Project description:Vitamin A (retinol) is absorbed in the small intestine, stored in liver, and secreted into circulation bound to serum retinol-binding protein (RBP4). Circulating retinol may be taken up by extrahepatic tissues or recycled back to liver multiple times before it is finally metabolized or degraded. Liver exhibits high affinity binding sites for RBP4, but specific receptors have not been identified. The only known high affinity receptor for RBP4, Stra6, is not expressed in the liver. Here we report discovery of RBP4 receptor-2 (RBPR2), a novel retinol transporter expressed primarily in liver and intestine and induced in adipose tissue of obese mice. RBPR2 is structurally related to Stra6 and highly conserved in vertebrates, including humans. Expression of RBPR2 in cultured cells confers high affinity RBP4 binding and retinol transport, and RBPR2 knockdown reduces RBP4 binding/retinol transport. RBPR2 expression is suppressed by retinol and retinoic acid and correlates inversely with liver retinol stores in vivo. We conclude that RBPR2 is a novel retinol transporter that potentially regulates retinol homeostasis in liver and other tissues. In addition, expression of RBPR2 in liver and fat suggests a possible role in mediating established metabolic actions of RBP4 in those tissues.

Project description:The key step in bacterial promoter opening is recognition of the -10 promoter element (T(-12)A(-11)T(-10)A(-9)A(-8)T(-7) consensus sequence) by the RNA polymerase ? subunit. We determined crystal structures of ? domain 2 bound to single-stranded DNA bearing-10 element sequences. Extensive interactions occur between the protein and the DNA backbone of every -10 element nucleotide. Base-specific interactions occur primarily with A(-11) and T(-7), which are flipped out of the single-stranded DNA base stack and buried deep in protein pockets. The structures, along with biochemical data, support a model where the recognition of the -10 element sequence drives initial promoter opening as the bases of the nontemplate strand are extruded from the DNA double-helix and captured by ?. These results provide a detailed structural basis for the critical roles of A(-11) and T(-7) in promoter melting and reveal important insights into the initiation of transcription bubble formation.

Project description:Recognition of specific substrates for degradation by the ubiquitin-proteasome pathway is ensured by a cascade of ubiquitin transferases E1, E2 and E3. The mechanism by which the target proteins are transported to the proteasome is not clear, but two yeast E3s and one mammalian E3 ligase seem to be involved in the delivery of targets to the proteasome, by escorting them and by binding to the 19 S regulatory particle of the proteasome. In the present study, we show that SNEV (senescence evasion factor), a protein with in vitro E3 ligase activity, which is also involved in DNA repair and splicing, associates with the proteasome by directly binding to the beta7 subunit of the 20 S proteasome. Upon inhibition of proteasome activity, SNEV does not accumulate within the cells although its co-localization with the proteasome increases significantly. Since immunofluorescence microscopy also shows increased co-localization of SNEV with ubiquitin after proteasome inhibition, without SNEV being ubiquitinated by itself, we suggest that SNEV shows E3 ligase activity not only in vitro but also in vivo and escorts its substrate to the proteasome. Since the yeast homologue of SNEV, Prp19, also interacts with the yeast beta7 subunit of the proteasome, this mechanism seems to be conserved during evolution. Therefore these results support the hypothesis that E3 ligases might generally be involved in substrate transport to the proteasome. Additionally, our results provide the first evidence for a physical link between components of the ubiquitin-proteasome system and the spliceosome.

Project description:We demonstrate here that the α subunit C-terminal domain of Escherichia coli RNA polymerase (αCTD) recognizes the upstream promoter (UP) DNA element via its characteristic minor groove shape and electrostatic potential. In two compositionally distinct crystallized assemblies, a pair of αCTD subunits bind in tandem to the UP element consensus A-tract that is 6 bp in length (A6-tract), each with their arginine 265 guanidinium group inserted into the minor groove. The A6-tract minor groove is significantly narrowed in these crystal structures, as well as in computationally predicted structures of free and bound DNA duplexes derived by Monte Carlo and molecular dynamics simulations, respectively. The negative electrostatic potential of free A6-tract DNA is substantially enhanced compared to that of generic DNA. Shortening the A-tract by 1 bp is shown to "knock out" binding of the second αCTD through widening of the minor groove. Furthermore, in computationally derived structures with arginine 265 mutated to alanine in either αCTD, either with or without the "knockout" DNA mutation, contact with the DNA is perturbed, highlighting the importance of arginine 265 in achieving αCTD-DNA binding. These results demonstrate that the importance of the DNA shape in sequence-dependent recognition of DNA by RNA polymerase is comparable to that of certain transcription factors.

