A biochemical genomics approach for identifying genes by the activity of their products.

For the identification of yeast genes specifying biochemical activities, a genomic strategy that is rapid, sensitive, and widely applicable was developed with an array of 6144 individual yeast strains, each containing a different yeast open reading frame (ORF) fused to glutathione S-transferase (GST). For the identification of ORF-associated activities, strains were grown in defined pools, and GST-ORFs were purified. Then, pools were assayed for activities, and active pools were deconvoluted to identify the source strains. Three previously unknown ORF-associated activities were identified with this strategy: a cyclic phosphodiesterase that acts on adenosine diphosphate-ribose 1"-2" cyclic phosphate (Appr>p), an Appr-1"-p-processing activity, and a cytochrome c methyltransferase.

An NAD derivative produced during transfer RNA splicing: ADP-ribose 1"-2" cyclic phosphate.

Transfer RNA (tRNA) splicing is essential in Saccharomyces cerevisiae as well as in humans, and many of its features are the same in both. In yeast, the final step of this process is removal of the 2' phosphate generated at the splice junction during ligation. A nicotinamide adenine dinucleotide (NAD)-dependent phosphotransferase catalyzes removal of the 2' phosphate and produces a small molecule. It is shown here that this small molecule is an NAD derivative: adenosine diphosphate (ADP)-ribose 1"-2" cyclic phosphate. Evidence is also presented that this molecule is produced in Xenopus laevis oocytes as a result of dephosphorylation of ligated tRNA.

Pre-tRNA splicing: variation on a theme or exception to the rule?

There has been a growing recognition that there are many conserved features among apparently diverse RNA splicing systems, suggesting that they may have a common origin. However, pre-tRNA splicing is an apparent exception in nearly all respects. Features of this unique class should be considered in any comprehensive discussion of the origin(s) of splicing and its implications for the evolution of gene structure.

A highly specific phosphatase from Saccharomyces cerevisiae implicated in tRNA splicing.

We identified and partially purified a phosphatase from crude extracts of Saccharomyces cerevisiae cells that can catalyze the last step of tRNA splicing in vitro. This phosphatase can remove the 2'-phosphate left over at the splice junction after endonuclease has removed the intron and ligase has joined together the two half-molecules. We suggest that this phosphatase is responsible for the completion of tRNA splicing in vivo, based primarily on its specificity for the 2'-phosphate of spliced tRNA and on the resistance of the splice junction 2'-phosphate to a nonspecific phosphatase. Removal of the splice junction 2'-phosphate from the residue adjacent to the anticodon is likely necessary for efficient expression of spliced tRNA. The phosphatase appears to be composed of at least two components which, together with endonuclease and ligase, can be used to reconstitute the entire tRNA-splicing reaction.

Conserved mechanism of tRNA splicing in eukaryotes.

The ligation steps of tRNA splicing in yeast and vertebrate cells have been thought to proceed by fundamentally different mechanisms. Ligation in yeast cells occurs by incorporation of an exogenous phosphate from ATP into the splice junction, with concomitant formation of a 2' phosphate at the 5' junction nucleotide. This phosphate is removed in a subsequent step which, in vitro, is catalyzed by an NAD-dependent dephosphorylating activity. In contrast, tRNA ligation in vertebrates has been reported to occur without incorporation of exogenous phosphate or formation of a 2' phosphate. We demonstrate in this study the existence of a yeast tRNA ligase-like activity in HeLa cells. Furthermore, in extracts from these cells, the entire yeastlike tRNA splicing machinery is intact, including that for cleavage, ligation, and removal of the 2' phosphate in an NAD-dependent fashion to give mature tRNA. These results argue that the mechanism of tRNA splicing is conserved among eukaryotes.

TPD1 of Saccharomyces cerevisiae encodes a protein phosphatase 2C-like activity implicated in tRNA splicing and cell separation.

