Efficiency of the miRNA–mRNA Interaction Prediction Programs

miRNAs play a key role in regulation of gene expression. Nowadays it is known more than 2500 human miRNAs, while a majority of miRNA–mRNA interactions remains unidentified. The recent development of a high-throughput CLASH (crosslinking, ligation and sequencing of hybrids) technique for discerning miRNA–mRNA interactions allowed an experimental analysis of the human miRNA–mRNA interactome. Therefore, it allowed us, for the first time, make an experimental analysis of the human miRNA–mRNA interactome as a whole and an evaluation of the quality of most commonly used miRNA prediction tools (TargetScan, PicTar, PITA, RNA22 and miRanda). To estimate efficiency of the miRNA–mRNA prediction tools, we used next parameters: sensitivity, positive predicted value, predictions in different mRNA regions (3' UTR, CDS, 5' UTR), predictions for different types of interactions (5 classes), predictions of “canonical” and “nocanonical” interactions, similarity with the random generated data. The analysis revealed low efficiency of all prediction programs in comparison with the CLASH data in terms of the all examined parameters.     

Degradation of δ-crystallin mRNA in the lens fiber cells of the chicken

δ-Crystallin is the principal protein synthesized in the embryonic chicken lens. After hatching δ-crystallin synthesis decreases and eventually ceases. We have determined when the δ-crystallin messenger RNA (mRNA) disappears from the lens fiber cells during the first year of age by cell-free translation of lens RNA in a reticulocyte lysate, RNA blot (Northern) hybridization, and in situ hybridization. The hybridization was performed with a nick-translated, cloned δ-crystallin cDNA (pδCr2). δ-Crystallin mRNA was present in the lens until 3 months of age and disappeared between the third and fifth month after hatching. The in situ hybridization experiments indicated that the δ-crystallin mRNA was present throughout the lens fiber mass until 1 month after hatching and was greatly reduced in the cortical fiber cells thereafter. In contrast to earlier stages, then, the cortical fiber cells differentiating at the lens equator after about 1 month of age do not accumulate δ-crystallin mRNA. The data also indicate that the maximal half-life of functional δ-crystallin mRNA in the posthatched chicken lens is about 2 months.     

Rat α2u-globulin mRNA expression in the preputial gland

Rat _2u-globulin and the mouse major urinary proteins (MUP) are encoded by homologous multigene families whose members exhibit diverse tissue-specific, developmental, and hormonal controls of expression. Although their patterns of expression and hormonal control appear to be very similar in many respects, we have found high levels of _2u-globulin mRNA in rat preputial glands, whereas MUP mRNA could not be detected in the male mouse preputial gland. Male and female rat preputial have similar concentrations of _2u-globulin mRNA, suggesting an absence of endocrine regulation as occurs in the liver and lachrymal glands. Two-dimensional polyacrylamide gel electrophoresis of proteins encoded by hybrid-selected _2u-globulin mRNA indicates that the liver and lachrymal translation products have different mobilities. However, many of the preputial gland products comigrate with most or all of the liver and lachrymal products. Among the possibilities suggested by these results is that _2u-globulin genes expressed in liver and lachrymal glands under endocrine control are also expressed constitutively in the preputial gland.This work was supported by Public Health Service Research Grant GM25023 from the National Institutes of Health.     

Determination of the primary sequence of the duck αD globin mRNA and comparison of all adult duck and chick globin mRNA sequences

