RNA chaperones stimulate formation and yield of the U3 snoRNA-Pre-rRNA duplexes needed for eukaryotic ribosome biogenesis.

Short duplexes between the U3 small nucleolar RNA and the precursor ribosomal RNA must form quickly and with high yield to satisfy the high demand for ribosome synthesis in rapidly growing eukaryotic cells. These interactions, designated the U3-ETS (external transcribed spacer) and U3-18S duplexes, are essential to initiate the processing of small subunit ribosomal RNA. Previously, we showed that duplexes corresponding to those in Saccharomyces cerevisiae are only observed in vitro after addition of one of two proteins: Imp3p or Imp4p.

Imp3p and Imp4p mediate formation of essential U3-precursor rRNA (pre-rRNA) duplexes, possibly to recruit the small subunit processome to the pre-rRNA.

In eukaryotes, formation of short duplexes between the U3 small nucleolar RNA (snoRNA) and the precursor rRNA (pre-rRNA) at multiple sites is a prerequisite for three endonucleolytic cleavages that initiate small subunit biogenesis by releasing the 18S rRNA precursor from the pre-rRNA. The most likely role of these RNA duplexes is to guide the U3 snoRNA and its associated proteins, designated the small subunit processome, to the target cleavage sites on the pre-rRNA. Studies by others in Saccharomyces cerevisiae have identified the proteins Mpp10p, Imp3p, and Imp4p as candidates to mediate U3-pre-rRNA interactions.

RNA recognition and base flipping by the toxin sarcin.

Sarcin is a member of a fungal toxin family that enters cells and specifically cleaves one of the thousands of RNA phosphodiester bonds in the ribosome. As a result, elongation factor binding is disrupted, translation is inhibited and apoptosis is triggered. The toxin targets a universal RNA structure in the ribosome called the sarcin/ricin loop (SRL).

Crystal structures of restrictocin-inhibitor complexes with implications for RNA recognition and base flipping.

The cytotoxin sarcin disrupts elongation factor binding and protein synthesis by specifically cleaving one phosphodiester bond in ribosomes. To elucidate the molecular basis of toxin action, we determined three cocrystal structures of the sarcin homolog restrictocin bound to different analogs that mimic the target sarcin/ricin loop (SRL) structure of the rat 28S rRNA. In these structures, restrictocin contacts the bulged-G motif and an unfolded form of the tetraloop of the SRL RNA.

Construction of a 3D model of oligopeptidase B, a potential processing enzyme in prokaryotes.

A three dimensional structural model of oligopeptidase B (OpB) was constructed by homology modeling. High resolution X-ray structure of prolyl oligopeptidase (PEP), the only protein with sequential and functional homology was used as a template. Initial models of OpB were built by the MODELLER and were analysed by the PROCHECK programs.

Structure determination and refinement of the Al3+ complex of the D254,256E mutant of Arthrobacter D-xylose isomerase at 2.40 A resolution. Further evidence for inhibitor-induced metal ion movement.

The structure of the D254.256E double mutant of Arthrobacter xylose isomerase with Al3+ at both metal-binding sites was determined by the molecular replacement method at a conventional R-factor of 0.179.