Analysis of the functional role of a G.A sheared base pair by in vitro genetics.

A classical genetic strategy has been combined with an in vitro selection method to search for functional interactions between the two domains of the hairpin ribozyme. G(21) is located within internal loop B; it is proposed to form a sheared base pair with A(43) across loop B and to bind a Mg(2+) ion. Both nucleotides are important for ribozyme function, and G.A sheared base pairs are a very widespread motif in structured RNA. We took advantage of its presence in the hairpin ribozyme to study its functional role. Pseudorevertants, in which the loss of G(21) was compensated by mutations at other positions, were isolated by in vitro selection. The vast majority of G(21) revertants contained substitutions within domain A, pointing to functional communication between specific sites within the two domains of the hairpin ribozyme. The possibility of a direct or redundant contacts is supported by electrophoretic mobility shift studies showing that a complex formed between domain B of the ribozyme and the substrate was disrupted and restored by base substitutions that have analogous effects on catalytic activity. The functional significance of this complex, the role of the nucleotides involved, and the basis for magnesium ion requirement is discussed.

Detection of a novel ATP-dependent cross-linked protein at the 5' splice site-U1 small nuclear RNA duplex by methylene blue-mediated photo-cross-linking.

Assembly of spliceosomes involves a number of sequential steps in which small nuclear ribonucleoprotein particles (snRNPs) and some non-snRNP proteins recognize the splice site sequences and undergo various conformational rearrangements. A number of important intermolecular RNA-RNA duplexes are formed transiently during the process of splice site recognition. Various steps in the assembly pathway are dependent upon ATP hydrolysis, either for protein phosphorylation or for the activity of helicases, which may modulate the RNA structures. Major efforts have been made to identify proteins that interact with specific regions of the pre-mRNA during the stages of spliceosome assembly and catalysis by site-specific UV cross-linking. However, UV cross-linking is often inefficient for the detection of proteins that interact with base-paired RNA. Here we have used the complementary approach of methylene blue-mediated photo-cross-linking to detect specifically proteins that interact with the duplexes formed between pre-mRNA and small nuclear RNA (snRNA). We have detected a novel cross-link between a 65-kDa protein (p65) and the 5' splice site. A range of data suggest that p65 cross-links to the transient duplex formed by U1 snRNA and the 5' splice site. Moreover, although p65 cross-linking requires only a 5' splice site within the pre-mRNA, it also requires ATP hydrolysis, suggesting that its detection reflects a very early ATP-dependent event during splicing.

Conservation of a hairpin ribozyme sequence in HIV-1 is required for efficient viral replication.

We have previously described a hairpin ribozyme that targets a highly conserved sequence in the U5 region of HIV-1. To determine if escape mutations would compromise virus replication, we introduced critical mutations into the ribozyme target site of an infectious molecular clone of HIV-1MN. HIV-1 MNA has a substitution of A for G immediately 3' to the cleavage site and HIV-1 MNGC has two substitutions in the flanking sequences that are complementary to the ribozyme. In vitro studies confirmed that neither the MNA-nor the MNGC-mutated target sequence was cleaved by the ribozyme, and furthermore, the MNGC-mutated target sequence failed to bind the ribozyme. Compensatory GC substitutions in the substrate recognition domain of the ribozyme resulted in a switch of binding and cleavage specificity. Replication of both the MNA and MNGC mutant viruses was initially two to three logs lower than that of wild-type virus, but after 3 weeks, virus production rose sharply in both cultures. Nucleotide sequence of RT-PCR-amplified viral sequences obtained from virus produced at later time points revealed complete reversion of MNA or partial reversion of MNGC to wild-type genotypes. No additional mutations within the ribozyme target sequence were observed. These results indicate that mutations in this conserved ribozyme target sequence led to significant attenuation of HIV-1MN.

Dissecting and analyzing the secondary structure domains of group I introns through the use of chimeric intron constructs.

The mitochondrial genes of the yeast Saccharomyces cerevisiae are often interrupted by introns defined as either group I or group II. Some of the introns contained within the precursor RNAs of these genes will self splice in vitro. The fourth introns of apocytochrome b (bi4) and cytochrome oxidase (ai4) are group I introns that do not self splice in vitro, even though they can fold into the same RNA secondary structures that are characteristic of the self-splicing introns. They require an intron-encoded maturase protein and a nuclear-encoded protein (a tRNALeu synthetase) for splicing in vivo. We have divided these introns into several sequence or structural elements and assayed them individually for their ability to support self-splicing activity. This was done by replacing the equivalent elements from the self-splicing intron from Tetrahymena thermophila with the mitochondrial elements. These intron chimeras show that peripheral sequences and the elements that define the splice sites are adequate for self-splicing activity but that the central portions containing the catalytic cores of ai4 and bi4 are deficient; these cores are the likely targets of the splicing proteins. In addition, the catalytic activity of the Tetrahymena intron is remarkably resistant to the structural alterations that we have introduced; this suggests that this technique will be of general utility for studying the structural and functional relationships of elements contained within different RNAs.

