TWIST represses estrogen receptor-alpha expression by recruiting the NuRD protein complex in breast cancer cells

Loss of estrogen receptor α (ERα) expression and gain of TWIST (TWIST1) expression in breast tumors correlate with increased disease recurrence and metastasis and poor disease-free survival. However, the molecular and functional regulatory relationship between TWIST and ERα are unclear. In this study, we found TWIST was associated with a chromatin region in intron 7 of the human ESR1 gene coding for ERα. This association of TWIST efficiently recruited the nucleosome remodeling and deacetylase (NuRD) repressor complex to this region, which subsequently decreased histone H3K9 acetylation, increased histone H3K9 methylation and repressed ESR1 expression in breast cancer cells. In agreement with these molecular events, TWIST expression was inversely correlated with ERα expression in both breast cancer cell lines and human breast ductal carcinomas. Forced expression of TWIST in TWIST-negative and ERα-positive breast cancer cells such as T47D and MCF-7 cells reduced ERα expression, while knockdown of TWIST in TWIST-positive and ERα-negative breast cancer cells such as MDA-MB-435 and 4T1 cells increased ERα expression. Furthermore, inhibition of histone deacetylase (HDAC) activity including the one in NuRD complex significantly increased ERα expression in MDA-MB-435 and 4T1 cells. HDAC inhibition together with TWIST knockdown did not further increase ERα expression in 4T1 and MDA-MB-435 cells. These results demonstrate that TWIST/NuRD represses ERα expression in breast cancer cells. Therefore, TWIST may serve as a potential molecular target for converting ERα-negative breast cancers to ERα-positive breast cancers, allowing these cancers to restore their sensitivity to endocrine therapy with selective ERα antagonists such as tamoxifen and raloxifene.     

A 1.5-Mb physical map of the hidrotic ectodermal dysplasia (Clouston syndrome) gene region on human chromosome 13q11

The HED (hidrotic ectodermal dysplasia) or Clouston syndrome gene (named ED2) has been mapped to the pericentromeric region of chromosome 13 (13q11) to a 2.4-cM interval flanked by markers D13S1828 and D13S1830. We have developed a BAC/PAC-based contig map of this region. This contig, comprising 23 clones and spanning 1.5 Mb, was established by mapping of 27 BAC/PAC end-derived STSs, 11 known polymorphic markers, 2 previously mapped genes, and 14 ESTs. The genomic clone overlaps were confirmed by restriction fragment fingerprint analysis. This contig provides the basis for genomic sequencing and gene identification in the ED2 critical region. Of the 14 ESTs mapped to the contig, 6 show homology to human genes and 8 appear to be novel. Expression patterns of the genes/ESTs were tested by Northern blot and RT-PCR. Full characterization of some of these genes, as well as the novel ESTs, will be useful in assessing their involvement in the HED/Clouston syndrome.     

Identification of the mouse and rat orthologs of the gene mutated in Usher syndrome type IIA and the cellular source of USH2A mRNA in retina,a target tissue of the disease

Usher syndrome type IIA (MIM: 27601) is an autosomal recessive disorder characterized by moderate to severe congenital deafness and progressive retinitis pigmentosa. We recently identified the human Usher syndrome type IIA gene (USH2A) on chromosome 1q41, which encodes a protein possessing 10 laminin epidermal growth factor and four fibronectin type 3 domains, both commonly observed in extracellular matrix proteins. To gain insight into the pathogenesis of Usher syndrome type IIA, we isolated and characterized the murine (Ush2a) and rat (rat Ush2a) orthologs of human USH2A. We mapped mouse Ush2a by fluorescence in situ hybridization to mouse chromosome 1 in the region syntenic to human chromosome 1q41. Rat Ush2a has been localized by radiation hybrid mapping to rat chromosome 13 between d13rat49 and d13rat76. The mouse and rat genes, similar to human USH2A, are expressed primarily in retina and cochlea. Mouse Ush2a encodes a 161-kDa protein that shows 68% identity and 9% similarity to the human USH2A protein. Rat Ush2a encodes a 167-kDa protein with 64% identity and 10% similarity to the human protein and 81% identity and 5% similarity to the mouse USH2A protein. The predicted amino acid sequence of the mouse and rat proteins, like their human counterpart, contains a leader sequence, an amino-terminal globular domain, 10 laminin epidermal growth factor domains, and four carboxy-terminal fibronectin type III motifs. With in situ hybridization, we compared the cellular expression of the USH2A gene in rat, mouse, and human retinas. USH2A mRNA in the adult rat, mouse, and human is expressed in the cells of the outer nuclear layer of the retina, one of the target tissues of the disease. In the developing rat retina, Ush2a mRNA expression appears in the neuroepithelium at embryonic day 17.     

