No evidence of mutations in the P450 aromatase gene in patients with polycystic ovary syndrome

BACKGROUND: Etiology and inheritance pattern in polycystic ovary syndrome (PCOS) remain uncertain. Granulosa cells from follicles of women with PCOS have little, if any, aromatase (encoded by the CYP19 gene) activity; follicles contain low levels of estradiol, P450arom mRNA and aromatase stimulating bioactivity. Mice with targeted disruption of the CYP19 gene present cystic follicles. It has been proposed that chronic exposure to high levels of LH, because of aromatase deficiency, determines the development of ovarian cysts. Herein, we investigated if mutations in the CYP19 gene and/or its ovary promoter are causal in patients with PCOS. METHODS: Twenty-five patients with PCOS and 50 control women were studied. PCR analysis of genomic DNA and complete sequence of all exons of the aromatase gene and its ovary promoter were performed. RESULTS: No heterozygous or homozygous mutant alleles were present in any of the patients studied. CONCLUSIONS: In the population studied, mutations of the P450arom gene or its promoter are not the cause of PCOS. However, these findings do not preclude the possible importance of an aromatase disorder in PCOS etiology. Variations in aromatase complex function could play a role in PCOS etiology, but the determinants of such variations might be located in other genes.     

Breakpoint analysis of the pericentric inversion distinguishing human chromosome 4 from the homologous chromosome in the chimpanzee (Pan troglodytes)

The study of breakpoints that occurred during primate evolution promises to yield valuable insights into the mechanisms underlying chromosome rearrangements in both evolution and pathology. Karyotypic differences between humans and chimpanzees include nine pericentric inversions, which may have potentiated the parapatric speciation of hominids and chimpanzees 5-6 million years ago. Detailed analysis of the respective chromosomal breakpoints is a prerequisite for any assessment of the genetic consequences of these inversions. The breakpoints of the inversion that distinguishes human chromosome 4 (HSA4) from its chimpanzee counterpart were identified by fluorescence in situ hybridization (FISH) and comparative sequence analysis. These breakpoints, at HSA4p14 and 4q21.3, do not disrupt the protein coding region of a gene, although they occur in regions with an abundance of LINE and LTR-elements. At 30 kb proximal to the breakpoint in 4q21.3, we identified an as yet unannotated gene, C4orf12, that lacks an homologous counterpart in rodents and is expressed at a 33-fold higher level in human fibroblasts as compared to chimpanzee. Seven out of 11 genes that mapped to the breakpoint regions have been previously analyzed using oligonucleotide-microarrays. One of these genes, WDFY3, exhibits a three-fold difference in expression between human and chimpanzee. To investigate whether the genomic architecture might have facilitated the inversion, comparative sequence analysis was used to identify an approximately 5-kb inverted repeat in the breakpoint regions. This inverted repeat is inexact and comprises six subrepeats with 78 to 98% complementarity. (TA)-rich repeats were also noted at the breakpoints. These findings imply that genomic architecture, and specifically high-copy repetitive elements, may have made a significant contribution to hominoid karyotype evolution, predisposing specific genomic regions to rearrangements.     

Two novel translocation breakpoints upstream of SOX9 define borders of the proximal and distal breakpoint cluster region in campomelic dysplasia

The semilethal skeletal malformation syndrome campomelic dysplasia (CD) with or without XY sex reversal is caused by mutations within the SOX9 gene on 17q24.3 or by chromosomal aberrations (translocations, inversions or deletions) with breakpoints outside the SOX9 coding region. The previously published CD translocation breakpoints upstream of SOX9 fall into two clusters: a proximal cluster with breakpoints between 50-300 kb and a distal cluster with breakpoints between 899-932 kb. Here, we present clinical, cytogenetic and molecular data from two novel CD translocation cases. Case 1 with karyotype 46,XY,t(1;17)(q42.1;q24.3) has characteristic symptoms of CD, including mild tibial bowing, cryptorchidism and hypospadias. By standard fluorescence in situ hybridization (FISH) and by high-resolution fiber FISH, the 17q breakpoint was mapped 375 kb from SOX9, defining the centromeric border of the proximal breakpoint cluster region. Case 2 with karyotype 46,X,t(Y;17)(q11.2;q24.3) has the acampomelic form of CD and complete XY sex reversal. By FISH and somatic cell hybrid analysis, the 17q breakpoint was mapped 789 kb from SOX9, defining the telomeric border of the distal breakpoint cluster region. We discuss the structure of the 1 Mb cis-control region upstream of SOX9 and the correlation between the position of the 14 mapped translocation breakpoints with respect to disease severity and XY sex reversal.     

