A covalent crosslink converts the hammerhead ribozyme from a ribonuclease to an RNA ligase.

The hammerhead ribozyme is a more efficient ribonuclease than an RNA ligase. Under typical reaction conditions, the rate of RNA chain cleavage is approximately 100-fold faster than the rate of the reverse ligation reaction such that virtually all of the hammerhead is in its cleaved form at equilibrium. Here we show that the introduction of a crosslink away from the catalytic core of the hammerhead has little effect on the cleavage rate but dramatically increases the ligation rate, thereby making the hammerhead an efficient RNA ligase. This experiment emphasizes the role of molecular flexibility in defining the properties of a macromolecular catalyst and suggests why other small ribozymes are more efficient ligases than ribonucleases.

Factors affecting nuclear export of the 60S ribosomal subunit in vivo.

In Saccharomyces cerevisiae, the 60S ribosomal subunit assembles in the nucleolus and then is exported to the cytoplasm, where it joins the 40S subunit for translation. Export of the 60S subunit from the nucleus is known to be an energy-dependent and factor-mediated process, but very little is known about the specifics of its transport. To begin to address this problem, an assay was developed to follow the localization of the 60S ribosomal subunit in S. cerevisiae. Ribosomal protein L11b (Rpl11b), one of the approximately 45 ribosomal proteins of the 60S subunit, was tagged at its carboxyl terminus with the green fluorescent protein (GFP) to enable visualization of the 60S subunit in living cells. A panel of mutant yeast strains was screened for their accumulation of Rpl11b-GFP in the nucleus as an indicator of their involvement in ribosome synthesis and/or transport. This panel included conditional alleles of several rRNA-processing factors, nucleoporins, general transport factors, and karyopherins. As predicted, conditional alleles of rRNA-processing factors that affect 60S ribosomal subunit assembly accumulated Rpl11b-GFP in the nucleus. In addition, several of the nucleoporin mutants as well as a few of the karyopherin and transport factor mutants also mislocalized Rpl11b-GFP. In particular, deletion of the previously uncharacterized karyopherin KAP120 caused accumulation of Rpl11b-GFP in the nucleus, whereas ribosomal protein import was not impaired. Together, these data further define the requirements for ribosomal subunit export and suggest a biological function for KAP120.

7The yeast mRNA-binding protein Npl3p interacts with the cap-binding complex.

A number of RNA-binding proteins are associated with mRNAs in both the nucleus and the cytoplasm. One of these, Npl3p, is a heterogeneous nuclear ribonucleoprotein-like protein with some similarity to SR proteins and is essential for growth in the yeast S. cerevisiae. Temperature-sensitive alleles have defects in the export of mRNA out of the nucleus (1). In this report, we define a genetic relationship between NPL3 and the nonessential genes encoding the subunits of the cap-binding complex (CBP80 and CBP20). Deletion of CBP80 or CBP20 in combination with certain temperature-sensitive npl3 mutant alleles fail to grow and thus display a synthetic lethal relationship. Further evidence of an interaction between Npl3p and the cap-binding complex was revealed by co-immunoprecipitation experiments; Cbp80p and Cbp20p specifically co-precipitate with Npl3p. However, the interaction of Npl3p with Cbp80p depends on both the presence of Cbp20p and RNA. In addition, we show that Cbp80p is capable of shuttling between the nucleus and the cytoplasm in a manner dependent on the ongoing synthesis of RNA. Taken together, these data support a model whereby mRNAs are co-transcriptionally packaged by proteins including Npl3p and cap-binding complex for export out of the nucleus.

Thermodynamic dissection of the substrate-ribozyme interaction in the hammerhead ribozyme.

The free energy of substrate binding to the hammerhead ribozyme was compared for 10 different hammerheads that differed in the length and sequence of their substrate recognition helices. These hammerheads were selected because neither ribozyme nor substrate oligonucleotide formed detectable alternate secondary structures. The observed free energies of binding varied from -8 to -24 kcal/mol and agreed very well with binding energies calculated from the nearest-neighbor free energies if a constant energetic penalty of DeltaG degreescore = +3.3 +/- 1 kcal/mol is used for the catalytic core. A set of substrates that contained a competing hairpin secondary structure showed weaker binding to the ribozyme by an amount consistent with the predicted free energy for hairpin formation. These thermodynamic conclusions permit the prediction of substrate binding affinities for ribozyme-substrate pairs of any helix length and sequence, and thus, should be very valuable for the rational design of ribozymes directed toward gene inactivation.

Circular substrates of the hammerhead ribozyme shift the internal equilibrium further toward cleavage.

To test whether the Y-shaped conformation of the hammerhead ribozyme is maintained throughout the catalytic pathway, the cleavage properties of circular substrates which bind the ribozyme through helices I and II were determined. Constraining the position of helices I and II in this manner did not significantly alter the rate constant for cleavage, consistent with no large rearrangement of the helices occurring during catalysis. Unexpectedly, the "internal" equilibrium between the cleavage and ligation reactions for the circular hammerheads was shifted further toward cleavage. This effect was due to the rate of ligation of the circular substrate being slower than the corresponding linear substrate. The temperature dependence of the internal equilibrium of the circular substrate revealed that although restricting the flexibility of the hammerhead reduced the favorable entropy change associated with cleavage as expected, the unfavorable enthalpy change was reduced as well, resulting in greater overall cleavage.