Project description:Sodium-dependent and chloride-dependent gamma-aminobutyric acid (GABA) transporter 1 (SLC6A1) is the target of a number of drugs of clinical importance and is a major determinant of synaptic GABA concentrations. We resequenced the human SLC6A1 gene previously and discovered a novel 21 bp insertion in the predicted promoter region that creates a second tandem copy of the sequence. Here we sought to determine the functional relevance of this variation.We used reporter assays, mobility shift assays, quantitative PCR, and proteomics methods as well as postmortem expression analysis for this work.Reporter assays showed that the insertion allele significantly increases promoter activity in multiple cell lines. The zinc finger transcription factor ZNF148 was found to significantly transactivate the promoter and increase expression when overexpressed but could not account for the differences in activity between the two alleles of the promoter. Copy number of the insertion sequence was associated with exponentially increasing activity of a downstream promoter, suggesting that the insertion sequence has enhancer activity when present in multiple copies. SLC6A1 promoter genotype was found to predict SLC6A1 RNA expression in human postmortem hippocampal samples. These results suggest that the insertion polymorphism leads to increased SLC6A1 promoter activity because, in part, of creation of an enhancer element when present as multiple copies. Genotyping individuals from Tanzania in this study suggested that the insertion allele has its origin in Africa.On account of the effect of the insertion on promoter activity, this relatively common polymorphism may prove useful in predicting clinical response to pharmacological modulators of SLC6A1 as well as GABAergic function in individuals of African descent.

Project description:A construct containing human Proalpha1(I) collagen gene promoter/enhancer-driven chloramphenicol acetyltransferase (CAT), pCOL-KT, failed to be expressed significantly in Sp1-deficient Schneider Drosophila line 2 (SL2) cells. However, CAT expression was induced 200-fold in SL2 cells co-transfected with pCOL-KT and pPACSp1, an Sp1-expression vector driven by the Drosophila actin 5C promoter. Elimination of the four potential Sp1-binding sites from pCOL-KT (pCOL-KTDeltaI), by removal of the first intron, did not abrogate Sp1-mediated induction of CAT. Even more significantly, a minimal Proalpha1(I) collagen promoter (-100 to +117 bp), containing a TATA box (-28 to -25 bp) and one putative Sp1-binding site (-87 to -82 bp), elicited strong Sp1-induced transactivation. Furthermore, mutation of the Sp1 motif in the minimal Proalpha1(I) collagen promoter-CAT construct abolished Sp1-induced expression of the reporter gene. Purified Sp1 protein bound specifically to DNA fragments of the Proalpha1(I) minimal promoter encompassing the putative Sp1-binding site; Sp1 binding could be competed out by a double-stranded oligonucleotide containing the wild-type Sp1 sequence, while an oligonucleotide containing a mutated Sp1 site failed to compete. Based on these results, we postulate that Sp1 plays an obligatory role in the transcriptional activation of the human Proalpha1(I) collagen gene. Additionally, we propose that a bona fide Sp1 motif, located most proximal to the TATA box, is necessary and sufficient for Sp1-mediated activation of the minimal Proalpha1(I) collagen promoter.

Project description:The organic cation transporter 1 (OCT1, SLC22A1) is strongly expressed in the human liver and facilitates the hepatic uptake of drugs such as morphine, metformin, tropisetron, sumatriptan and fenoterol and of endogenous substances such as thiamine. OCT1 expression is inter-individually highly variable. Here, we analyzed SNPs in the OCT1 promoter concerning their potential contribution to the variability in OCT1 expression. Using electrophoretic mobility shift and luciferase reporter gene assays in HepG2, Hep3B, and Huh7 cell lines, we identified the SNPs -1795G>A (rs6935207) and -201C>G (rs58812592) as having effects on transcription factor binding and/or promoter activity. The A-allele of the -1795G>A SNP showed allele-specific binding of the transcription factor NF-Y leading to 2.5-fold increased enhancer activity of the artificial SV40 promoter. However, the -1795G>A SNP showed no significant effects on the native OCT1 promoter activity. Furthermore, the -1795G>A SNP was not associated with the pharmacokinetics of metformin, fenoterol, sumatriptan and proguanil in healthy individuals or tropisetron efficacy in patients undergoing chemotherapy. Allele-dependent differences in USF1/2 binding and nearly total loss in OCT1 promoter activity were detected for the G-allele of -201C>G, but the SNP is apparently very rare. In conclusion, common OCT1 promoter SNPs have only minor effects on OCT1 expression.

