Computer System mRNA-FAST (mRNA Function,Activity, STructure)

Computer system mRNA-FAST (mRNA Function, Activity, STructure; http://wwwmgs.bionet.nsc.ru/mgs/dbases/trsig/) is described. The system has been developed to analyze nucleotide sequences of mRNA and to measure their essential properties. The system compiles the data base on translation signals including nucleotide sequences of the regulatory regions with structural and experimental information on their specific activities. It also contains programs to search for local homology between mRNA and translation signals, to search for potential signals basing on analysis of the oligonucleotide dictionaries, and to model secondary RNA structure. Possible applications of the system mRNA-FAST are discussed.     

Protein structure and the sequential structure of mRNA: α-Helix and β-sheet signals at the nucleotide level

A direct comparison of experimentally determined protein structures and their corresponding protein coding mRNA sequences has been performed. We examine whether real world data support the hypothesis that clusters of rare codons correlate with the location of structural units in the resulting protein. The degeneracy of the genetic code allows for a biased selection of codons which may control the translational rate of the ribosome, and may thus in vivo have a catalyzing effect on the folding of the polypeptide chain. A complete search for GenBank nucleotide sequences coding for structural entries in the Brookhaven Protein Data Bank produced 719 protein chains with matching mRNA sequence, amino acid sequence, and secondary structure assignment. By neural network analysis, we found strong signals in mRNA sequence regions surrounding helices and sheets. These signals do not originate from the clustering of rare codons, but from the similarity of codons coding for very abundant amino acid residues at the N- and C-termini of helices and sheets. No correlation between the positioning of rare codons and the location of structural units was found. The mRNA signals were also compared with conserved nucleotide features of 16S-like ribosomal RNA sequences and related to mechanisms for maintaining the correct reading frame by the ribosome. © 1996 Wiley-Liss, Inc.     

Sounds of silence: synonymous nucleotides as a key to biological regulation and complexity

Messenger RNA is a key component of an intricate regulatory network of its own. It accommodates numerous nucleotide signals that overlap protein coding sequences and are responsible for multiple levels of regulation and generation of biological complexity. A wealth of structural and regulatory information, which mRNA carries in addition to the encoded amino acid sequence, raises the question of how these signals and overlapping codes are delineated along non-synonymous and synonymous positions in protein coding regions, especially in eukaryotes. Silent or synonymous codon positions, which do not determine amino acid sequences of the encoded proteins, define mRNA secondary structure and stability and affect the rate of translation, folding and post-translational modifications of nascent polypeptides. The RNA level selection is acting on synonymous sites in both prokaryotes and eukaryotes and is more common than previously thought. Selection pressure on the coding gene regions follows three-nucleotide periodic pattern of nucleotide base-pairing in mRNA, which is imposed by the genetic code. Synonymous positions of the coding regions have a higher level of hybridization potential relative to non-synonymous positions, and are multifunctional in their regulatory and structural roles. Recent experimental evidence and analysis of mRNA structure and interspecies conservation suggest that there is an evolutionary tradeoff between selective pressure acting at the RNA and protein levels. Here we provide a comprehensive overview of the studies that define the role of silent positions in regulating RNA structure and processing that exert downstream effects on proteins and their functions.     

Higher order structures of the 5'-proximal region decrease the efficiency of translation of the porcine pro-opiomelanocortin mRNA

The SP6 polymerase/promoter system was used to synthesize porcine pro-opiomelanocortin mRNAs with nucleotide sequence deletions in the 5'- as well as 3'-untranslated and coding regions. The translational efficiency of the mutant mRNAs was evaluated by cell-free translation or by monitoring the rate and extent of ribosome binding in the presence of sparsomycin. The results of these experiments indicate that specific nucleotide sequences in the 5'-untranslated and coding regions of the pro-opiomelanocortin mRNA decrease its rate of translation. Structure mapping of the mRNA with double-strand and single-strand specific nucleases suggests that these sequences can form stable secondary structures.     

Selection and characterization of randomly produced mutants of gene V protein of bacteriophage M13.

Gene V protein of bacteriophage Ff (M13, f1, fd) is a master regulator of phage DNA replication and phage mRNA translation. It exerts these two functions by binding to single-stranded viral DNA or to specific sequences in the 5' ends of its target mRNAs, respectively. To study the structure/function relationship of gene V protein, M13 gene V was inserted in a phagemid expression vector and a library of missense and nonsense mutants was constructed by random chemical mutagenesis. Phagemids encoding gene V proteins with decreased biological activities were selected and the nucleotide sequences of their gene V fragments were determined. Furthermore, the mutant proteins were characterized both with respect to their ability to inhibit the production of phagemid DNA transducing particles and their ability to repress the translation of a chimeric lacZ reporter gene whose expression is controlled by the promoter and translational initiation signals of M13 gene II. From the data obtained, it can be deduced that the mechanism by which gene V protein binds to single-stranded DNA differs from the mechanism by which it binds to its target sequence in the gene II mRNA.     

