Activation of nuclear protein binding to the antioxidant/electrophile response element in vascular smooth muscle cells by benzo(a)pyrene

This laboratory has previously shown that binding of nuclear proteins to the antioxidant/electrophile response element (ARE/EpRE) participates in deregulation of vascular gene expression by benzo(a)pyrene (BaP), a suspected atherogen. In the present study, oligonucleotides representing ARE/EpREs within the c-Ha-ras and glutathione-S-transferase (GST-Ya) promoters were employed to evaluate the role of flanking sequences in stabilizing protein:DNA interactions in BaP-treated vascular smooth muscle cells (vSMCs). We also wanted to define promoter-specific patterns of protein recognition to ARE/EpREs in this cell system. In electrophoretic mobility shift assays (EMSA), optimal protein binding to a human Ha-ras ARE/EpRE variant sequence fitted to match the extended mouse(m) GST-Ya ARE/EpRE core (5'-TMAnnRTGAYnnnGCR-3') was dependent on 5' nucleic acid sequence. Using immobilized DNA affinity chromatography (IDAC), we identified four nuclear proteins of M(r) 62, 60, 50, and 30 kDa that associated specifically with the mGSTYa ARE/EpRE. Photo crosslinking to a BrdU-substituted hHa-ras or mGST ARE/EpRE probe identified specific proteins of M(r) 80, 60, 55, 25, 23 kDa or 80, 60, 55, 27, 25, 23 kDa, respectively. Protein:DNA complexes detected using IDAC eluate overlapped with those observed in crude nuclear extracts. Chemical treatments known to modulate ARE/EpRE protein binding in vSMCs did not alter overall protein:DNA affinity and/or sequence recognition to either hHa-ras or mGST-Ya elements. We conclude that nucleotide sequences 5' to the core ARE/EpRE influence specific binding of nuclear proteins and that multiple proteins bind to ARE/EpREs in a promoter-specific manner in vSMCs.     

DNA sequence determinants of nuclear protein binding to the c-Ha-ras antioxidant/electrophile response element in vascular smooth muscle cells: identification of Nrf2 and heat shock protein 90 beta as heterocomplex components

The antioxidant/electrophile response element (ARE/EpRE) is a cis-acting element involved in redox regulation of c-Ha-ras gene. Protein binding to the ARE/EpRE may be credited to deoxyribonucleic acid sequence; therefore, studies were conducted to evaluate the influence of internal and flanking regions to the 10-bp human c-Ha-ras ARE/EpRE core (hHaras10) on nuclear protein binding in oxidant-treated vascular smooth muscle cells. A protein doublet bound to an extended oligonucleotide comprising the ARE/EpRE core in genomic context (hHaras27), whereas a single complex bound to hHarasl0. Protein binding involved specific interactions of 25- and 23-kDa proteins with hHarasl0, and binding of 80-, 65-, and 55-kDa proteins to hHaras27. Competition assays with hNQO1 and rGSTA2 confirmed the specificity of deoxyribonucleic acid-protein interactions and indicated preferred binding of p25 and p23 to the c-Ha-ras ARE/EpRE. "NNN" sequences within the core afforded unique protein-binding profiles to the c-Ha-ras ARE/EpRE. In addition, Nrf2 and heat shock protein 90beta (p80) were identified as components of the c-Ha-ras ARE/EpRE heterocomplex. We conclude that both internal bases and flanking sequences regulate nuclear protein recruitment and complex assembly on the c-Ha-ras ARE/EpRE.     

Influence of the hepatitis C virus 3′-untranslated region on IRES-dependent and cap-dependent translation initiation

Translation of hepatitis C virus (HCV) genomic RNA is directed by an internal ribosome entry site (IRES) in the 5′-untranslated region (5′-UTR), and the HCV 3′-UTR enhances IRES activity. Since the HCV 3′-UTR has a unique structure among 3′-UTRs, we checked possible communication between the 5′- and the 3′-UTR of HCV during translation using chimeric reporter RNAs. We show that translation directed by the HCV IRES and by the HCV-like IRES of porcine teschovirus (PTV) which belongs to a quite distinct family of viruses (picornaviruses) or by the EMCV IRES is also enhanced by the HCV 3′-UTR or by a poly(A)-tail in different cell types.     