Project description:Plants have evolved a plethora of responses to cope with phosphate (Pi) deficiency, including the transcriptional activation of a large set of genes. Among Pi-responsive genes, the expression of the Arabidopsis phospholipase DZ2 (PLDZ2) is activated to participate in the degradation of phospholipids in roots in order to release Pi to support other cellular activities. A deletion analysis was performed to identify the regions determining the strength, tissue-specific expression, and Pi responsiveness of this regulatory region. This study also reports the identification and characterization of a transcriptional enhancer element that is present in the PLDZ2 promoter and able to confer Pi responsiveness to a minimal, inactive 35S promoter. This enhancer also shares the cytokinin and sucrose responsive properties observed for the intact PLDZ2 promoter. The EZ2 element contains two P1BS motifs, each of which is the DNA binding site of transcription factor PHR1. Mutation analysis showed that the P1BS motifs present in EZ2 are necessary but not sufficient for the enhancer function, revealing the importance of adjacent sequences. The structural organization of EZ2 is conserved in the orthologous genes of at least eight families of rosids, suggesting that architectural features such as the distance between the two P1BS motifs are also important for the regulatory properties of this enhancer element.

Project description:The involucrin proximal promoter was examined for response elements that confer cell-type specificity. Using a segment spanning positions -157 to +41, three possible response elements were identified by their protein-binding activity using DNase I footprinting. From distal to proximal, they were: an activator protein-1 (AP-1) site (previously identified) overlapping an Ets-like site; a second Ets-like site located 13 bp more proximally; and an extended region designated footprinted site A (FPA). Mutation of the distal Ets-like site had essentially no effect on the transcriptional activity in transfections, while mutation of the proximal site reduced the activity by half. FPA was shown by electrophoretic mobility-shift assay (EMSA) to be comprised of two separable binding sites, FPA1 (distal) and FPA2 (proximal). While mutation of FPA2 had only a modest effect on transcriptional activity in transient transfections, mutation of FPA1 reduced transcriptional activity to approx. 20% of that obtained with the intact promoter. Additional mutations of FPA1 indicated that the active region comprises positions -85 to -73 (GTGGTGAAACCTGT). The molecular masses of the major proteins binding to this site were shown by UV cross-linking to be approx. 40 and 50 kDa, while minor bands were observed at 80 and 110 kDa. Since the involucrin promoter exhibits much higher transcriptional activity in keratinocytes than in other cell types in transfection assays (indicating that cell type specificity of expression is retained), the comparative influence of FPA1 was examined. While mutation of the AP-1 site affected transcriptional activity similarly in all cell lines tested, mutation of FPA1 decreased activity substantially in keratinocytes, but not in NIH-3T3 and HeLa cells, evidence for a contribution to cell-type specificity of expression. Furthermore, a correlation between the sensitivity to FPA1 mutation and amount of involucrin expression in different keratinocyte cell lines was evident. EMSA showed that NIH-3T3 and HeLa cells lacked the same FPA1 DNA-protein complex as keratinocytes. However, the amount of complex formed with nuclear extracts from several keratinocyte lines did not correlate well with the level of involucrin expression. Other factors, such as differences in post-translational modification or co-activators, must account for varied transcriptional response mediated by this site among keratinocyte lines.

Project description:The use of alternative promoters for the cell type-specific expression of a given mRNA/protein is a common cell strategy. NEMO is a scaffold protein required for canonical NF-?B signaling. Transcription of the NEMO gene is primarily controlled by two promoters: one (promoter B) drives NEMO transcription in most cell types and the second (promoter D) is largely responsible for NEMO transcription in liver cells. Herein, we have used a CRISPR/Cas9-based approach to disrupt a core sequence element of promoter B, and this genetic editing essentially eliminates expression of NEMO mRNA and protein in 293T human kidney cells. By cell subcloning, we have isolated targeted 293T cell lines that express no detectable NEMO protein, have defined genomic alterations at promoter B, and do not support activation of canonical NF-?B signaling in response to treatment with tumor necrosis factor. Nevertheless, non-canonical NF-?B signaling is intact in these NEMO-deficient cells. Expression of ectopic wild-type NEMO, but not certain human NEMO disease mutants, in the edited cells restores downstream NF-?B signaling in response to tumor necrosis factor. Targeting of the promoter B element does not substantially reduce NEMO expression (from promoter D) in the human SNU-423 liver cancer cell line. Thus, we have created a strategy for selectively eliminating cell type-specific expression from an alternative promoter and have generated 293T cell lines with a functional knockout of NEMO. The implications of these findings for further studies and for therapeutic approaches to target canonical NF-?B signaling are discussed.