Correction: Investigation of common, low-frequency and rare genome-wide variation in anorexia nervosa.

The fortieth author's name was listed incorrectly. The correct presentation is A Keski-Rahkonen.

Investigation of common, low-frequency and rare genome-wide variation in anorexia nervosa.

Anorexia nervosa (AN) is a complex neuropsychiatric disorder presenting with dangerously low body weight, and a deep and persistent fear of gaining weight. To date, only one genome-wide significant locus associated with AN has been identified. We performed an exome-chip based genome-wide association studies (GWAS) in 2158 cases from nine populations of European origin and 15 485 ancestrally matched controls. Unlike previous studies, this GWAS also probed association in low-frequency and rare variants. Sixteen independent variants were taken forward for in silico and de novo replication (11 common and 5 rare). No findings reached genome-wide significance. Two notable common variants were identified: rs10791286, an intronic variant in OPCML (P=9.89 × 10-6), and rs7700147, an intergenic variant (P=2.93 × 10-5). No low-frequency variant associations were identified at genome-wide significance, although the study was well-powered to detect low-frequency variants with large effect sizes, suggesting that there may be no AN loci in this genomic search space with large effect sizes.

Characterization of novel benzodiazepine ligands in Spodotera frugiperda (Sf-9) insect cells.

The goals of the present work were to characterize the binding profile of nine benzodiazepine ligands in Spodotera frugiperda (Sf-9) insect cells expressing specific gamma aminobutyric acid (A) (GABA(A)) receptor subunit combinations and compare the affinities to those for the receptors in the rat cerebellum. Three recombinant baculovirus constructs, each harboring a different GABA(A) receptor subunit, were introduced into insect cells by simultaneous infection. Saturation and competition binding assays were carried out in membranes from Sf-9 cells infected with either alpha1beta2gamma2 or alpha6beta2gamma2 subunit combinations. The affinities of the ligands to the alpha1beta2gamma2 or alpha6beta2gamma2 receptors expressed in Sf-9 cells were similar to the affinities previously determined for the alpha1 or alpha6 subunit-containing GABA(A) receptors in the rat cerebellum, respectively, thus confirming the previously assigned receptor types in the cerebellum.

Antibody labelling and flow cytometric analysis of metaphase chromosomes reveals two discrete structural forms.

Metaphase chromosomes from cultured Chinese Hamster Ovary cells were labelled in suspension with a monoclonal antibody to histone 2B, counterstained with propidium iodide (PI) and analysed by flow cytometry. Contour plots of antibody binding (FITC fluorescence) against DNA content (PI fluorescence) revealed two discrete forms of each individual chromosome, showing high and low levels of antibody binding respectively. The two types of chromosome were easily distinguishable by immunofluorescence microscopy. The distribution of individual chromosomes between the two populations was related to chromosome size, with larger chromosomes predominating in the low-labelling population and vice versa. Variations in ionic strength, pH, divalent cation concentration or preparation procedure influenced the absolute level of antibody binding but did not eliminate the two populations. In contrast, preincubation with intercalating dyes, such as ethidium and propidium, inhibited antibody binding and generated a single, low-labelling population. Preliminary evidence suggests that in vivo changes in chromosome structure can affect the distribution of chromosomes between the two populations. Prolonged exposure of cells to Colcemid prior to chromosome isolation, a procedure known to increase chromosome condensation, resulted in a progressive shift into the low-labelling population. Our results suggest that chromosomes undergo a relatively rapid transition from the high-labelling to the low-labelling form during the prometaphase-metaphase stage of mitosis. The timing of this transition appears to be size dependent, with the larger chromosomes preceding the smaller. The transition may represent a change in chromosome condensation.

Differential underacetylation of histones H2A, H3 and H4 on the inactive X chromosome in human female cells.

It has previously been shown that the acetylated forms of histone H4 are depleted or absent in both constitutive, centric heterochromatin and in the facultative heterochromatin of the inactive X chromosome (Xi) in female cells. By immunostaining of metaphase chromosomes from human lymphocytes with antibodies to the acetylated isoforms of histones H2A and H3, we now show that these histones too are underacetylated in both Xi and centric heterochromatin. Xi shows two prominent regions of residual H3 acetylation, one encompassing the pseudoautosomal region at the end of the short arm and one at about Xq22. Both these regions have been shown previously to be sites of residual H4 acetylation. H2A acetylation on Xi is higher overall than that of H3 or H4 and is particularly high around the pseudoautosomal region, but not at Xq22. The results suggest that the acetylated isoforms of H3 and H4 have at least some effects on chromosomal structure and function that are not shared by acetylated H2A.