Far upstream element binding protein 1 activates translation of p27Kip1 mRNA through its internal ribosomal entry site

The cyclin dependent kinase inhibitor p27 plays an important role in controlling the eukaryotic cell cycle by regulating progression through G1 and entry into S phase. It is often elevated during differentiation and under conditions of cellular stress. In contrast, it is commonly downregulated in cancer cells and its levels are generally inversely correlated with favorable prognosis. The cellular levels of p27 are regulated, in part, by translational control mechanisms. The 5′-untranslated region (5′-UTR) of the p27 mRNA harbors an internal ribosome entry site (IRES) which may facilitate synthesis of p27 in certain conditions. In this study, Far Upstream Element (FUSE) Binding Protein 1 (FBP1) was shown to directly bind to the human p27 5′-UTR and to promote IRES activity. An eight-nucleotide element downstream of a U-rich region within the 5′-UTR was important for FBP1 binding and p27 IRES activity. Overexpression of FBP1 enhanced endogenous p27 levels and stimulated translation initiation. In contrast, repression of FBP1 by siRNA transfection downregulated endogenous p27 protein levels. Using rabbit reticulocyte lysates, FBP1 stimulated p27 mRNA translation in vitro. The central domain of FBP1, containing four K homology motifs, was required for p27 5′-UTR RNA binding and the N terminal domain was important for translational activation. These findings indicate that FBP1 is a novel activator of p27 translation upon binding to the 5′-UTR.     

The beginning and the end: flanking nucleotides induce a parallel G-quadruplex topology

Genomic sequences susceptible to form G-quadruplexes (G4s) are always flanked by other nucleotides, but G4 formation in vitro is generally studied with short synthetic DNA or RNA oligonucleotides, for which bases adjacent to the G4 core are often omitted. Herein, we systematically studied the effects of flanking nucleotides on structural polymorphism of 371 different oligodeoxynucleotides that adopt intramolecular G4 structures. We found out that the addition of nucleotides favors the formation of a parallel fold, defined as the ‘flanking effect’ in this work. This ‘flanking effect’ was more pronounced when nucleotides were added at the 5′-end, and depended on loop arrangement. NMR experiments and molecular dynamics simulations revealed that flanking sequences at the 5′-end abolish a strong syn-specific hydrogen bond commonly found in non-parallel conformations, thus favoring a parallel topology. These analyses pave a new way for more accurate prediction of DNA G4 folding in a physiological context.     

Purification of an Arabidopsis chloroplast extract with in vitro RNA processing activity on psbA and petD 3'-untranslated regions

The mature 3′-end of many chloroplast mRNAs is generated by the processing of the 3′-untranslated region (3′-UTR), which is a mechanism that involves the removal of a segment located downstream an inverted repeat sequence that forms a stem-loop structure. Nuclear-encoded chloroplast RNA binding proteins associate with the stem-loop to process the 3′-UTR or to influence mRNA stability. A spinach chloroplast processing extract (CPE) has been previously generated and used to in vitro dissect the biochemical mechanism underlying 3′-UTR processing. Being Arabidopsis thaliana an important genetic model, the development of a CPE allowing to correlate 3′-UTR processing activity with genes encoding proteins involved in this process, would be of great relevance. Here, we developed a purification protocol that generated an Arabidopsis CPE able to correctly process a psbA 3′-UTR precursor. By UV crosslinking, we characterized the protein patterns generated by the interaction of RNA binding proteins with Arabidopsis psbA and petD 3′-UTRs, finding that each 3′-UTR bound specific proteins. By testing whether Arabidopsis CPE proteins were able to bind spinach ortholog 3′-UTRs, we also found they were bound by specific proteins. When Arabidopsis CPE 3′-UTR processing activity on ortholog spinach 3′-UTRs was assessed, stable products appeared: for psbA, a smaller size product than the expected mature 3′-end, and for petD, low amounts of the expected product plus several others of smaller sizes. These results suggest that the 3′-UTR processing mechanism of these chloroplast mRNAs might be partially conserved in Arabidopsis and spinach.     

