Effect of spermidine on the conformation of bacteriophage MS2 RNA. Electron microscopy and computer modeling

The structure of single-stranded RNA from the bacteriophage MS2 has been examined by electron microscopy in the presence of the polyamine spermidine. The molecules are found in two alternate conformations. The first of these can be characterized as a cruciform structure composed of three large loops approximately 500 to 700 nucleotides in size. The interior of the molecule has extensive base-paired regions which connect distant regions of the molecule; the farthest being 2500 nucleotides apart. In the second conformation, the molecules appear rod-like. Two of the large loops disappear, and these regions form, instead, extensive long-range helices. Computer modeling has been employed to explore the base-pairing potential of the sequence of bacteriophage MS2 RNA. Double-stranded regions identified by electron microscopy are shown to occur in local G + C-rich stretches of the RNA. Detailed models have been calculated for two regions of long-range contact. One of these includes the ribosome-binding site for the viral coat protein gene. The results are discussed in the context of the known role of RNA structure in the regulation of viral gene expression.     

RNA synthesis of vesicular stomatitis virus. VIII. Oligonucleotides of the structural genes and mRNA.

The single-stranded RNA genome of vesicular stomatitis virus (VSV, Indiana serotype, San Juan strain) yields approx. 75 RNase T1-resistant oligonucleotides ranging in size from 10 to 50 bases. Each of the five structural genes, isolated as duplex RNA molecules hybridized to complementary mRNA, contains two or more of these large oligonucleotides. One of the oligonucleotides is identified as part of the non-coding region near the 3' end of the genome. Comparison of these results with others indicate that the RNA sequence of VSV is apparently stable in the laboratory but not in the wild. RNase T1-resistant oligonucleotides are also shown for all five VSV mRN species. Whether the mRNA for these digestions are are isolated from duplex RNA molecules or as single-stranded RNA species, the oligonucleotide patterns for each mRNA are virtually identical, indicating that each mRNA is transcribed from contiguous sequences on the genome. Comparison with published oligonucleotide patterns obtained from other isolates of VSV or from VSV deletion mutants indicate that identity and changes in their genome structure can be correlated with specific structural genes.     

Intercalation conformations in single- and double-stranded nucleic acids

Two regions in the crystal structure of yeast phenylalanine tRNA, where single-stranded loops interact by intercalation, have been examined in detail. There are four examples of a nucleotide base from one loop intercalating between two sequential bases of another loop in these two regions. These four dinucleoside phosphate conformations serve as models for intercalation in single-stranded nucleic acids. Double-stranded DNA and RNA polymers were constructed by computer model building methods, which incorporated the dinucleoside phosphate conformations found in these single-stranded, intercalation regions in otherwise standard double-helices. The results suggest that it is unlikely that there is a unique intercalation geometry for either single- or double-stranded nucleic acids, but that nucleic acids may assume one of a variety of intercalation geometries which will best accommodate a particular intercalating agent for a particular base sequence.     

1,10-Phenanthroline-copper, a footprinting reagent for single-stranded regions of RNAs.

The 1,10-phenanthroline-cuprous complex (OP-Cu) with hydrogen peroxide as a coreactant nicks the single-stranded loops and bulges of RNA stem-loop structures more rapidly than the double-stranded stems. This chemical nuclease is therefore a useful footprinting reagent for these regions and can be used to monitor both intramolecular and intermolecular hybridization of single-stranded domains. The formation of A-form structures characteristic of either RNA-RNA or RNA-DNA duplexes inhibits scission because it blocks the binding site of the coordination complex in single-stranded loops and not because the oxidatively sensitive hydrogens of the ribose moiety are blocked. The C-4' and C-1' hydrogens are accessible to solvent in A-structures.     

Naturally occurring antisense RNA control--a brief review

Biological control by naturally occurring anti-sense RNAs has been documented in a number of prokaryotic cases, and strongly suggested in several eukaryotic systems. The biological activities controlled are diverse, including transposition, phage development, chromosomal gene expression, and plasmid replication, compatibility and conjugation. Control is exerted at many different levels, by both direct and long-range effects. The stem/loop structures common to all anti-sense RNAs are important functional domains: loops are the sites of critical interactions in the initiation of pairing to the target RNA; stems determine anti-sense RNA stability in vivo. These features need to be considered in the design of artificial anti-sense RNA control. Details of RNA/RNA pairing have emerged; pairing initiates at single-stranded regions in anti-sense RNA loops, and stable complex formation involves the nearby end of one or both molecules.     

