from CACH/VWM patients are hypersensitive to pharmacologically-induced endoplasmic reticulum (ER) stress. Since brain cells from affected individuals are not available for research, we wished to assess the effect of eIF2B mutation on oligodendroglial-derived cells.

Methodology/Principal Findings

A rat oligodendroglial-derived cell line was used for a stable knock-down of eIF2B5 followed by stable expression of mutated eIF2B5(R195H) cDNA. In response to a pharmacological ER-stress agent, eIF2B5(R195H) expressing cells exhibited heightened ER-stress response demonstrated by hyper induction of ATF4, GADD34, Bip, PDIA1, PDIA3, PDIA4 and PDIA6 proteins. Moreover, even in the absence of a pharmacological stress agent, eIF2B5(R195H)-expressing cells exhibited high basal levels of ATF4, GADD34 and ER-associated Bip, PDIA1 and PDIA3.

Significance

The data provide evidence that oligodendroglial-derived cells expressing a mutated eIF2B constantly use their stress response mechanism as an adaptation mean in order to survive. The current study is the first to demonstrate the effects of eIF2B5 mutation on ER homeostasis in oligodendroglial-derived cells.     

Functional resolution of fibrosis in mdx mouse dystrophic heart and skeletal muscle by halofuginone

The effect of halofuginone (Halo) on established fibrosis in older mdx dystrophic muscle was investigated. Mice (8 to 9 mo) treated with Halo (or saline in controls) for 5, 10, or 12 wk were assessed weekly for grip strength and voluntary running. Echocardiography was performed at 0, 5, and 10 wk. Respiratory function and exercise-induced muscle damage were tested. Heart, quadriceps, diaphragm, and tibialis anterior muscles were collected to study fibrosis, collagen I and III expression, collagen content using a novel collagenase-digestion method, and cell proliferation. Hepatocyte growth factor and alpha-smooth muscle actin proteins were assayed in quadriceps. Halo decreased fibrosis (diaphragm and quadriceps), collagen I and III expression, collagen protein, and smooth muscle actin content after 10 wk treatment. Muscle-cell proliferation increased at 5 wk, and hepatocyte growth factor increased by 10 wk treatment. Halo markedly improved both cardiac and respiratory function and reduced damage and improved recovery from exercise. The overall impact of established dystrophy and dysfunction in cardiac and skeletal muscles was reduced by Halo treatment. Marked improvements in vital-organ functions implicate Halo as a strong candidate drug to reduce morbidity and mortality in Duchenne muscular dystrophy.     

Circadian Rhythms in 6-Sulphatoxymelatonin and Nocturnal Sleep in Blind Children

This article describes the relationship between melatonin secretion and sleep quality and subjective complaints about sleep in totally blind children. Eleven boarding-school children (mean age 15.2 years) participated. The major urinary melatonin metabolite 6-sulphatoxymelatonin (aMT6s) was measured five times a day for 48 h. Sleep-wake cycles were recorded by continuous actigraphic recordings during the same time period. Results showed that delayed secretory peaks in aMT6s were significantly associated with disturbed nocturnal sleep and with complaints about morning fatigue.