An algorithm for the display of nucleic acid secondary structure

Canada's contributions to RNA research: past, present, and future perspectives

The field of RNA research has provided profound insights into the basic mechanisms modulating the function and adaption of biological systems. RNA has also been at the center stage in the development of transformative biotechnological and medical applications, perhaps most notably was the advent of mRNA vaccines that were critical in helping humanity through the Covid-19 pandemic. Unbeknownst to many, Canada boasts a diverse community of RNA scientists, spanning multiple disciplines and locations, whose cutting-edge research has established a rich track record of contributions across various aspects of RNA science over many decades. Through this position paper, we seek to highlight key contributions made by Canadian investigators to the RNA field, via both thematic and historical viewpoints. We also discuss initiatives underway to organize and enhance the impact of the Canadian RNA research community, particularly focusing on the creation of the not-for-profit organization RNA Canada ARN. Considering the strategic importance of RNA research in biology and medicine, and its considerable potential to help address major challenges facing humanity, sustained support of this sector will be critical to help Canadian scientists play key roles in the ongoing RNA revolution and the many benefits this could bring about to Canada.

RNA Visualization: Relevance and the Current State-of-the-Art Focusing on Pseudoknots

RNA visualization is crucial in order to understand the relationship that exists between RNA structure and its function, as well as the development of better RNA structure prediction algorithms. However, in the context of RNA visualization, one key structure remains difficult to visualize: Pseudoknots. Pseudoknots occur in RNA folding when two secondary structural components form base-pairs between them. The three-dimensional nature of these components makes them challenging to visualize in two-dimensional media, such as print media or screens. In this review, we focus on the advancements that have been made in the field of RNA visualization in two-dimensional media in the past two decades. The review aims at presenting all relevant aspects of pseudoknot visualization. We start with an overview of several pseudoknotted structures and their relevance in RNA function. Next, we discuss the theoretical basis for RNA structural topology classification and present RNA classification systems for both pseudoknotted and non-pseudoknotted RNAs. Each description of RNA classification system is followed by a discussion of the software tools and algorithms developed to date to visualize RNA, comparing the different tools' strengths and shortcomings.

Evolution and structural organisation of mitochondrial DNA control region of myiasis-causing flies

This study reports the molecular characterization of the mtDNA control region (called the A+T-rich region in insects) of five dipteran species which cause myiasis: Cochliomyia hominivorax Coquerel, Cochliomyia macellaria Fabricius, Chrysomya megacephala Fabricius, Lucilia eximia Wiedemann (Diptera: Calliphoridae) and Dermatobia hominis Linnaeus Jr (Diptera: Oestridae). The control region in these species varies in length from 1000 to 1600 bp. Two structural domains with specific evolutionary patterns were identified. These were (1) conserved sequence blocks containing primary sequence motifs, including dinucleotide pyrimidine-purine series and long T-stretches, located at the 5' end adjacent to the tRNA(Ile) gene and (2) a hypervariable domain at the 3' end characterized by increased nucleotide divergence and size variation. A high frequency of A<-->T transversions at nucleotide substitution level indicated directional mutation pressure. The phylogenetic usefulness of the insect control region is discussed.

Glanzmann thrombasthenia. Cooperation between sequence variants in cis during splice site selection

Glanzmann thrombasthenia (GT), an autosomal recessive bleeding disorder, results from abnormalities in the platelet fibrinogen receptor, GP(IIb)-IIIa (integrin alpha(IIb)beta3). A patient with GT was identified as homozygous for a G-->A mutation 6 bp upstream of the GP(IIIa) exon 9 splice donor site. Patient platelet GP(IIIa) transcripts lacked exon 9 despite normal DNA sequence in all of the cis-acting sequences known to regulate splice site selection. In vitro analysis of transcripts generated from mini-gene constructs demonstrated that exon skipping occurred only when the G-->A mutation was cis to a polymorphism 116 bp upstream, providing precedence that two sequence variations in the same exon which do not alter consensus splice sites and do not generate missense or nonsense mutations, can affect splice site selection. The mutant transcript resulted from utilization of a cryptic splice acceptor site and returned the open reading frame. These data support the hypothesis that pre-mRNA secondary structure and allelic sequence variants can influence splicing and provide new insight into the regulated control of RNA processing. In addition, haplotype analysis suggested that the patient has two identical copies of chromosome 17. Markers studied on three other chromosomes suggested this finding was not due to consanguinity. The restricted phenotype in this patient may provide information regarding the expression of potentially imprinted genes on chromosome 17.