The Saccharomyces cerevisiae TPD1 gene has been implicated in tRNA splicing because a tpd1-1 mutant strain accumulates unspliced precursor tRNAs at high temperatures (W. H. van Zyl, N. Wills, and J. R. Broach, Genetics 123:55-68, 1989). The wild-type TPD1 gene was cloned by complementation of the tpd1-1 mutation and shown to encode a protein with substantial homology to protein phosphatase 2C (PP2C) of higher eukaryotes. Expression of Tpd1p in Escherichia coli results in PP2C-like activity. Strains deleted for the TPD1 gene exhibit multiple phenotypes: temperature-sensitive growth, accumulation of unspliced precursor tRNAs, sporulation defects, and failure of cell separation during mitotic growth. On the basis of the presence of these observable phenotypes and the fact that Tpd1p accounts for a small percentage of the observed PP2C activity, we argue that Tpd1p is a unique member of the PP2C family.

Genomic analysis of biochemical function.

Establishing the linkage between an individual biochemical activity and the gene(s) specifying that activity has been facilitated by advances in mass spectrometry and affinity purification methods. In addition, a genomic protein array has been produced in yeast by fusing each yeast open reading frame to glutathione-S-transferase, thus linking each protein with its cognate gene. Purification and biochemical assay of pools of glutathione-S-transferase-open-reading-frame proteins allows analysis of the entire proteome for biochemical activities, followed by simple deconvolution to identify the responsible open reading frame. An alternative method to analyze large sets of proteins is the use of protein microarrays in which over 10,000 individual proteins can be immobilized and assayed on a single slide.

A brief consideration of the SOS inducing signal.

SOS functions are induced in E. coli by treatments that damage cellular DNA or interrupt its synthesis. The biochemical basis of induction is activation of the specific proteolytic activity of recA protein, which then inactivates the lexA repressor. We discuss the development of the inducing signal in the cell.

The chemical synthesis of oligoribonucleotides with selectively placed 2'-O-phosphates.

A phosphoramidite, solid support method for the chemical synthesis of oligoribonucleotides containing 2'-O-phosphate at a selected position is presented. Synthesis of these oligoribonucleotides is based on uridine- and adenosine-(2'-O-phosphate)-3'-phosphoramidites, and a new condition for removal of 2'-O-phosphate protecting groups, which does not cleave internucleotide bonds. The structure of oligoribonucleotides with 2'-O-phosphate has been proven by enzymatic digestions and dephosphorylation by yeast 2'-phosphotransferase.

Protein-protein interactions: methods for detection and analysis.

The function and activity of a protein are often modulated by other proteins with which it interacts. This review is intended as a practical guide to the analysis of such protein-protein interactions. We discuss biochemical methods such as protein affinity chromatography, affinity blotting, coimmunoprecipitation, and cross-linking; molecular biological methods such as protein probing, the two-hybrid system, and phage display: and genetic methods such as the isolation of extragenic suppressors, synthetic mutants, and unlinked noncomplementing mutants. We next describe how binding affinities can be evaluated by techniques including protein affinity chromatography, sedimentation, gel filtration, fluorescence methods, solid-phase sampling of equilibrium solutions, and surface plasmon resonance. Finally, three examples of well-characterized domains involved in multiple protein-protein interactions are examined. The emphasis of the discussion is on variations in the approaches, concerns in evaluating the results, and advantages and disadvantages of the techniques.

An enzyme from Saccharomyces cerevisiae uses NAD+ to transfer the splice junction 2'-phosphate from ligated tRNA to an acceptor molecule.

An enzyme from Saccharomyces cerevisiae which removes the splice junction 2'-phosphate from ligated tRNA appears to require NAD+. This two-component enzyme has been previously implicated in tRNA splicing because of its specificity for substrates bearing an internal 2'-phosphate and because of the absence of other observed proteins that can efficiently catalyze the same activity after fractionation of the extracts. We show here that component I of this enzyme is heat-stable, chromatographs as a small molecule, can be substituted efficiently by NAD+, and comigrates with NAD+ on a reversed-phase column. Dephosphorylation of ligated tRNA in the presence of component I or NAD+ is accompanied by stoichiometric transfer of the splice junction 2'-phosphate to an unidentified acceptor molecule.

Induction of SOS functions: regulation of proteolytic activity of E. coli RecA protein by interaction with DNA and nucleoside triphosphate.