Molecular structure and flanking nucleotide sequences of the natural chicken ovomucoid gene

Five independent clones containing the natural chicken ovomucoid gene have been isolated from a chicken gene library. One of these clones, CL21, contains the complete ovomucoid gene and includes more than 3 kb of DNA sequences flanking both termini of the gene. Restriction endonuclease mapping, electron microscopy and direct DNA sequencing analyses of this clone have revealed that the ovomucoid gene is 5.6 kb long and codes for a messenger RNA of 821 nucleotides. The structural gene sequence coding Ifor the mature messenger RNA is split into at least eight segments by a minimum of seven intervening sequences of various sizes. The shortest structural gene segment is only 20 nucleotides long. All seven intervening sequences are located within the peptide coding region of the gene, and the sequences at the 5' and 3' untranslated regions of the mRNA are not interrupted by intervening sequences. The DNA sequences of the regions flanking the 5' and 3' termini of the gene have been determined. Thirty nucleotides before the start of the messenger RNA coding sequence is the heptanucleotide TATATAT, which is also present in a similar location relative to the chicken ovalbumin gene and other unique sequence eucaryotic genes. This sequence resembles that of the Pribnow box in procaryotic genes where a promoter function has been implicated. Seven nucleotides past the 3' end of the gene is the tetranucleotide TTGT, a sequence found to be present at identical locations as either TTTT or TTGT in other eucaryotic genes that have been sequenced. These conserved DNA sequences flanking eucaryotic genes may serve some regulator function in the expression of these genes.     

Sequence and expression pattern of the Drosophila melanogaster mitochondrial porin gene: evidence of a conserved protein domain between fly and mouse

We have recently cloned a cDNA encoding mitochondrial porin in Drosophila melanogaster and shown its chromosomal localization (Messina et al., FEBS Lett. (1996) 384, 9–13). Such cDNA was used as a probe for screening a genomic library. We thus cloned and sequenced a 4494-bp genomic region which contained the whole gene for the mitochondrial porin or VDAC. It was found that this D. melanogaster porin gene contains five exons, numbered IA (115 bp), IB (123 bp), II (320 bp), III (228 bp) and IV (752 bp). The exons II, III and IV contain the protein coding sequence and the 3′ untranslated sequence (3′-UTR). The first base in exon II precisely corresponds to the first base of the starting ATG codon. Exon IA corresponds to the 5′-UTR sequence reported in the published cDNA sequence. Exon IB corresponds to an alternative 5′-UTR sequence, demonstrated to be transcribed by 5′-RACE experiments. The exon-intron splicing borders and the length of the exon III perfectly match a homologous internal exon detected in the mouse genes. Such exon encodes a protein domain predicted by sequence transmembrane arrangement models to contain major hydrophilic loops and it is thus suspected to have a conserved distinct function. In situ hybridization experiments confirmed the localization of the genomic clone on the chromosome 2L at region 32B3-4. Together with genomic Southern blotting at various stringencies, the same experiment did not confirm the presence of a second genetic locus on D. melanogaster chromosomes. Northern blots demonstrated that the porin gene is a housekeeping one: three messages of approx. 1.2–1.6 kbp are transcribed in every fly developmental stage that was studied. They were shown to derive by an alternative usage of different promoters and polyadenylation sites.     

Localization and nucleotide sequence of the gene for the membrane polypeptide D2 from pea chloroplast DNA

Summary The gene for the membrane polypeptide D2 has been mapped on the pea (Pisum sativum) chloroplast genome. The nucleotide sequence of the gene and its flanking regions is presented. The only large open reading frame in the sequence codes for a protein of MW 39.5 kD. A potential ribosome binding site is located 6 nucleotides upstream from the initiation codon and there are two sets of putative promotor sequences in the 5 flanking region. The polypeptide has a high content of hydrophobic amino acids, predominatly grouped in clusters of 20 or more residues. The 3 end of the D2 gene is overlapped by 50 nucleotides of a second open reading frame (UORF I) which is at least 369 nucleotides long. Based on current data we suggest the D2 polypeptide to be a constituent of photosystem II (PSII).     

