Altered expression and splicing of Ca(2+) metabolism genes in myotonic dystrophies DM1 and DM2.

AIMS: Myotonic dystrophy types 1 and 2 (DM1 and DM2) are multisystem disorders caused by similar repeat expansion mutations, with similar yet distinct clinical features. Aberrant splicing of multiple effector genes, as well as dysregulation of transcription and translation, has been suggested to underlie different aspects of the complex phenotypes in DM1 and DM2. Ca(2+) plays a central role in both muscle contraction and control of gene expression, and recent expression profiling studies have indicated major perturbations of the Ca(2+) signalling pathways in DM. Here we have further investigated the expression of genes and proteins involved in Ca(2+) metabolism in DM patients, including Ca(2+) channels and Ca(2+) binding proteins. METHODS: We used patient muscle biopsies to analyse mRNA expression and splicing of genes by microarray expression profiling and RT-PCR. We studied protein expression by immunohistochemistry and immunoblotting. RESULTS: Most of the genes studied showed mRNA up-regulation in expression profiling. When analysed by immunohistochemistry the Ca(2+) release channel ryanodine receptor was reduced in DM1 and DM2, as was calsequestrin 2, a sarcoplasmic reticulum lumen Ca(2+) storage protein. Abnormal splicing of ATP2A1 was more pronounced in DM2 than DM1. CONCLUSIONS: We observed abnormal mRNA and protein expression in DM affecting several proteins involved in Ca(2+) metabolism, with some differences between DM1 and DM2. Our protein expression studies are suggestive of a post-transcriptional defect(s) in the myotonic dystrophies.

Tumor-suppression function of transcription factor USF2 in prostate carcinogenesis.

Although the transcription factor USF2 has been implicated in the regulation of cellular growth and proliferation, it is unknown whether alterations in USF2 contribute to tumorigenesis and tumor development. We examined the role of USF2 in prostate tumorigenesis. Western blot analysis revealed markedly decreased USF2 levels in three androgen-independent prostate cancer cell lines, PC-3, DU145, and M12, as compared to nontumorigenic prostate epithelial cells or the androgen-dependent cell line, LNCaP. Ectopic expression of USF2 in PC-3 cells did not affect the cell proliferation rate of PC-3 cells on plastic surfaces. However, it dramatically decreased anchorage-independent growth of PC-3 cells in soft agar (90-98% inhibition) and the invasion capability (80% inhibition) of PC-3 cells in matrix gel assay. Importantly, expression of USF2 in PC-3 cells inhibited the tumorigenicity of PC-3 cells in an in vivo nude mice xenograft model (80-90% inhibition). These results suggest that USF2 has tumor-suppression function. Consistent with its function in tumor suppression, we found that the USF2 protein is present in normal prostate epithelial cells but absent in 18 of 42 (43%) human prostate cancer tissues (P = 0.015). To further examine the functional role of USF2 in vivo, we generated mice with genetic deletion of USF2 gene. We found that USF2-null mice displayed marked prostate hyperplasia at a young age, suggesting that USF2 is involved in the normal growth and differentiation of prostate. Together, these studies demonstrate that USF2 has tumor-suppressor function and plays a role in prostate carcinogenesis.

New methods for molecular diagnosis and demonstration of the (CCTG)n mutation in myotonic dystrophy type 2 (DM2).

Myotonic dystrophy types 1 and 2 are autosomal dominant, multisystemic disorders with many similarities in their clinical manifestations. Myotonic dystrophy type 1 is caused by a (CTG)n expansion in the 3' untranslated region of the DMPK gene in 19q13.3 and myotonic dystrophy type 2 by a (CCTG)n expansion in intron 1 of ZNF9 in 3q21.3. However, the clinical diagnosis of myotonic dystrophy type 2 is more complex than that of myotonic dystrophy type 1, and conventional molecular genetic methods used for diagnosing myotonic dystrophy type 1 are insufficient for myotonic dystrophy type 2. Herein we describe two in situ hybridization protocols for the myotonic dystrophy type 2 mutation detection. Chromogenic in situ hybridization was used to detect both the genomic expansion and the mutant transcripts in muscle biopsy sections. Chromogenic in situ hybridization can be used in routine myotonic dystrophy type 2 diagnostics. Fluorescence in situ hybridization on extended DNA fibers was used to directly visualize the myotonic dystrophy type 2 mutation and to estimate the repeat expansion sizes.