The identification and characterization of a break within the large subunit ribosomal RNA of Trichinella spiralis: comparison of gap sequences within the genus

A break was identified in the large subunit ribosomal RNA of Trichinella spiralis that results in its dissociation into 2 smaller fragments of approximately equal length. The approximate location of the break within the encoding gene was mapped from subcloned rDNA fragments by S1 protection experiments. The boundaries of the break were determined by cDNA primer extension and S1 nuclease protection assays. The excised fragment (gap sequence) was localized to expansion segment 5 within domain IV from which 86 bases are removed during the excision process. The gap region is flanked by the consensus sequence CGAAAG; however, comparison of expansion segment 5 sequences from T. spiralis, T. nativa, T. nelsoni and T. pseudospiralis, all of which undergo 'gap processing', demonstrates significant size and sequence heterogeneity and provides little evidence for additional consensus sequences which could be implicated in gap processing.

Archetypical features in tRNA families

A compilation of known tRNA, and tRNA gene sequences from archaebacteria, eubacteria, and eukaryotes permits the construction of tRNA cloverleafs which show conserved structural elements for each tRNA family. Positions conserved across the three kingdoms are thought to represent archetypical features of tRNAs which preceded the divergence of these kingdoms.

The S segment of the Germiston virus RNA genome can code for three proteins

The complete sequence of the S segment of Germiston bunyavirus has been determined from plasmids containing S cDNA inserts. The S segment is 980 nucleotides long with the first 15 bases at the 3' end complementary to the first 15 bases at the 5' end. Three overlapping open reading frames (ORF) were identified in the viral complementary RNA strand. The first ORF codes for a polypeptide of 233 amino acids (Mr 26,600) which is the nucleoprotein N. The second ORF codes for a polypeptide of 109 amino acids (Mr 11,800) which corresponds to the NSS protein, also called p12. Following this ORF, in the same frame, a third ORF which could encode a polypeptide of 75 amino acids was identified. Such a polypeptide has not yet been detected in infected cells. The N and NSS proteins of Germiston virus were compared with the corresponding proteins of La Crosse, snowshoe hare, and Aino viruses, and show a high extent of homology.

Cloning of bovine P1 protamine cDNA and the evolution of vertebrate P1 protamines

A bovine P1 protamine cDNA from a bull testis cDNA library was isolated utilizing a series of oligonucleotide probes. Sequence analysis showed that the cloned cDNA insert extended 317 bp to the poly(A) tail. The 51-residue 6750-dalton protamine primary translated protein is encoded within a 156-bp segment. The protamine sequence predicted from the cDNA sequence differs from that previously reported for the amino acid sequence of bovine protamine P1 by the insertion of the tripeptide Cys-Arg-Arg from residues 39-41 in the carboxy-terminal region of the mature protein. Consistent with previous hybridization analysis, nucleotide sequence comparisons showed that trout protamine cDNA was more closely related to that of bovine than to that of mouse. However, bovine P1 protamine cDNA shared greater sequence homology with mouse P1. A common nucleotide sequence of 30 bp is conserved among all three of these species. Primer extension analysis revealed that, as with trout protamine mRNAs, the majority of the untranslated portion of the mRNA lies 3' to the coding segment. Comparisons of their mRNA secondary structures by computer modeling indicate that the mRNAs fold back onto themselves, producing similar, extensively hydrogen-bonded, convoluted forms. These models support the view that translational regulation of protamine mRNA may be partially dependent on secondary structure. Southern analysis suggests that the bovine protamine P1 gene is not sex-linked and is present as one (or relatively few) copy within the bovine genome.