The nucleotide sequence of the duck α^D globin mRNA was determined. Its main feature is an exceptionally short 3′ non-coding segment of only 46 nucleotides, placed after the coding sequence of 141 codons. The last of the 6 adult globin mRNA of duck and chicken being thus sequenced, a comparison of all their features has become possible. Comparing the duck α^D mRNA to the related sequence in the chicken, we found greater homology than comparing it to the linked α^A globin sequence in the same species. Extensive homology can be found for a same globin chain α^A, α^D or β in between different avian species including also the goose and the ostrich; the avian α globin chains show a lower degree of sequence conservation in between species than the β chains. In contrast, within one species the three globin sequences have further diverged. The divergence between the α^A and α^D globin within a same species point to individual functional specificity and hence independent evolution and suggest that a mechanism of ‘gene conversion’ did not operate in between the avian α globin genes. Two segments of the amino acid sequence which we named ‘A^α’ and ‘B^α’ remain homologous in all avian α globins; two other regions ‘A^β’ and ‘B^β’ are identical in between the β globins. Segment A is placed at the 5′ end of exon II, and segment B at the 3′ end of the same exon; some amino acids in those segments are involved in the Heme binding site. Being almost identical in all know mammalian and avian globins of the α respectively the β type, regions A and B seem to represent the best conserved sequences in adult globin mRNA maintained during the divergence of species.     

No role of the 5′ untranslated region of ornithine decarboxylase mRNA in the feedback control of the enzyme

The polyamines are ubiquitous in nature and appear to fulfil several important functions, mostly related to growth, in the cell. The first, and often rate-limiting, step in the biosynthesis of the polyamines is catalysed by ornithine decarboxylase (ODC), which is subject to a variety of control mechanisms. The polyamines exert a strong feedback regulation of the expression - as well as the degradation of the enzyme. The regulation of ODC expression appears to occur at the translational level. The ODC mRNA contains a long GC-rich 5 untranslated region (UTR), which has been demonstrated to hamper the translation of the mRNA. However, it has not yet been conclusively established whether this part of the mRNA fulfils any function in relation to the polyamine-mediated control of ODC synthesis. In the present study, we have used stable transgenic CHO cells, expressing either full-length ODC mRNA or 5 UTR-truncated ODC mRNA, to elucidate the role, if any, of the 5 UTR in the translational regulation of the enzyme by polyamines. No differences in regulatory properties were observed between the cells expressing the full-length ODC mRNA and those expressing the ODC mRNA devoid of most the 5 UTR. The cell lines down-regulated ODC (synthesis as well as activity) to the same extent upon exposure to an excess of polyamines, demonstrating that the feedback control of ODC mRNA translation occurs by a mechanism independent of the major part of the 5 UTR of the ODC mRNA.     

Template Location on the Human Ribosome: Environment of the mRNA Nucleotide Adjacent to the A-Site Codon on the 3′-Side

The 18S rRNA nucleotides close to the template nucleotide adjacent to the 80S ribosomal A-site codon on the 3′-end (i.e., the nucleotide in position +7 relative to the first nucleotide of the P-site codon) were identified using the affinity crosslinking approach. For this purpose, the photoreactive mRNA analogues with a perfluorophenylazide group attached through various linkers to the uridine C5, 3′-terminal phosphate or guanosine N7 were used. The position of the mRNA analogues on the ribosome was preset using tRNA^Phe, which recognized the phenylalanine codon directed to the P-site. An analysis of the rRNAs isolated from the irradiated complexes of 80S ribosomes showed that all the analogues are almost equally crosslinked to the 18S rRNA nucleotides we attributed to the A-site codon environment: namely, to nucleotides A1823, A1824, and A1825 of the 3′-minidomain and to the 620–630 fragment of the 18S rRNA 5′-domain. In addition, we identified a new component of the mRNA binding site of human ribosomes, nucleotide C1698, belonging to the 18S rRNA 3′-minidomain, using analogues bearing a perfluorophenylazide group on uridine and guanine residues.__________Translated from Bioorganicheskaya Khimiya, Vol. 31, No. 3, 2005, pp. 295–302.Original Russian Text Copyright © 2005 by Demeshkina, Styazhkina, Bulygin, Repkova, Ven’yaminova, Karpova.     