Deletions of SCN1A 5′ genomic region with promoter activity in Dravet syndrome

Mutations involving the voltage‐gated sodium channel α_I gene SCN1A are major genetic causes of childhood epileptic disorders, as typified by Dravet syndrome. Here we investigated the upstream regions of the SCN1A 5′ noncoding exons and found two major regions with promoter activity. These two major promoters were simultaneously active in various brain regions and in most neurons. Using multiplex ligation‐dependent probe amplification (MLPA) assays with probes for the 5′ noncoding exons, their upstream regions, and all coding exons of SCN1A, we investigated 130 epileptic patients who did not show any SCN1A mutations by sequence analysis of all coding exons and exon–intron boundaries. Among 71 Dravet syndrome patients, we found two patients with heterozygous microdeletions removing the 5′ noncoding exons and regions with promoter activity but not affecting the coding exons. We also identified four patients with deletions/duplication in the coding region. One patient with symptomatic focal epilepsy also showed a deletion in the coding region. This study provides the first case of microdeletion limited to the SCN1A 5′ promoter region with the coding sequence preserved, and indicates the critical involvement of this upstream region in the molecular pathology of Dravet syndrome. Hum Mutat 31:–11, 2010. © 2010 Wiley‐Liss, Inc.     

Opposite deletions/duplications of the X chromosome: two novel reciprocal rearrangements

Paralogous sequences on the same chromosome allow refolding of the chromosome into itself and homologous recombination. Recombinant chromosomes have microscopic or submicroscopic rearrangements according to the distance between repeats. Examples are the submicroscopic inversions of factor VIII, of the IDS gene and of the FLN1/emerin region, all resulting from misalignment of inverted repeats, and double recombination. Most of these inversions are of paternal origin possibly because the X chromosome at male meiosis is free to refold into itself for most of its length. We report on two de novo rearrangements of the X chromosome found in four hypogonadic females. Two of them had an X chromosome deleted for most of Xp and duplicated for a portion of Xq and two had the opposite rearrangement (class I and class II rearrangements, respectively). The breakpoints were defined at the level of contiguous YACs. The same Xp 11.23 breakpoint was found in the four cases. That of the long arm coincided in three cases (Xq21.3) and was more proximal in case 4 (Xq21.1). Thus class I rearrangements (cases 1 and 2) are reciprocal to that of case 3, whilst that of case 4 shares only the Xp breakpoint. The abnormal X was paternal in the three cases investigated. Repeated inverted sequences located at the breakpoints of rearrangements are likely to favour the refolding of the paternal X chromosome and the recombination of the repeats. The repeat at the Xp11 may synapse with either that at Xq21.3 or that at Xq21.1. These rearrangements seem to originate as the Xq28 submicroscopic inversions but they are identifiable at the microscopic level and result from a single recombination event.     