Structure of the coding region and mRNA variants of the apyrase gene from pea (Pisum sativum)

Partial amino acid sequences of a 49 kDa apyrase (ATP diphosphohydrolase, EC 3.6.1.5) from the cytoskeletal fraction of etiolated pea stems were used to derive oligonucleotide DNA primers to generate a cDNA fragment of pea apyrase mRNA by RT-PCR and these primers were used to screen a pea stem cDNA library. Two almost identical cDNAs differing in just 6 nucleotides within the coding regions were found, and these cDNA sequences were used to clone genomic fragments by PCR. Two nearly identical gene fragments containing 8 exons and 7 introns were obtained. One of them (H-type) encoded the mRNA sequence described by Hsieh et al. (1996) (DDBJ/EMBL/GenBank Z32743), while the other (S-type) differed by the same 6 nucleotides as the mRNAs, suggesting that these genes may be alleles. The six nucleotide differences between these two alleles were found solely in the first exon, and these mutation sites had two types of consensus sequences. These mRNAs were found with varying lengths of 3′ untranslated regions (3′-UTR). There are some similarities between the 3′-UTR of these mRNAs and those of actin and actin binding proteins in plants. The putative roles of the 3′-UTR and alternative polyadenylation sites are discussed in relation to their possible role in targeting the mRNAs to different subcellular compartments. Sequence data from this article were deposited with the DDBJ/EMBL/GenBank Data Libraries under Accession Nos. Genomic sequences of pea apyrase: AB023621, AB030444, AB030445, AB038554, AB038555. cDNA sequences of pea apyrase: AB022319, AB027614, AB038668, AB038669.     

Selection of mRNA 5'-untranslated region sequence with high translation efficiency through ribosome display

The 5′-untranslated region (5′-UTR) of mRNAs functions as a translation enhancer, promoting translation efficiency. Many in vitro translation systems exhibit a reduced efficiency in protein translation due to decreased translation initiation. The use of a 5′-UTR sequence with high translation efficiency greatly enhances protein production in these systems. In this study, we have developed an in vitro selection system that favors 5′-UTRs with high translation efficiency using a ribosome display technique. A 5′-UTR random library, comprised of 5′-UTRs tagged with a His-tag and Renilla luciferase (R-luc) fusion, were in vitro translated in rabbit reticulocytes. By limiting the translation period, only mRNAs with high translation efficiency were translated. During translation, mRNA, ribosome and translated R-luc with His-tag formed ternary complexes. They were collected with translated His-tag using Ni-particles. Extracted mRNA from ternary complex was amplified using RT-PCR and sequenced. Finally, 5′-UTR with high translation efficiency was obtained from random 5′-UTR library.     

Nucleotide sequence and genomic organization of a human T lymphocyte serine protease gene

We have determined the nucleotide sequence of 4508 base pairs of human genomic DNA which contain the human serine esterase gene from cytotoxic T lymphocytes (SECT) (equivalent to the 1-3E cDNA clone) and include 879 bp of 5' flanking DNA and 393 bp of 3' flanking DNA. The gene consists of five exons of 88, 148, 136, 261, and 257 nucleotides separated by four introns of 1043, 455, 205, and 643 nucleotides. The location of introns with respect to protein coding sequences in the SECT gene is identical to that of the human cathepsin G and murine granzyme B genes. Comparison of SECT gene exonic sequences to murine granzyme B-F cDNA sequences indicates similarities of 75 and 72% for granzymes B and C and 61, 59, and 61% for granzymes D, E, and F, respectively. The 5' flanking sequence of the SECT gene showed similarity only to the 5' flanking sequence of the murine granzyme B gene, indicating that these genes are homologous. Comparison of the SECT gene sequence to the human cathepsin G sequence indicated no similarity in the 5' flanking DNA although the exonic sequences show 64% sequence similarity overall and 45% sequence similarity in the respective 3' untranslated regions. These similarities suggest that the SECT and cathepsin G genes are members of the same family of serine protease genes. Evidence from high and low stringency Southern transfer analysis of human genomic DNA indicates the presence of another gene of at least 85% sequence similarity to the SECT gene.