Real-time kinetics of HIV-1 Rev-Rev response element interactions. Definition of minimal binding sites on RNA and protein and stoichiometric analysis.

The kinetics of interaction between the human immunodeficiency virus-1 Rev protein and its RNA target, Rev response element (RRE) RNA was determined in vitro using a biosensor technique. Our results showed that the primary Rev binding site is a core stem-loop RNA molecule of 30 nucleotides that bound Rev at a 1:1 ratio, whereas the 244-nucleotide full-length RRE bound four Rev monomers. At high Rev concentrations, additional binding of Rev to RRE was observed with ratios of more than 10:1. Because RRE mutants that lacked the core binding site and were inactive in vivo bound Rev nonspecifically at these concentrations, the real stoichiometric ratio of Rev-RRE is probably closer to 4:1. Binding affinity of Rev for RRE was approximately 10(-10) M, whereas the affinity for the core RNA was about 10(-11) M, the difference being due to the contribution of low affinity binding sites on the RRE. Mathematical analysis suggested cooperativity of Rev binding, probably mediated by the Rev oligomerization domains. C-terminal deletions of Rev had no effect on RRE binding, but truncation of the N terminus by as few as 11 residues significantly reduced binding specificity. This method was also useful to rapidly evaluate the potential of aminoglycoside antibiotics, to inhibit the Rev-RRE interaction.

Genetic probes of ribosomal RNA function.

We have used a genetic approach to uncover the functional roles of rRNA in protein synthesis. Mutations were constructed in a cloned rrn operon by site-directed mutagenesis or isolated by genetic selections following random mutagenesis. We have identified mutations that affect each step in the process of translation. The data are consistent with the results of biochemical and phylogenetic analyses but, in addition, have provided novel information on regions of rRNA not previously investigated.

Structural changes in the 530 loop of Escherichia coli 16S rRNA in mutants with impaired translational fidelity.

The higher order structure of the functionally important 530 loop in Escherichia coli 16S rRNA was studied in mutants with single base changes at position 517, which significantly impair translational fidelity. The 530 loop has been proposed to interact with the EF-Tu-GTP-aatRNA ternary complex during decoding. The reactivity at G530, U531 and A532 to the chemical probes kethoxal, CMCT and DMS respectively was increased in the mutant 16S rRNA compared with the wild-type, suggesting a more open 530 loop structure in the mutant ribosomes. This was supported by oligonucleotide binding experiments in which probes complementary to positions 520-526 and 527-533, but not control probes, showed increased binding to the 517C mutant 70S ribosomes compared with the non-mutant control. Furthermore, enzymatic digestion of 70S ribosomes with RNase T1, specific for single-stranded RNA, substantially cleaved both wild-type and mutant rRNAs between G524 and C525, two of the nucleotides involved in the 530 loop pseudoknot. This site was also cleaved in the 517C mutant, but not wild-type rRNA, by RNase V1. Such a result is still consistent with a more open 530 loop structure in the mutant ribosomes, since RNase V1 can cut at appropriately stacked single-stranded regions of RNA. Together these data indicate that the 517C mutant rRNA has a rather extensively unfolded 530 loop structure. Less extensive structural changes were found in mutants 517A and 517U, which caused less misreading. A correlation between the structural changes in the 530 loop and impaired translational accuracy is proposed.

In vivo analyses of the internal control region in the 5S rRNA gene from Saccharomyces cerevisiae.

The internal control region of the Saccharomyces cerevisiae 5S rRNA gene has been characterized in vivo by genomic DNase I footprinting and by mutational analyses using base substitutions, deletions or insertions. A high copy shuttle vector was used to efficiently express mutant 5S rRNA genes in vivo and isotope labelling kinetics were used to distinguish impeded gene expression from nascent RNA degradation. In contrast to mutational studies in reconstituted systems, the analyses describe promoter elements which closely resemble the three distinct sequence elements that have been observed in Xenopus laevis 5S rRNA. The results indicate a more highly conserved structure than previously reported with reconstituted systems and suggest that the saturated conditions which are used in reconstitution studies mask sequence dependence which may be physiologically significant. Footprint analyses support the extended region of protein interaction which has recently been observed in some reconstituted systems, but mutational analyses indicate that these interactions are not sequence specific. Periodicity in the footprint provides further detail regarding the in vivo topology of the interacting protein.

Effect of sequence mutations on the higher order structure of the yeast 5 S rRNA.

Mutant yeast ribosomal 5 S RNAs were probed by enzymatic cleavage and chemical reactivity to define further the higher order structure. Mutations that destabilized helix IV resulted in an altered tertiary structure in which a reduced reactivity to ethylnitrosourea at U90 and G91 could be correlated with greater enzymatic and Fe(II)-EDTA cleavages in helices II and V. The results provide direct evidence for, and a further definition of, a structural juxtaposition between helix II and the end of helix IV and indicate that, in contrast to earlier suggestions, the remaining tertiary structure is sufficiently stable to prevent "pseudoknot-like" interactions between helices III and IV. The data are fully consistent with the "lollipop" model of the tertiary structure.

Unbalanced ribosome assembly in Saccharomyces cerevisiae expressing mutant 5 S rRNAs.

