Studies of metabolic control using NMR and molecular genetics.

The techniques of NMR spectroscopy and molecular genetics have provided new and powerful approaches to studying the control and organisation of cellular metabolism in vivo. We review here our recent applications of these methodologies to the study of energy metabolism in yeast and mammalian cells.

Complete nucleotide sequence of a mouse VL30 retro-element.

The complete nucleotide sequence of a mouse retro-element is presented. The cloned element is composed of 4,834 base pairs (bp) with long terminal repeats of 568 bp separated by an internal region of 3,698 bp. The element did not appear to have any open reading frames that would be capable of encoding the functional proteins that are normally produced by retro-elements. However, some regions of the genome showed some homology to retroviral gag and pol open reading frames. There was no region in VL30 corresponding to a retroviral env gene. This implies that VL30 is related to retrotransposons rather than to retroviruses. The sequence also contained regions that were homologous to known reverse transcriptase priming sites and viral packaging sites. These observations, combined with the known transcriptional capacity of the VL30 promoter, suggest that VL30 relies on protein functions of other retro-elements, such as murine leukemia virus, while maintaining highly conserved cis-active promoter, packaging, and priming sites necessary for its replication and cell-to-cell transmission.

The genetic organization of the yeast Ty element.

The genetic organization of the yeast transposon Ty resembles that of higher eukaryotic retroviruses and other elements such as the copia-like sequences of Drosophila. The Ty genome is 5.9 kb (10(3) bases) long. It has 340 bp (base pairs) terminal repeats known as delta sequences and it produces a terminally redundant 5.7 kb RNA that starts in the 5' delta and ends in the 3' delta. Ty transcription is directed by signals upstream and downstream of the major RNA start site and is regulated by the mating-type configuration of the cell. The 5.7 kb transcriptional unit is divided into two overlapping open reading frames, TYA and TYB. TYA occupies approximately the first quarter of the transcriptional unit while TYB occupies the rest. TYB overlaps TYA by either 38 or 44 nucleotides, depending on the element, and is in the plus one reading frame with respect to TYA. TYA is expressed to produce protein p1 (50 x 10(3) Mr) and TYB is expressed as a TYA:TYB fusion protein, p3 (190 x 10(3) Mr). Both of these proteins are subsequently cleaved to produce proteins p2, p4, p5, p6, reverse transcriptase and a protease that is responsible for some of these cleavage events. These proteins are assembled into virus-like particles (Ty-VLPs) that contain Ty RNA and reverse transcriptase activity. It is likely that the Ty-VLPs are units of transposition as Ty transposes via an RNA intermediate.

A retrovirus-like strategy for expression of a fusion protein encoded by yeast transposon Ty1.

Eukaryotic transposons such as the Ty element of yeast or the copia-like sequences of Drosophila show structural and functional similarities to both prokaryotic transposons and retroviral proviruses, but the prokaryotic transposons and retroviral proviruses use markedly different expression strategies which yield products having entirely different functions. To determine the phylogenetic relationship between eukaryotic transposons, prokaryotic transposons and retroviruses, we have sought to identify and characterize the proteins encoded by the yeast Ty element and to describe the strategies used to express these proteins. We show here that the yeast transposon produces a fusion protein by a specific frameshifting event that fuses two out-of-phase open reading frames (ORFs). The process is remarkably similar to that used by retroviruses such as Rous sarcoma virus (RSV) to produce Pr180gag-pol.