Cloning and tissue distribution of Leptin mRNA in the pig∗

Abstract

The sequence of the pig ob cDNA, which codes for the protein leptin, has been determined by screening a pig adipose cDNA library with an RT‐PCR amplified cDNA fragment of this gene. The 501 bp ob cDNA has 89% identity to the human ob cDNA, 92% identity to the bovine ob cDNA, 84% identity to the mouse ob cDNA and 84% identity to the rat ob cDNA. At the amino acid level, pig leptin which codes for a protein with a predicted molecular weight of 18,661‐dalton, has 86% identity to human leptin, 93% identity to bovine leptin, 84% identity to rat leptin and 84% identity to mouse leptin. RT‐PCR screening of RNA isolated from pig adipose, skeletal muscle, cardiac muscle, pancreas, stomach, kidney, spleen and jejunum detected ob mRNA only in adipose tissue; Northern blots with an ob cDNA probe identified a 4.0 kb species in adipose tissue. The conservation of sequence and expression pattern of leptin in the pig reported here indicates that as in other species, this protein likely plays an important role in controlling food intake and fat deposition in the pig.     

Influenza Virus mRNA Translation Revisited: Is the eIF4E Cap-Binding Factor Required for Viral mRNA Translation?

Influenza virus mRNAs bear a short capped oligonucleotide sequence at their 5' ends derived from the host cell pre-mRNAs by a "cap-snatching" mechanism, followed immediately by a common viral sequence. At their 3' ends, they contain a poly(A) tail. Although cellular and viral mRNAs are structurally similar, influenza virus promotes the selective translation of its mRNAs despite the inhibition of host cell protein synthesis. The viral polymerase performs the cap snatching and binds selectively to the 5' common viral sequence. As viral mRNAs are recognized by their own cap-binding complex, we tested whether viral mRNA translation occurs without the contribution of the eIF4E protein, the cellular factor required for cap-dependent translation. Here, we show that influenza virus infection proceeds normally in different situations of functional impairment of the eIF4E factor. In addition, influenza virus polymerase binds to translation preinitiation complexes, and furthermore, under conditions of decreased eIF4GI association to cap structures, an increase in eIF4GI binding to these structures was found upon influenza virus infection. This is the first report providing evidence that influenza virus mRNA translation proceeds independently of a fully active translation initiation factor (eIF4E). The data reported are in agreement with a role of viral polymerase as a substitute for the eIF4E factor for viral mRNA translation.     

A Synonymous Single Nucleotide Polymorphism in ΔF508 CFTR Alters the Secondary Structure of the mRNA and the Expression of the Mutant Protein

Recent advances in our understanding of translational dynamics indicate that codon usage and mRNA secondary structure influence translation and protein folding. The most frequent cause of cystic fibrosis (CF) is the deletion of three nucleotides (CTT) from the cystic fibrosis transmembrane conductance regulator (CFTR) gene that includes the last cytosine (C) of isoleucine 507 (Ile507ATC) and the two thymidines (T) of phenylalanine 508 (Phe508TTT) codons. The consequences of the deletion are the loss of phenylalanine at the 508 position of the CFTR protein (ΔF508), a synonymous codon change for isoleucine 507 (Ile507ATT), and protein misfolding. Here we demonstrate that the ΔF508 mutation alters the secondary structure of the CFTR mRNA. Molecular modeling predicts and RNase assays support the presence of two enlarged single stranded loops in the ΔF508 CFTR mRNA in the vicinity of the mutation. The consequence of ΔF508 CFTR mRNA “misfolding” is decreased translational rate. A synonymous single nucleotide variant of the ΔF508 CFTR (Ile507ATC), that could exist naturally if Phe-508 was encoded by TTC, has wild type-like mRNA structure, and enhanced expression levels when compared with native ΔF508 CFTR. Because CFTR folding is predominantly cotranslational, changes in translational dynamics may promote ΔF508 CFTR misfolding. Therefore, we propose that mRNA “misfolding” contributes to ΔF508 CFTR protein misfolding and consequently to the severity of the human ΔF508 phenotype. Our studies suggest that in addition to modifier genes, SNPs may also contribute to the differences observed in the symptoms of various ΔF508 homozygous CF patients.     