Ribonucleic Acid Synthesis of Vesicular Stomatitis Virus: I. Species of Ribonucleic Acid Found in Chinese Hamster Ovary Cells Infected with Plaque-forming and Defective Particles

Plaque-forming B particles of vesicular stomatitis virus (VSV) induce the synthesis of virus-specific ribonucleic acid (RNA) in Chinese hamster ovary cells, whereas defective T particles do not. Infection with low input multiplicities of B results in the formation of four species of RNA. During infection with high multiplicities, RNA synthesis begins with mainly these four species of RNA but gradually shifts to a new pattern of RNA synthesis involving five other species of RNA. The change can also be induced by superinfection with T at 2.5 hr after infection with a low multiplicity of B. T added at the same time as B prevents virtually all RNA synthesis. Synthesis of the first group of RNA species correlates with the formation of B particles, whereas synthesis of the second group correlates with the formation of T particles. The various species of RNA formed after infection with VSV particles include single-stranded RNA, a completely double-stranded RNA, and RNA with partially double-stranded regions. These observations begin to establish a molecular basis for understanding the ability of T particles to interfere with the growth of B particles.     

Analysis by electron microscopy of the variable segment in the maxi-circle of kinetoplast DNA from Trypanosoma brucei

The 20.5-kbp maxi-circle from the kinetoplast DNA of Trypanosoma brucei contains a 5-kbp segment which is not cut by most restriction endonucleases and which varies in size in closely-related trypanosome strains (Borst, P., Fase-Fowler, F., Hoeijmakers, J.H.J. and Frasch, A.C.C. (1980) Biochim. Biophys. Acta 610, 197–210). We have now analysed partial denaturation maps of the linearized maxi-circles by electron microscopy and find that the variable segment is not more AT-rich than the remainder of the maxi-circle. Early denaturation begins at two separate regions of the maxi-circle outside the variable region and one of these corresponds with the position of the gene for the large (12 S) ribosomal RNA. Denaturation-renaturation of maxi-circles leads to the formation of partially mismatched duplexes that look like underwound loops in electron micrographs. These loops are only found in the variable region and they vary in size and appearance. Under our renaturation conditions single-stranded maxi-circle DNA is devoid of secondary structure and this suggests that the underwound loops arise by misalignment of straight tandem repeats in the DNA. We have also analysed heteroduplexes between maxi-circles from two closely related T. brucei strains that differ by 1 kbp in the size of their variable segment. Most molecules had no underwound loops and contained mismatched regions in the variable segment only. The appearance of these regions is diverse, varying from fully duplex with two single-stranded loops to molecules with a heterogeneous array of smaller loops. The total size of single-stranded DNA in the heteroduplexes may be as high as 1.2 μm, i.e., a factor 4 higher than the size difference between the heteroduplex partners. We conclude that the variable region consists of imperfect tandem repeats of a sequence that evolves rapidly. This region might contain the origin of maxi-circle replication.     

A new principle of RNA folding based on pseudoknotting.

Tertiary interactions involving hairpin or interior loops of RNA can lead to extended quasi-continuous double helical stem regions, consisting of coaxially stacked segments of duplex RNA, bridged by single-stranded connections. This type of compact folding plays a role in various strategic regions of RNA molecules. Their role in ribosome functioning, RNA splicing and recognition of tRNA-like structures is discussed.     

Structure of the Escherichia coli 16 S ribosomal RNA. Psoralen crosslinks and N-acetyl-N'-(p-glyoxylylbenzoyl)cystamine crosslinks detected by electron microscopy

Escherichia coli 16 S ribosomal RNA in reconstitution buffer has been photochemically crosslinked with aminomethyltrimethylpsoralen and chemically crosslinked with N-acetyl-N'-(p-glyoxylylbenzoyl)cystamine. The positions of crosslinking have been detected by viewing the molecules in the electron microscope. DNA restriction fragments that contain psoralen mono-adducts were hybridized and crosslinked to the samples so that the orientations of the crosslinked molecules were seen directly. A two-dimensional histogram method has been used to classify the different types of looped crosslinked molecules. These methods allow the identification of 13 distinct types of loops in the photochemically crosslinked molecules and 31 distinct types of loops in the chemically crosslinked molecules. The psoralen experiments are a reinvestigation of some of our earlier results. Some of the crosslinks were previously reported in the incorrect orientation; with the corrected orientation, seven of the psoralen crosslinks can now be correlated with complementarities in the proposed secondary-structure models. However, there are still six other psoralen crosslinks that indicate additional contacts not found in the current models. The chemical crosslinks indicate pairs of single-stranded regions that must be close in the folded molecule. Many of these crosslinks occur between regions that are distant in the secondary structure; these crosslinks indicate part of the three-dimensional form of the folded molecule.