An improved version of the hairpin ribozyme functions as a ribonucleoprotein complex.

Most RNA molecules that are endowed with catalytic activity function in the form of ribonucleoproteins within cells. These complexes are frequently large, poorly defined, and difficult to study. As a model system to study biological catalysis by ribonucleoproteins, we have modified the hairpin ribozyme by inserting an RNA structure that serves as a binding site for bacteriophage R17 coat protein in the form of an extension to ribozyme helix 4, which lies at the periphery of the catalytic domain. In the absence of protein, we find that incorporation of the protein-binding domain increases the catalytic efficiency of the hairpin ribozyme by 2-fold for the cleavage reaction and 16-fold for the ligation reaction. This increase in activity correlates with an increase in the proportion of molecules which fold into the active tertiary structure, as measured by a UV cross-linking assay. Mobility-shift and filter-binding assays of complex formation show that R17 coat protein binds to the chimeric ribozyme with a dissociation constant essentially identical to that of the isolated protein-binding domain; no binding of the protein to the unmodified ribozyme could be detected. The kinetics of cleavage and ligation reactions are not altered by the presence of saturating concentrations of coat protein, and competition studies demonstrate that the protein remains bound to the ribozyme throughout the catalytic cycle. These studies establish that the hairpin ribozyme can be engineered to function efficiently in the form of a ribonucleoprotein in vitro and will serve as the basis for future experimentation to understand mechanisms of protein modulation of catalytic RNA activity, and to introduce other protein-binding domains, for example, HIV-1 rev-binding and tar elements, which may be useful for influencing subcellular localization, regulating intracellular activity, or generating ribozymes that also function as "decoys" in antiviral applications.

A shortened form of the Tetrahymena thermophila group I intron can catalyze the complete splicing reaction in trans.

The group I intron from Tetrahymena thermophila is able to catalyze its own excision from a precursor RNA. The intron recognizes the splice sites through an intron-encoded sequence called the internal guide sequence, or IGS. The 5' and 3' exons are thought to align on the IGS and form a pseudoknot structure consisting of two stems (P1 and P10). We created a shortened form of the intron that lacks the exon sequences and the entire IGS. This RNA is unable to react upon itself. It can catalyze a sequential two-step transesterification reaction on a P1P10 substrate added in trans that completely mimics splicing. The reaction works for different substrates that contain a U.G base-pair preceding the 5' cleavage site and a guanosine base preceding the 3' cleavage site, but that are otherwise unrelated in sequence. The ribozyme uses primarily the correct 5' and 3' splice sites even in the presence of potential cryptic splice sites, and therefore it must rely on the structure of the substrate (formation of the P1 and P10 helices) for correct splice site recognition. A C-G base-pair after the 5' splice site in P1 decreases activity while a U.G or G.U base-pair enhances activity. The relative position in P1 of the U.G base-pair preceding the 5' splice site is an important determinant. The ability of the intron to recognize primarily a specific structure, rather than a sequence, has ramifications for splice-site selection, for molecular modeling of the group I intron, and for ribozyme-based gene targeting.

A new specific DNA endonuclease activity in yeast mitochondria.

Two group I intron-encoded proteins from the yeast mitochondrial genome have already been shown to have a specific DNA endonuclease activity. This activity mediates intron insertion by cleaving the DNA sequence corresponding to the splice junction of an intronless strain. We have discovered in mitochondrial extracts from the yeast strain 777-3A a new DNA endonuclease activity which cleaves the fused exon A3-exon A4 junction sequence of the CO XI gene.

In vivo and in vitro analyses of an intron-encoded DNA endonuclease from yeast mitochondria. Recognition site by site-directed mutagenesis.

The pal 4 nuclease (termed I-Sce II) is encoded in the group I al 4 intron of the COX I gene of Saccharomyces cerevisiae. It introduces a specific double-strand break at the junction of the two exons A4-A5 and thus mediates the insertion of the intron into an intronless strain. To define the sequence recognized by pal 4 we introduced 35 single mutations in its target sequence and examined their cleavage properties either in vivo in E. coli (when different forms of the pal 4 proteins were artificially produced) or in vitro with mitochondrial extracts of a mutant yeast strain blocked in the splicing of the al 4 intron. We also detected the pal 4 DNA endonuclease activity in extracts of the wild type strain. The results suggest that 6 to 9 noncontiguous bases in the 17 base-pair region examined are necessary for pal 4 nuclease to bind and cleave its recognition site. We observed that the pal 4 nuclease specificity can be significantly different with the different forms of the protein thus explaining why only some forms are highly toxic in E. coli. This study shows that pal 4 recognition site is a complex phenomenon and this might have evolutionary implications on the transfer properties of the intron.