Phosphorylation regulates the Star-PAP-PIPKIα interaction and directs specificity toward mRNA targets

Star-PAP is a nuclear non-canonical poly(A) polymerase (PAP) that shows specificity toward mRNA targets. Star-PAP activity is stimulated by lipid messenger phosphatidyl inositol 4,5 bisphoshate (PI4,5P₂) and is regulated by the associated Type I phosphatidylinositol-4-phosphate 5-kinase that synthesizes PI4,5P₂ as well as protein kinases. These associated kinases act as coactivators of Star-PAP that regulates its activity and specificity toward mRNAs, yet the mechanism of control of these interactions are not defined. We identified a phosphorylated residue (serine 6, S6) on Star-PAP in the zinc finger region, the domain required for PIPKIα interaction. We show that S6 is phosphorylated by CKIα within the nucleus which is required for Star-PAP nuclear retention and interaction with PIPKIα. Unlike the CKIα mediated phosphorylation at the catalytic domain, Star-PAP S6 phosphorylation is insensitive to oxidative stress suggesting a signal mediated regulation of CKIα activity. S6 phosphorylation together with coactivator PIPKIα controlled select subset of Star-PAP target messages by regulating Star-PAP-mRNA association. Our results establish a novel role for phosphorylation in determining Star-PAP target mRNA specificity and regulation of 3′-end processing.     

G-quadruplexes within prion mRNA: the missing link in prion disease?

Cellular ribonucleic acid (RNA) plays a crucial role in the initial conversion of cellular prion protein PrP^C to infectious PrP^Sc or scrapie. The nature of this RNA remains elusive. Previously, RNA aptamers against PrP^C have been isolated and found to form G-quadruplexes (G4s). PrP^C binding to G4 RNAs destabilizes its structure and is thought to trigger its conversion to PrP^Sc. Here it is shown that PrP messenger RNA (mRNA) itself contains several G4 motifs, located in the octarepeat region. Investigation of the RNA structure in one of these repeats by circular dichroism, nuclear magnetic resonance and ultraviolet melting studies shows evidence of G4 formation. In vitro translation of full-length PrP mRNA, naturally harboring five consecutive G4 motifs, was specifically affected by G4-binding ligands, lending support to G4 formation in PrP mRNA. A possible role of PrP binding to its own mRNA and the role of anti-prion drugs, many of which are G4-binding ligands, in prion disease are discussed.     

Protein S3 in the human 80S ribosome adjoins mRNA 3′ of the A-site codon

The protein environment of mRNA 3′ of the A-site codon (the decoding site) in the human 80S ribosome was studied using a set of oligoribonucleotide derivatives bearing a UUU triplet at the 5′-end and a perfluoroarylazide group at one of the nucleotide residues 3′ of this triplet. Analogues of mRNA were phased into the ribosome using binding at the tRNA^Phe P-site, which recognizes the UUU codon. Mild UV irradiation of ribosome complexes with tRNA^Phe and mRNA analogues resulted in the predominant crosslinking of the analogues with the 40S subunit components, mainly with proteins and, to a lesser extent, with rRNA. Among the 40S subunit ribosomal proteins, the S3 protein was the main target for modification in all cases. In addition, minor crosslinking with the S2 protein was observed. The crosslinking with the S3 and S2 proteins occurred both in ternary complexes and in the absence of tRNA. Within ternary complexes, crosslinking with S15 protein was also found, its efficiency considerably falling when the modified nucleotide was moved from positions +5 to +12 relative to the first codon nucleotide in the P-site. In some cases, crosslinking with the S30 protein was observed; it was most efficient for the derivative containing a photoreactive group at the +7 adenosine residue. The results indicate that the S3 protein in the human ribosome plays a key role in the formation of the mRNA binding site 3′ of the codon in the decoding site.