Intrachromosomal rearrangement of chromosome 3q27: an under recognized mechanism of BCL6 translocation in B-cell non-Hodgkin lymphoma

Balanced reciprocal translocations involving chromosomal region 3q27, which led to identification of the BCL6 protooncogene, are one of the most common recurrent chromosomal abnormalities reported in B-cell non-Hodgkin lymphomas (B-NHL). Cloning of the breakpoints of these translocations has facilitated the identification of a number of BCL6 partners including immunoglobulin genes and more than 20 non-immunoglobulin genes on almost all human chromosomes. Fusion of BCL6 with these genes leads to deregulated BCL6 expression because of substitution of its promoter with that of the translocation partner. Despite the promiscuous nature of BCL6 translocations, intrachromosomal rearrangements of the BCL6 gene have not been well recognized. In the present study, we present evidence for intrachromosomal rearrangements, because of interstitial deletions and inversions, involving region 3q27 as an overlooked mechanism of BCL6 deregulation. These rearrangements accounted for 3/20 (15%) of all BCL6 translocations occurring in B-NHL, including follicular lymphomas, diffuse large B-cell lymphomas, and marginal zone B-cell lymphomas, diagnosed at our institute. In addition to confirming previously described partner loci on chromosome 3, we also identified a novel BCL6 partner locus (3p24) that to our knowledge has not been reported previously. Our data should help facilitate the identification of new BCL6 partner genes, which may enhance our understanding of the clinical and biological role of BCL6 in B-NHL pathogenesis.     

Intrachromosomal serial replication slippage in trans gives rise to diverse genomic rearrangements involving inversions

Serial replication slippage in cis (SRScis) provides a plausible explanation for many complex genomic rearrangements that underlie human genetic disease. This concept, taken together with the intra- and intermolecular strand switch models that account for mutations that arise via quasipalindrome correction, suggest that intrachromosomal SRS in trans (SRStrans) mediated by short inverted repeats may also give rise to a diverse series of complex genomic rearrangements. If this were to be so, such rearrangements would invariably generate inversions. To test this idea, we collated all informative mutations involving inversions of >or=5 bp but <1 kb by screening the Human Gene Mutation Database (HGMD; www.hgmd.org) and conducting an extensive literature search. Of the 21 resulting mutations, only two (both of which coincidentally contain untemplated additions) were found to be incompatible with the SRStrans model. Eighteen (one simple inversion, six inversions involving sequence replacement by upstream or downstream sequence, five inversions involving the partial reinsertion of removed sequence, and six inversions that occurred in a more complicated context) of the remaining 19 mutations were found to be consistent with either two steps of intrachromosomal SRStrans or a combination of replication slippage in cis plus intrachromosomal SRStrans. The remaining lesion, a 31-kb segmental duplication associated with a small inversion in the SLC3A1 gene, is explicable in terms of a modified SRS model that integrates the concept of "break-induced replication." This study therefore lends broad support to our postulate that intrachromosomal SRStrans can account for a variety of complex gene rearrangements that involve inversions.     

鼻咽癌细胞中ezrin基因启动子上游序列转录调控特性的研究

目的:研究鼻咽癌细胞中ezrin基因启动子上游序列的转录调控特性。方法:构建一系列携带ezrin基因-1541/-706序列的报告基因表达载体,ezrin基因-1541/-706序列以正向和反向分别连接至不含启动子的报告基因上游、ezrin启动子上游、SV40启动子上游、ezrin启动子或SV40启动子控制的报告基因下游,将质粒转染CNE2细胞,检测荧光素酶活性。结果:CNE2细胞中,当-1541/-706序列正向位于报告基因上游时表现出启动子活性,其转录激活作用约为ezrin启动子的50%;反向连接时无启动子活性。而且,当-1541/-706序列正向位于ezrin启动子或SV40启动子上游时,显著提高荧光素酶表达;当反向位于启动子下游、正向或反向位于启动子控制的报告基因下游时,转录增强作用消失。结论:CNE2细胞中ezrin基因启动子上游序列具有转录激活和转录增强作用,这种作用具有DNA序列位置和方向依赖性。     

A common polymorphism in the human aromatase gene alters the risk for polycystic ovary syndrome and modifies aromatase activity in vitro