A completely in?vitro system for obtaining scFv using mRNA display, PCR, direct sequencing, and wheat embryo cell-free translation

Using mRNA display followed by in vitro sequencing and translation, a complete in vitro system for obtaining scFv has been developed. An mRNA display library for synthetic scFv was panned against human TNF receptor (TNFR). The nucleotide portion of the enriched molecules was subjected to limiting dilution, and PCR-amplified. Three of the proteins encoded by the amplified fragments were synthesized in a wheat embryo (WE) cell-free system using a batch method. They were shown to bind TNFR by ELISA. One of their sequences was identified in vitro. The identified clone was further synthesized at approx. 0.5 mg/ml reaction mixture in a WE system with dialysis as a totally soluble protein.     

A method for identifying splice sites and translation start sites in human genomic sequences

We describe a new method for identifying the sequences that signal the start of translation, and the boundaries between exons and introns (donor and acceptor sites) in human mRNA. According to the mandatory keyword, ORGANISM, and feature key, CDS, a large set of standard data for each signal site was extracted from the ASCII flat file, gbpri.seq, in the GenBank release 108.0. This was used to generate the scoring matrices, which summarize the sequence information for each signal site. The scoring matrices take into account the independent nucleotide frequencies between adjacent bases in each position within the signal site regions, and the relative weight on each nucleotide in proportion to their probabilities in the known signal sites. Using a scoring scheme that is based on the nucleotide scoring matrices, the method has great sensitivity and specificity when used to locate signals in uncharacterized human genomic DNA. These matrices are especially effective at distinguishing true and false sites.     

Selection of AUG initiation codons differs in plants and animals.

The influence of the nucleotide at position -3 relative to the AUG initiation codon on the initiation of protein synthesis was studied in two different in vitro translation systems using synthetic mRNAs. The four mRNAs, transcribed from cDNAs directed by an SP6 promoter, were identical except for mutations at nucleotide -3. In each case, translation of mRNAs produced a single protein of Mr = 12,600. Relative translational efficiencies showed a hierarchy in the reticulocyte lysate system (100, 85, 61 and 38% for A, G, U and C in position -3, respectively) but no differences in the wheat germ system. Differential mRNA degradation or polypeptide chain elongation were excluded as causes of the differences observed in translation in the reticulocyte lysate. mRNA competition increased the differences observed in translational efficiencies in reticulocyte lysate but showed no effect in wheat germ. Analysis of 61 plant and 209 animal mRNA sequences revealed qualitative and quantitative differences between the consensus sequences surrounding AUG initiation codons. Whereas the consensus sequence for animals was CACCAUG that for plants was AACAAUGGC. Both the structural and functional findings suggest that the factors which select AUG initiation codons in plants and animals differ significantly.     

A downstream CA repeat sequence increases translation from leadered and unleadered mRNA in Escherichia coli

When placed downstream of the start codon, multimers of the dinucleotide CA stimulated translation from lacZ, gusA and neo mRNAs in the presence or absence of an untranslated leader sequence. Enhanced expression in the absence of a leader and Shine-Dalgarno sequence indicated that stimulation by CA multimers was independent of translation signals contained within the untranslated leader. Multimers of CA stimulated a significantly higher level of lacZ expression than multimers of individual C or A nucleotides. Translation levels increased as the number of CA repeats increased; fewer multimers were required for enhanced expression from leadered mRNA than from mRNA that was deleted for its leader sequence. Addition of down-stream CA multimers increased the ribosome binding strength of mRNA in vitro and the amount of full-length mRNA in vivo, suggesting that the enhanced expression resulted from translation of a more abundant functional message containing a stronger ribosome binding site. The presence of downstream CA-rich sequences, occurring naturally in several Escherichia coli genes, might contribute to translation of other mRNAs. Addition of CA multimers might represent a general mechanism for increasing expression from genes of interest.     

Leader sequences of eukaryotic mRNA can be simultaneously bound to initiating 80S ribosome and 40S ribosomal subunit

Binding of mRNA leader sequences to ribosomes was studied in conditions of a cell-free translation system based on wheat germ extract. Leader sequence of TMV mRNA (the so-called omega-RNA sequence) was able to bind simultaneously 80S ribosome and 40S ribosomal subunit. It was found that nucleotide substitutions in omega-RNA resulting in destabilization of RNA structure have no effect on the complex formation with both 80S ribosome and 40S ribosomal subunit. Leader sequence of globin mRNA is also able to form a similar joint complex. It is supposed that the ability of mRNA leader sequences to bind simultaneously 80S ribosome and 40S subunit is independent of leader nature and may reflect previously unknown eukaryotic mechanisms of translation initiation.     