Structure of the human TNF receptor 1 (p60) gene (TNFR1) and localization to chromosome 12p13 [corrected]

Clones encoding the entire coding and 3' untranslated region of the human type I tumor necrosis factor receptor (p60) gene (TNFR1) were isolated by hybridization using probes derived from TNFR-1 cDNA. The gene was characterized by restriction mapping. DNA blot analysis and sequence analysis. The coding region and the 3' untranslated region are distributed over 10 exons. Each of the four repeats, comprising the extracellular ligand binding domain and characterizing a receptor superfamily, is interrupted by an intron. However, the intron-exon structure is not conserved in the nerve growth factor receptor gene, another member of this superfamily. By PCR analysis of human-mouse somatic cell hybrids and in situ hybridization using biotinylated genomic TNFR1 DNA, we localized the gene to human chromosomal band 12p13. This corresponds to the homologous murine gene localized at the distal region of mouse chromosome 6.     

Assignment of the erythropoietin receptor (EPOR) gene to mouse chromosome 9 and human chromosome 19

Erythropoietin (EPO), the primary regulator of mammalian erythropoiesis, binds and activates a specific receptor on erythroid progenitors. The human and mouse cDNAs for this receptor (EPOR) have recently been isolated. These cDNAs were used to establish the genomic location of the EPOR gene. By somatic cell hybrid analysis, the locus for the EPOR maps to human chromosome (Chr) 19pter-q12. By interspecific backcross mapping the locus is tightly linked to the murine Ldlr locus near the centromere of mouse Chr9. This region of mouse Chr9 is homologous to a region of human Chr 19p13 carrying the human LDLR and MEL loci, strongly suggesting that the human EPOR gene is at 19p13 near the human LDLR locus.     

The EIF3S3 gene encoding the p40 subunit of the translation initiation factor eIF3 has eight exons and maps to the Langer-Giedion syndrome chromosome region on 8q24, but is not the TRPS1 gene

We have mapped the gene encoding the p40 subunit of the eukaryotic translation initiation factor eIF3 (EIF3S3) close to the distal border of the minimal critical region for tricho-rhino-phalangeal syndrome type I (TRPS I) on human chromosome 8q24. Because this location makes EIF3S3 a candidate for the TRPS1 gene, we have determined the genomic structure of the EIF3S3 gene and searched for gene deletions and mutations in patients with TRPS I. The gene has eight exons and is transcribed from telomere to centromere. No deletion could be detected in 32 unrelated patients with an apparently normal karyotype. Sequence analysis of all exons in 15 unrelated patients did not reveal any point mutation either. Our data exclude EIF3S3 as the TRPS1 gene.     

Physical mapping of the human ATX1 homologue (HAH1) to the critical region of the 5q- syndrome within 5q32, and immediately adjacent to the SPARC gene

The 5q- syndrome is a myelodysplastic syndrome with the 5q deletion as the sole karyotypic abnormality. The human ATX1 homologue (HAH1), encodes a copper-binding protein with a role in antioxidant defence. We have mapped this gene to the 3 Mb critical region of gene loss of the 5q- syndrome within 5q32, flanked by the genes for ADRB2 and IL12B, using gene dosage analysis. Fine physical mapping of the HAH1 gene within this genomic interval was then performed by screening YAC and BAC contigs spanning the critical region of the 5q- syndrome using PCR amplification. The HAH1 gene maps immediately adjacent to the SPARC gene at 5q32, and is flanked by the genetic markers D5S1838 and D5S1419. The HAH1 gene is expressed in haematological tissues and plays a role in antioxidant defence. Antioxidant levels are low in most cancers and the importance of antioxidant enzymes in cancer genesis is well recognised. Genomic localisation, function and expression would suggest that the HAH1 gene represents a candidate gene for the 5q-syndrome.     

The human homolog of insect-derived growth factor, CECR1, is a candidate gene for features of cat eye syndrome

Cat eye syndrome (CES) is a developmental disorder with multiple organ involvement, associated with the duplication of a 2-Mb region of 22q11.2. Using exon trapping and genomic sequence analysis, we have isolated and characterized a gene, CECR1, that maps to this critical region. The protein encoded by CECR1 is similar to previously identified novel growth factors: IDGF from Sarcophaga peregrina (flesh fly) and MDGF from Aplysia californica (sea hare). The CECR1 gene is alternatively spliced and expressed in numerous tissues, with most abundant expression in human adult heart, lung, lymphoblasts, and placenta as well as fetal lung, liver, and kidney. In situ hybridization of a human embryo shows specific expression in the outflow tract and atrium of the developing heart, the VII/VIII cranial nerve ganglion, and the notochord. The location of this gene in the CES critical region and its embryonic expression suggest that the overexpression of CECR1 may be responsible for at least some features of CES, particularly the heart defects.