Histone H4 acetylation and replication timing in Chinese hamster chromosomes.

The distribution of acetylated isoforms of histone H4 along Chinese hamster chromosomes has been studied by immunostaining with antibodies recognizing H4 acetylated at defined lysines in its N-terminal domain. The heterochromatic long arm of the X chromosome in both female (CHO) and male (DON) cell lines is underacetylated at three out of four lysines (5, 8, and 12). In contrast, the level of acetylation at lysine 16, which is the first to be acetylated in mammals, was similar in X chromosomes and autosomes. Labeling of the cells with bromodeoxyuridine (BrdU) to mark late-replicating chromosome domains, followed by double immunostaining with antibodies to BrdU and acetylated H4, showed a close, though not perfect, correlation between late replication and low levels of H4 acetylation. The results show that levels of histone acetylation are associated with the replication timing of defined domains on both the X chromosome and autosomes, but the exceptions we observe suggest that this link is not absolute or essential.

Different strategies of X-inactivation in germinal and somatic cells: histone H4 underacetylation does not mark the inactive X chromosome in the mouse male germline.

It has previously been shown by immunocytochemistry that the inactive X chromosome (Xi) in somatic cells of human and mouse females is marked by underacetylation of histone H4. It has been suggested that this may be important for transcriptional silencing of genes on Xi. We have now investigated X-inactivation in meiotic cells of the male germline. In these cells the single X chromosome is transcriptionally inactive and expresses XIST, a gene that in somatic cells is transcribed only from Xi. By immunostaining with antibodies to H4 acetylated at lysines 5, 8, 12, or 16, we demonstrate that histone H4 on the male X is not underacetylated. We conclude that there is a differential germline strategy for maintenance of X-inactivation and that H4 underacetylation, though associated with the long-term marking of inactive X chromosomes in the female soma, is not always essential for the transcriptional down-regulation of X-linked genes.

Histone underacetylation is an ancient component of mammalian X chromosome inactivation.

Underacetylation of histone H4 is thought to be involved in the molecular mechanism of mammalian X chromosome inactivation, which is an important model system for large-scale genetic control in eukaryotes. However, it has not been established whether histone underacetylation plays a critical role in the multistep inactivation pathway. Here we demonstrate differential histone H4 acetylation between the X chromosomes of a female marsupial, Macropus eugenii. Histone underacetylation is the only molecular aspect of X inactivation known to be shared by marsupial and eutherian mammals. Its strong evolutionary conservation implies that, unlike DNA methylation, histone underacetylation was a feature of dosage compensation in a common mammalian ancestor, and is therefore likely to play a central role in X chromosome inactivation in all mammals.

Histone acetylation and X inactivation.

In mammals, the levels of X-linked gene products in males and females are equalised by the silencing, early in development, of most of the genes on one of the two female X chromosomes. Once established, the silent state is stable from one cell generation to the next. In eutherian mammals, the inactive X chromosome (Xi) differs from its active homologue (Xa) in a number of ways, including increased methylation of selected CpGs, replication late in S-phase, expression of the Xist gene with binding of Xist RNA and underacetylation of core histones. The latter is a common property of genetically inactive chromatin but, in the case of Xi, it is not clear whether it is an integral part of the silencing process or simply a consequence of some other property of Xi, such as late replication. The present review describes two approaches that address this problem. The first shows that Xi in marsupial mammals also contains underacetylated H4, even though its properties differ widely from those of the eutherian Xi. The continued presence of histone underacetylation on Xi in these evolutionarily distant mammals argues for its fundamental importance. The second approach uses mouse embryonic stem cells and places H4 deacetylation in a sequence of events leading to complete X inactivation. The results argue that histone underacetylation plays a role in the stabilisation of the inactive state, rather than in its initiation.

H4 acetylation, XIST RNA and replication timing are coincident and define x;autosome boundaries in two abnormal X chromosomes.