The transcription factors MTF-1 and USF1 cooperate to regulate mouse metallothionein-I expression in response to the essential metal zinc in visceral endoderm cells during early development.

During early development of the mouse embryo, expression of the metallothionein-I (MT-I) gene is heightened specifically in the endoderm cells of the visceral yolk sac. The mechanisms of regulation of this cell-specific pattern of expression of metallothionein-I are unknown. However, it has recently been shown that MTF-1, functioning as a metalloregulatory transcription factor, activates metallothionein genes in response to the essential metal zinc. In contrast with the metallothionein genes, MTF-1 is essential for development; null mutant embryos die due to liver degeneration. We report here that MTF-1 is absolutely essential for upregulation of MT-I gene expression in visceral endoderm cells and that optimal expression also involves interactions of the basic helix-loop-helix upstream stimulatory factor-1 (USF1) with an E-box1-containing sequence at -223 bp in the MT-I promoter. Expression of MT-I in visceral endoderm cells was dependent on maternal dietary zinc. Thus, the essential metal, zinc, apparently provides the signaling ligand that activates cell-specific MT-I expression in visceral endoderm cells.

Adenovirus E1A down-regulates the EGF receptor via repression of its promoter.

The epidermal growth factor receptor (EGF-R), after activation by its ligands, stimulates a cascade of intracellular events leading to cellular proliferation. Its expression is increased in various forms of cancer as a consequence of altered regulation. Our objective was to study potential negative regulators of EGF-R expression; we investigated the effect of adenovirus E1A proteins. E1A proteins can exert both positive and negative effects on cell growth, depending on the cell type and cellular context, and have anti-tumorigenic features on human cancer cells. We show that human cell lines stably transformed with the adenovirus E1 region show significantly reduced expression of EGF-R protein and mRNA compared to their control, non-E1A-expressing counterparts. Furthermore, the promoter activity of EGF-R can be specifically repressed by E1A in transient co-transfection analysis in multiple cell types. Transfections with deleted promoter fragments and constructs containing short fragments of the putative E1A-responsive region fused to a heterologous promoter indicate that E1A-responsive elements are contained in a promoter region (from -150 to -76). Analysis of E1A mutants showed that both E1A gene products, 12S and 13S, repress EGF-R promoter activity and that full repression requires the presence of an intact CR1 domain.

Overlapping roles and asymmetrical cross-regulation of the USF proteins in mice.

USF1 and USF2 are ubiquitously expressed transcription factors implicated as antagonists of the c-Myc protooncoprotein in the control of cellular proliferation. To determine the biological role of the USF proteins, mutant mice were generated by homologous recombination in embryonic stem cells. USF1-null mice were viable and fertile, with only slight behavioral abnormalities. However, these mice contained elevated levels of USF2, which may compensate for the absence of USF1. In contrast, USF2-null mice contained reduced levels of USF1 and displayed an obvious growth defect: they were 20-40% smaller at birth than their wild-type or heterozygous littermates and maintained a smaller size with proportionate features throughout postnatal development. Some of the USF-deficient mice, especially among the females, were prone to spontaneous epileptic seizures, suggesting that USF is important in normal brain function. Among the double mutants, an embryonic lethal phenotype was observed for mice that were homozygous for the Usf2 mutation and either heterozygous or homozygous for the Usf1 mutation, demonstrating that the USF proteins are essential in embryonic development.

A negative cis-acting G-fer element participates in the regulation of expression of the human H-ferritin-encoding gene (FERH).