Diversity of preferred nucleotide sequences around the translation initiation codon in eukaryote genomes

Understanding regulatory mechanisms of protein synthesis in eukaryotes is essential for the accurate annotation of genome sequences. Kozak reported that the nucleotide sequence GCCGCC(A/G)CCAUGG (AUG is the initiation codon) was frequently observed in vertebrate genes and that this 'consensus' sequence enhanced translation initiation. However, later studies using invertebrate, fungal and plant genes reported different 'consensus' sequences. In this study, we conducted extensive comparative analyses of nucleotide sequences around the initiation codon by using genomic data from 47 eukaryote species including animals, fungi, plants and protists. The analyses revealed that preferred nucleotide sequences are quite diverse among different species, but differences between patterns of nucleotide bias roughly reflect the evolutionary relationships of the species. We also found strong biases of A/G at position -3, A/C at position -2 and C at position +5 that were commonly observed in all species examined. Genes with higher expression levels showed stronger signals, suggesting that these nucleotides are responsible for the regulation of translation initiation. The diversity of preferred nucleotide sequences around the initiation codon might be explained by differences in relative contributions from two distinct patterns, GCCGCCAUG and AAAAAAAUG, which implies the presence of multiple molecular mechanisms for controlling translation initiation.     

Translation inhibition of the Salmonella fliC gene by the fliC 5' untranslated region, fliC coding sequences, and FlgM

The 5'-untranslated region (5'UTR) of the fliC flagellin gene of Salmonella contains sequences critical for efficient fliC mRNA translation coupled to assembly. In a previous study we used targeted mutagenesis of the 5' end of the fliC gene to isolate single base changes defective in fliC gene translation. This identified a predicted stem-loop structure, SL2, as an effector of normal fliC mRNA translation. A single base change (-38C:U) in the fliC 5'UTR resulted in a mutant that is defective in fliC mRNA translation and was chosen for this study. Motile (Mot+) revertants of the -38C:T mutant were isolated and characterized, yielding several unexpected results. Second-site suppressors that restored fliC translation and motility included mutations that disrupt a RNA duplex stem formed between RNA sequences in the fliC 5'UTR SL2 region (including a precise deletion of SL2) and bases early within the fliC-coding region. A stop codon mutation at position 80 of flgM also suppressed the -38C:T motility defect, while flgM mutants defective in anti-sigma28 activity had no effect on fliC translation. One remarkable mutation in the fliC 5'UTR (-15G:A) results in a translation defect by itself but, in combination with the -38C:U mutation, restores normal translation. These results suggests signals intrinsic to the fliC mRNA that have both positive and negative effects on fliC translation involving both RNA structure and interacting proteins.     

Molecular cloning of cDNAs from androgen-independent mRNA species of DBA/2 mouse sub-maxillary glands

cDNA libraries have been constructed from mRNAs isolated from mature male DBA/2 mouse submaxillary glands. Several recombinant plasmids have been assigned to particular mRNA species and their in vitro translation products by HART and hybrid selection. Clones containing copies of two abundant mRNA species that showed no sexual dimorphism were selected for detailed characterisation. Nucleotide sequences determined from one series of clones define an 850 nucleotide mRNA encoding a polypeptide of 16.5 kd having an N-terminal signal sequence, an acidic core and four glycosylation sites. A second family of clones correspond to an mRNA of 800 nucleotides, the sequence of which can be interpreted as coding for an intracellular protein of 14.7 kd. Computer searches of protein and nucleic acid sequences have not revealed the identity of either of these submaxillary gland products.     

Binding proteins for mRNA localization and local translation, and their dysfunction in genetic neurological disease

Neurons utilize mRNA transport and local translation as a means to influence development and plasticity. The molecular mechanisms for this mRNA sorting involve the recognition of cis-acting sequences by distinct mRNA binding proteins that have a dual role, acting in both mRNA transport and translational regulation. Other proteins play a part in the assembly of messenger ribonucleoprotein complexes into transport granules. mRNA binding proteins are crucial targets of phosphorylation signals that regulate local translation. Fragile X syndrome and spinal muscular atrophy have emerged as two genetic neurological diseases that could result, in part, from impaired assembly, localization, and translational regulation of these messenger ribonucleoproteins.     

Further characterization of isolated presumptive euchromatin fractions of mouse hepatoma cells utilizing a cDNA probe complementary to the homologous poly(A)+ mRNA

Poly(A)+ mRNA from mouse hepatoma ascites cell cytoplasm is characterized by three frequency classes: an abundant frequency class of a limited number of different nucleotide sequences, a less abundant frequency class of a larger number of different nucleotide sequences, and a rare frequency class containing a high number of different nucleotide sequences. [3H]cDNA synthesized on this poly(A)+ mRNA template hybridizes with some of the DNAs of the putative transcribable euchromatin fraction at a significantly faster rate than with total DNA if residual contaminating RNA is not removed. Following NaOH incubation to remove such RNA, the cDNA probe hybridized with essentially the same rate to the euchromatin fractions and total DNA. Nick translation of the nuclease-sensitive sequences of chromatin demonstrated that, even with limited nuclease digestion, the excised sequences rapidly converted to small oligonucleotides. The nick-translatable, small chromatin segments showed no enrichment for transcribable sequences. Chromatin segments, which distribute to the 50S-70S glycerol gradient fractions and which satisfy several of the presumptive criteria for enrichment for transcribable sequences, therefore show no enrichment for sequences complementary to the cDNA for poly(A)+ mRNA.