Aromatase is a key enzyme involved in estradiol and estrone biosynthesis. Given that polymorphisms of the CYP19A1 gene encoding aromatase have been correlated with plasma testosterone levels, CYP19A1 may therefore act as a genetic modifier of the hyperandrogenic phenotype of polycystic ovary syndrome (PCOS). However, no functional CYP19A1 polymorphisms that predict the risk of PCOS have been identified. We explored the role of CYP19A1 genetic variation in a large case-control study involving 1078 samples, in which five common genetic polymorphisms were scored. Human embryonic kidney 293 cells were transiently transfected with a vector encoding either the CYP19A1 wild-type (WT) allele or an Arg(264)Cys variant to evaluate aromatase activity. Cells were cultured with androstenedione and estrone levels were measured using a specific ELISA. The Arg(264)Cys variant of CYP19A1 (rs700519) is associated with PCOS (P= 0.004, corrected P = 0.02). In this functional study, when cells were cultured in varying concentrations of androstenedione (100, 400 and 500 nM), transfection with the Arg(264)Cys variant resulted in increased conversion of androstenedione to estrogen when compared with transfection with the WT construct (P< 0.001). Our data suggest that the common missense polymorphism rs710059 is associated with susceptibility to PCOS and that the Arg(264)Cys variant may increase aromatase enzymatic activity. Overall, these findings imply that aromatase plays an important role in PCOS.     

Distinct patterns of abnormal GNAS imprinting in familial and sporadic pseudohypoparathyroidism type IB

Pseudohypoparathyroidism type IB (PHPIB) is associated with abnormal imprinting of GNAS, the gene encoding the heterotrimeric G protein Gsalpha and other alternative products. The gene contains three differentially methylated regions (DMRs) located upstream of the Gsalpha promoter (from upstream to downstream): the paternally methylated NESP55 promoter region, the maternally methylated NESP antisense (NESPAS)/XLalphas promoter region and the maternally methylated exon 1A region located just upstream of the Gsalpha promoter. We have now performed a detailed analysis of the GNAS methylation profile in 20 unrelated PHPIB probands. Consistent with prior results, all have loss of exon 1A imprinting (a paternal epigenotype on both alleles). All five probands with familial disease had a deletion mutation within the closely linked STX16 gene and a GNAS imprinting defect involving only the exon 1A region. In contrast, the STX16 mutation was absent in all sporadic cases. The majority of these patients had abnormal imprinting of the more upstream regions in addition to the exon 1A imprinting defect, with eight of 15 having a paternal epigenotype on both alleles throughout the GNAS locus. In virtually all cases, the imprinting status of the NESP55 and NESPAS/XLalphas promoters is concordant, suggesting that their imprinting is co-regulated, whereas the imprinting of the NESPAS/XLalphas promoter region and XLalphas first exon is not always concordant even though they are closely linked and lie within the same DMR. Familial and sporadic forms of PHPIB have distinct GNAS imprinting patterns that occur through different defects in the imprinting mechanism.     

Polymorphisms of the upstream regulatory region of the major histocompatibility complex DRB genes in domestic horses

Sequence information was obtained on the variation of the ELA-DRB upstream regulatory region (URR) after polymerase chain reaction-single strand conformation polymorphism (PCR-SSCP) cloning and sequencing of approximately 220 bp upstream of the first exon of horse DRB genes. The sequence of the proximal URR of equine DRB is composed of highly conserved sequence motifs, showing the presence of the W, X, Y, CAAT and TATA conserved boxes of major histocompatibility complex (MHC) class II promoters. Five different polymorphic horse DRB promoter sequences were detected in five horse breeds. The results demonstrate the existence of polymorphism in the nucleotide sequences of the ELA-DRB URR, located in the functionally important conserved consensus sequences, the X2 box, the Y box and the TATA box, while conservation were observed in X1 and CAAT boxes. The nucleotide diversity among horse URRs was intermediate between that seen within human and mouse DRB promoters, suggesting the existence of another important source of variability in ELA-DRB genes. In addition, phylogenetic comparisons, identity analysis and sequence organization suggested that the reported sequences would correspond to an expressed ELA-DRB locus. However, further information about the functional significance of these promoter polymorphisms will probably be acquired through expression studies on the different sequences.