Mutant 5 S rRNA genes were expressed in Saccharomyces cerevisiae to further define the function of the ribosomal 5 S RNA. RNA synthesis and utilization were assayed using previously constructed markers which have been shown to be functionally neutral and easily detected by gel electrophoresis. Most mutations were found not to affect the growth rate because they were poorly expressed or could be accommodated effectively in the ribosomal structure. Two of the mutants, Y5A99U56U57 and Y5U90i5 adversely affected cell growth as well as protein synthesis in vitro. Polyribosome profiles in both of these mutants were substantially shorter, and an analysis of the ribosomal subunit composition revealed a significant imbalance with a 25-35% excess in 40 S subunits. Kinetic analyses of RNA labeling indicated very low cellular levels of mutant RNA either because it was poorly expressed (Y5U90i5) or rapidly degraded before being incorporated into mature 60 subunits (Y5A99U56U57). The results suggest that the 5 S RNA is required for the assembly of stable ribosomal 60 S subunits and raise the possibility that this RNA or, more likely, its corresponding ribonucleoprotein complex is critical for subunit assembly or even RNA processing.

Use of mutant RNAs in studies on yeast 5S rRNA structure and function.

The expression of mutant yeast 5S rRNA genes in vivo is reviewed as a basis for further studies on the structure, function, and regulation of the ribosomal 5S rRNA. Specific base substitutions, insertions, or deletions can result in substantial structural changes which can be detected readily by gel electrophoresis, permitting the assay of mutant RNA synthesis and utilization. Furthermore, the use of high and low copy shuttle vectors, as well as alternate growth conditions, permits a wide adjustment of the mutant RNA concentration. Under optimized conditions more than 80% of the cell's RNA can be replaced with mutant molecules. The application of this strategy to studies on the biosynthesis and structure of the 5S rRNA are demonstrated through recently isolated mutations.

A widely distributed "CAT" family of repetitive DNA sequences.

The yeast genome contains a family of repetitive sequences consisting primarily of a tandemly arranged trinucleotide, CAT, or a closely related CGT sequence. To characterize similar sequences in divergent organisms, a previously isolated "CAT" sequence was used to isolate homologous genomic clones from a human cell line, an insect and a higher plant. Sequence analyses show that comparable repetitive sequences are widely distributed and may be present in all eukaryotic genomes. In situ hybridization analyses indicate that in yeast, the CAT elements are dispersed among all the chromosomes, and a more detailed analysis in Drosophila indicates that at least one of these sequences maps on the X chromosome between known genetic loci which are actively expressed. Repeated searches of yeast cDNA libraries indicate that these CAT clusters are not expressed but substantial effects on the expression of a cloned gene strongly suggest that they play an important role in gene regulation.

Efficient expression and utilization of mutant 5 S rRNA in Saccharomyces cerevisiae.

The expression of mutant 5 S rRNA genes in vivo is examined as a basis for further studies on the control, structure, and function of the ribosomal 5 S RNA. Specific single base substitutions (e.g. positions 98 or 99) or short insertions can result in substantial structural changes that can easily be detected by gel electrophoresis and permit the assay of mutant RNA synthesis and utilization. In addition, the use of high and low copy shuttle vectors as well as alternate growth conditions permits the adjustment of mutant RNA levels in vivo. Despite the high genomic copy number for the 5 S rRNA gene, under optimized conditions as much as 80% of the cellular 5 S RNA can be mutant, and RNA structure analyses indicate that some of these RNAs can readily be assembled into the ribosome structure resulting in an in vivo ribosome population which is also approximately 80% mutant. The results indicate that plasmid integrated 5 S rRNA genes are preferentially expressed and suggest that additional features of the chromosome structure regulate 5 S rRNA gene expression in vivo.

Structure and evolution of the 4.5-5S ribosomal RNA intergenic region from Glycine max (soya bean).

The nucleotide sequence for the 4.5-5S ribosomal DNA region from the chloroplastids of soya beans was determined as the basis of further comparative studies on the structure and evolution of this intergenic region. Comparisons with other plant sequences as well as equivalent sequences in eubacteria suggest that the longer internal transcribed spacer regions of plants have evolved, at least in part, by DNA sequence duplications and that the presence of the 4.5S rRNA in chloroplast may result from the accidental acquisition of a RNA maturation site during the evolution of longer internal transcribed spacer regions. Estimates of the secondary structures also indicate only a very limited retention of structural features and suggest that the primary role of the intergenic sequences may be to bring processed sites into close proximity.

Activity changes of three nucleolytic enzymes during the life cycle of Saccharomyces cerevisiae.

Conditions were established for the assay of three nucleolytic enzymes: a Mg2+-independent endoribonuclease, a Mg2+-dependent endonuclease, and a Mg2+-dependent 5'-exonuclease in Saccharomyces cerevisiae cell extracts. The changes in the activities of these enzymes were determined throughout the life cycle of the organism. As the cells progressed from the exponential to the stationary growth phase, the specific activities of the Mg2+-independent endoribonuclease and of the Mg2+-dependent 5'-exonuclease increased, whereas the Mg2+-dependent endonuclease decreased. During sporulation the Mg2+-independent endoribonuclease and the Mg2+-dependent 5'-exonuclease increased several-fold over the first 10 h, but, since a similar increase was seen in nonsporulating control cells, the increases did not appear to be related to sporulation. However, the specific activity of the Mg2+-dependent endonuclease showed a sporulation-related increase during the first 3 h of sporulation, with a subsequent decline to very low levels. The specific activity of this enzyme increased again during germination to the levels seen in exponential phase cells. The Mg2+-independent endoribonuclease and the Mg2+-dependent 5'-exonuclease showed little change during germination of the ascospores. The high specific activity of the Mg2+-independent endoribonuclease during periods of nutrient deprivation is in agreement with the proposed role for this enzyme in the degradation of rRNA under these conditions.