The inactive X (Xi) differs from its active homologue (Xa) in a number of ways, including increased methylation of CpG islands, replication late in S phase, underacetylation of histone H4 and association with XIST RNA. Global changes in DNA methylation occur relatively late in development, but the other properties all change during or shortly after the establishment of Xi and may play a role in the mechanism by which an inactive chromatin conformation spreads across most of the chromosome. In the present report, we use two human X;autosome translocation chromosomes to study the spreading of inactive X chromatin across X;autosome boundaries. In one of these chromosomes, t(X;6), Xp distal to p11.2 is replaced by 6p21.1-6pter and, in the other, ins(X;16), a small fragment derived from 16p13 is inserted into the distal third of Xq. In lymphoid cells from patients carrying these translocations in an unbalanced form, Xi was shown by HUMARA assay to be derived exclusively [t(X:6)] or predominantly [ins (X;16)] from the derived X chromosome. We used a combination of immunolabelling and RNA/DNA fluorescence in situ hybridization to define the distribution of XIST RNA, deacetylated H4 and late-replicating DNA across the two derived X chromosomes in inactive form. Within the limits of the cytogenetic techniques employed, the results show complete coincidence of these three parameters, with all three being excluded from the autosomal component of the derived X chromosome.

The effects of three bioreductive drugs (mitomycin C, RSU-1069 and SR4233) on cell lines selected for their sensitivity to mitomycin C or ionising radiation.

We have investigated the cross-sensitivity of a number of cell lines to three different classes of bioreductive drugs under both aerobic and hypoxic conditions. The cell lines used were selected for their sensitivity to DNA-damaging agents and fall into two groups. One group, MMC cells derived from CHO-K1 cells (Robson et al., 1985), show a range of sensitivities to mitomycin C in air. The second group, irs cells were cloned from V79 Chinese hamster fibroblasts (Jones et al., 1987) and exhibit sensitivity to ionising radiation. The sensitivity of both groups of cells to mitomycin C (MMC), RSU-1069 and SR4233 was assessed under aerobic and hypoxic conditions. No difference in aerobic or hypoxic toxicity of MMC was observed for CHO-K1 or MMC sensitive cell lines (MMC-2 and MMC-3). However, the MMC-resistant cell line (MMCr) was 10 times more sensitive under hypoxic than aerobic conditions. This suggests that MMCr cells lack or are deficient in the enzymes responsible for activating MMC under aerobic conditions compared to other MMC cells. In contrast, differential toxicities of between 3 and 30 have been observed for all CHO cells treated with RSU-1069 and SR4233. Treatment of V79 and irs cells with RSU-1069 and SR4233 also resulted in selective toxicity towards hypoxic cells. Differential toxicities between 50 and 100 were observed for V79 cells. For both RSU-1069 and SR4233, the hypoxic toxicities were similar in V79 and irs cells but in air, the radiation sensitive cells were up to 10 times more sensitive than wild type cells.

X-Inactivation and histone H4 acetylation in embryonic stem cells.

In female mammalian cells, dosage compensation for X-linked genes is achieved by the transcriptional silencing, early in development, of many genes on just one of the two X chromosomes. Several properties distinguish the inactive X (Xi) from its active counterpart (Xa). These include expression of Xist, a gene located in the X-inactivation center (Xic), late replication, differential methylation of selected CpG islands and underacetylation of histone H4. The relationship between these properties and transcriptional silencing remains unclear. Female mouse embryonic stem (ES) cells have two active X chromosomes, one of which is inactivated as cells differentiate in culture. We describe here the use of these cells in studying the sequence of events leading to X-inactivation. By immunofluorescent labeling of metaphase chromosome spreads from ES cells with antibodies to acetylated H4, we show that an underacetylated X chromosome appears only after 4 days of differentiation, and only in female cells. The frequency of cells with an underacetylated X reaches a maximum by Day 6. In undifferentiated cells, H4 in centric heterochromatin is acetylated to the same extent as that in euchromatin but has become relatively underacetylated, as in adult cells, by Day 4 of differentiation (i.e. , when deacetylation of Xi is first seen). The overall deacetylation of Xi follows Xist expression and the first appearance of a single, late-replicating X, both of which occur on Day 2. It also follows the silencing of X-linked genes. Levels of mRNA from four such genes, Hprt, G6pd, Rps4, and Pgk-1, had all fallen by approximately 50% (relative to the autosomal gene Aprt) by Days 2-4. The results show that properties that characterize Xi are put in place in a set order over several days. H4 deacetylation occupies a defined place within this sequence, suggesting that it is an intrinsic part of the X-inactivation process. The stage at which a completely deacetylated Xi is first seen suggests that deacetylation may be necessary for the maintenance of silencing but is not required for its initiation. Nor is it required for, or an immediate consequence of, late replication. However, we note that selective deacetylation of H4 on specific genes would not be detected by the microscopical approach we have used and that such selective deacetylation may still be part of the silencing process.