Ferritin (Fer) is the major iron storage protein in man. Its synthesis is regulated both at the translational and transcriptional levels. In previous studies on transcriptional regulation of the human H-ferritin-encoding gene (FERH), a 160-bp promoter segment was analyzed [Bevilacqua et al., Gene 111 (1992) 255-260]. In order to obtain a more complete view of the elements involved in the transcriptional regulation of FERH, we have studied, in a further upstream region of the human FERH promoter (pFERH), a sequence between -272 and -291, named G-fer, because it contains a stretch of ten G, which binds a nuclear factor present in different cell types. DNA-binding assays and competition experiments suggest that the factor binding to G-fer has binding properties very similar to inhibitory factor-1 (IF-1), an ubiquitous factor that interacts with G-rich elements in the promoters of the mouse type-I collagen genes. DNA transfection experiments in HeLa cells, using either a wild-type or mutated pFERH fused to a reporter gene, showed that a 3-bp substitution mutation, that abolished the binding of the specific factor to G-fer, increased the promoter activity, thus suggesting an inhibitory role for the G-fer element and its cognate trans-acting factor.

Ubiquitous expression of the 43- and 44-kDa forms of transcription factor USF in mammalian cells.

USF is a helix-loop-helix transcription factor that, like Myc, recognizes the DNA binding motif CACGTG. Two different forms of USF, characterized by apparent molecular weights of 43,000 and 44,000, were originally identified in HeLa cells by biochemical analysis. Clones for the 43-kDa USF were first characterized, but only partial clones for the human 44-kDa USF (USF2, or FIP) have been reported. Here we describe a complete cDNA for the 44-kDa USF from murine cells. Analysis of this clone has revealed that the various USF family members are quite divergent in their N-terminal amino acid sequences, while a high degree of conservation characterizes their dimerization and DNA-binding domains. Interestingly, the 3' noncoding region of the 44-kDa USF cDNAs displayed an unusual degree of conservation between human and mouse. In vitro transcription/translation experiments indicated a possible role for this region in translation regulation. Alternative splicing forms of the 44-kDa USF messages exist in both mouse and human. Examination of the tissue and cell-type distribution of USF by Northern blot and gel retardation assays revealed that while expression of both the 43- and 44-kDa USF species is ubiquitous, different ratios of USF homo- and heterodimers are found in different cells.

Lactoferrin binding sites and nuclear localization in K562(S) cells.

Lactoferrin, a single chain cationic glycoprotein, present in the secondary granules of neutrophils, acts as a negative feedback regulator of myelopoiesis. Specific receptors for lactoferrin were detected on the surface of different hematopoietic cell types. The influence of lactoferrin on cell growth in culture has been reported. Interactions of lactoferrin with DNA were also demonstrated. In the present paper we confirm the presence of lactoferrin specific binding sites on K562 cells and we estimate the number of binding sites and the dissociation constant. By Western blotting analysis performed on K562 lysates we find a band of about 120 kDa responsible for specific binding of lactoferrin. We also show that lactoferrin, after binding at the cell surface, is internalized in a temperature dependent way and is immunologically detectable as a DNA-linked protein in nuclear extracts.

Single-step purification of bacterially expressed polypeptides containing an oligo-histidine domain.

Plasmid expression vectors have been constructed that direct the synthesis in Escherichia coli of fusion proteins containing a stretch of six histidine residues at either the N or C terminus. This oligo-histidine domain allows the single-step purification of the fusion proteins, under nondenaturing conditions, by immobilized metal affinity chromatography on Ni2+ bound to iminodiacetic acid-agarose. Several eukaryotic transcription factors (e.g., the upstream stimulatory factor for the adenovirus major late promoter) have been successfully purified, in an active state, by this method.

Members of the USF family of helix-loop-helix proteins bind DNA as homo- as well as heterodimers.

We have isolated human cDNA clones for USF2, a new member of the upstream stimulatory factor (USF) family of transcription factors. Analysis of these clones revealed the existence of highly conserved elements in the C terminal region of all USF proteins. These include the basic region, helix-loop-helix (HLH) motif, and, in the case of the human proteins, the C-terminal leucine repeat (LR). In addition, a highly conserved USF-specific domain is located immediately upstream of the basic region. Using in vitro translated proteins, we found that all members of the USF family bound DNA as dimers. The N-terminal portion of USF, including the USF-specific domain, was entirely dispensable for dimer formation and DNA-binding. However, deletion mutants of USF2 lacking the LR were deficient in DNA-binding activity. Interestingly, each of the USF proteins could form functional heterodimers with the other family members, including the sea urchin USF, which does not have a LR motif. This indicates that the conserved LR in human USF is not required for dimer formation, and influences only indirectly DNA-binding.