Posttranscriptional modification of transfer RNA in the submarine hyperthermophile Pyrolobus fumarii.

In the RNA of hyperthermophiles, which grow optimally between 80 degrees C and 106 degrees C, posttranscriptional modification has been identified as a leading mechanism of structural stabilization. Particularly in the Archaeal evolutionary domain these modifications are expressed as a structurally diverse array of modification motifs, many of which include ribose methylation. Using mass spectrometric techniques we have examined the posttranscriptional modifications in unfractionated tRNA from the remarkable organism Pyrolobus fumarii, which grows optimally at 106 degrees C, but up to 113 degrees C (Blöchl et al. (1997), Extremophiles, 1, 14-21). Twenty-six modified nucleosides were detected, 11 of which are methylated in ribose. A new RNA nucleoside, 1,2'-O-dimethylguanosine (m1Gm) was characterized and the structure confirmed by chemical synthesis.

A detailed view of a ribosomal active site: the structure of the L11-RNA complex.

We report the crystal structure of a 58 nucleotide fragment of 23S ribosomal RNA bound to ribosomal protein L11. This highly conserved ribonucleoprotein domain is the target for the thiostrepton family of antibiotics that disrupt elongation factor function. The highly compact RNA has both familiar and novel structural motifs. While the C-terminal domain of L11 binds RNA tightly, the N-terminal domain makes only limited contacts with RNA and is proposed to function as a switch that reversibly associates with an adjacent region of RNA. The sites of mutations conferring resistance to thiostrepton and micrococcin line a narrow cleft between the RNA and the N-terminal domain. These antibiotics are proposed to bind in this cleft, locking the putative switch and interfering with the function of elongation factors.