Aziridinyl nitropyrroles and nitropyrazoles as hypoxia-selective cytotoxins and radiosensitizers.

A series of 1- and 2-substituted 4- and 5-nitropyrroles and 3- and 4-nitropyrazoles has been prepared and evaluated in vitro as radiosensitizers of hypoxic cells and as bioreductively-activated cytotoxins. Both the nitropyrroles and the nitropyrazoles were considerably less effective, based upon the differential between hypoxic and aerobic toxicity, than were similar 2-nitroimidazoles bearing alkylating moieties. The trends in radiosensitizing efficiency observed for both classes of drugs corresponded with their one-electron reduction potentials (E1(7] as measured by pulse radiolysis, although they were generally more effective than predicted from previous correlations of E1(7] with sensitizing efficacy and reactivities. Furthermore, the enhancement of sensitizing efficiency by the incorporation of alkylating groups is considerably greater than has been observed for nitroimidazoles. alpha-[(1-Aziridinyl)methyl]-3-nitropyrazole- 1-ethanol (10, E1(7) = -456 mV) and methyl 5-nitro-1-(cyclopropylcarbonyl)pyrrole-2-carboxylate (25, E1(7) = -326 mV) were the most effective radiosensitizers in vitro. Only 3-[cis-2,3-dimethyl-1-aziridinyl) methyl)-1-oxo-3,4-dihydro-6-nitro-1-H-pyrrolo [2,1-c] oxazine (22) and methyl 5-nitro-1-(cyclopropylcarbonyl)pyrrole-2-carboxylate (25) showed significant bioreductively-activated cytotoxicity, with differentials of 3.5. Although these differential toxicities were coupled with significantly lower aerobic toxicity compared with similar 2-nitroimidazoles, this series was not deemed effective enough to warrant further evaluation. The electron affinity and radiosensitization could be manipulated by chemical design but hypoxia-selectivity was not clearly related to these properties.

Xist RNA exhibits a banded localization on the inactive X chromosome and is excluded from autosomal material in cis.

The propagation of X chromosome inactivation is thought to be mediated by the cis- limited spreading of the non-protein coding Xist transcript. In this report we have investigated the localization of Xist RNA on rodent metaphase chromosomes. We show that Xist RNA exhibits a banded pattern on the inactive X and is excluded from regions of constitutive heterochromatin. The banding pattern suggests a preferential association with gene-rich, G-light regions. Analysis of X:autosome rearrangements revealed that restricted propagation of X inactivation into cis -linked autosomal material is reflected by a corresponding limited spread of Xist RNA. We discuss these results in the context of models for the function of Xist RNA in the propagation of X inactivation.

A developmental switch in H4 acetylation upstream of Xist plays a role in X chromosome inactivation.

We have investigated the role of histone acetylation in X chromosome inactivation, focusing on its possible involvement in the regulation of Xist, an essential gene expressed only from the inactive X (Xi). We have identified a region of H4 hyperacetylation extending up to 120 kb upstream from the Xist somatic promoter P1. This domain includes the promoter P0, which gives rise to the unstable Xist transcript in undifferentiated cells. The hyperacetylated domain was not seen in male cells or in female XT67E1 cells, a mutant cell line heterozygous for a partially deleted Xist allele and in which an increased number of cells fail to undergo X inactivation. The hyperacetylation upstream of Xist was lost by day 7 of differentiation, when X inactivation was essentially complete. Wild-type cells differentiated in the presence of the histone deacetylase inhibitor Trichostatin A were prevented from forming a normally inactivated X, as judged by the frequency of underacetylated X chromosomes detected by immunofluorescence microscopy. Mutant XT67E1 cells, lacking hyperacetylation upstream of Xist, were less affected. We propose that (i) hyperacetylation of chromatin upstream of Xist facilitates the promoter switch that leads to stabilization of the Xist transcript and (ii) that the subsequent deacetylation of this region is essential for the further progression of X inactivation.