Damage to cellular DNA or interruption of chromosomal DNA synthesis leads to induction of the SOS functions in E. coli. The immediate agent of induction is the RecA protein, which proteolytically cleaves and inactivates repressors, leading to induction of genes they control. RecA protein modified by tif mutations allows expression of SOS functions in the absence of inducing treatments. We show here that tif-mutant RecA protein is more efficient than wild-type RecA protein in interacting with DNA and nucleoside triphosphate. This result suggests that formation of a complex with DNA and nucleoside triphosphate is the critical event that activates RecA protein to destroy repressors after SOS-inducing treatments, and that damage to cellular DNA promotes this reaction by providing single-stranded DNA or active nucleoside triphosphate or both. Since dATP is the most effective nucleoside triphosphate in promoting repressor cleavage, we suggest that it is the natural cofactor of recA protein in vivo.

HeLa cells contain a 2'-phosphate-specific phosphotransferase similar to a yeast enzyme implicated in tRNA splicing.

We have previously shown that HeLa cells contain activities implicated in tRNA splicing in yeast, a ligase capable of joining tRNA half-molecules and an NAD-dependent activity capable of removing the 2'-phosphate created at the splice junction by the ligase (Zillmann, M., Gorovsky, M.A., and Phizicky, E.M. (1991) Mol. Cell. Biol. 11, 5410-5416). We show here that removal of the splice junction 2'-phosphate is, as in yeast, a 2'-phosphate-specific phosphotransfer reaction that produces the same, as yet unidentified, small molecule. This enzyme is highly specific for oligomeric substrates having internal 2'-phosphates. Oligomers bearing terminal 2'-phosphates are at least 50-fold less reactive and those bearing 5'- or 3'-terminal phosphates are at least 600-fold less reactive. The requirement for an internal 2'-phosphate can be satisfied by a substrate as small as a dimer.

Saccharomyces cerevisiae tRNA ligase. Purification of the protein and isolation of the structural gene.

The tRNA ligase protein of Saccharomyces cerevisiae is one of the components required for splicing of yeast tRNA precursors in vitro. We have purified this protein to near homogeneity using an affinity elution chromatographic step. Purified tRNA ligase is a 90-kDa protein that, in addition to catalyzing the ligation of tRNA half-molecules in the coupled splicing reaction, will also ligate an artificial substrate. Using this artificial substrate, we provide evidence for the existence of a previously predicted activated intermediate in the ligation reaction. The amino acid sequence of the amino-terminal end of the protein was determined, and we have used this information to isolate the structural gene from a library of yeast DNA. We prove that this DNA encodes the tRNA ligase protein by DNA sequencing and by demonstrating overproduction of the protein.

Structure and function of the yeast tRNA ligase gene.

We report here the DNA sequence of the entire coding region of the Saccharomyces cerevisiae tRNA ligase gene. tRNA ligase is one of two enzymes required for tRNA splicing in yeast, and the enzyme is likely a single polypeptide with multiple activities. We find that tRNA ligase is a basic protein of 827 amino acids corresponding to a molecular weight of approximately 95,400. The inferred amino acid sequence for tRNA ligase is not significantly homologous to that of other known proteins of similar activity. In addition to the tRNA ligase reading frame and several other unidentified open reading frames, we have found two open reading frames, ORF1 and ORF2, near the 5'-end of the ligase structural gene. One of these, ORF2, produces a divergent transcript which initiates only 125 nucleotides upstream of the tRNA ligase transcript, and is present in approximately the same relative abundance as the transcript for tRNA ligase.

A conditional lethal yeast phosphotransferase (tpt1) mutant accumulates tRNAs with a 2'-phosphate and an undermodified base at the splice junction.

tRNA splicing is essential in yeast and humans and presumably all eukaryotes. The first two steps of yeast tRNA splicing, excision of the intron by endonuclease and joining of the exons by tRNA ligase, leave a splice junction bearing a 2'-phosphate. Biochemical analysis suggests that removal of this phosphate in yeast is catalyzed by a highly specific 2'-phosphotransferase that transfers the phosphate to NAD to form ADP-ribose 1"-2" cyclic phosphate. 2'-Phosphotransferase catalytic activity is encoded by a single essential gene, TPT1, in the yeast Saccharomyces cerevisiae. We show here that Tpt1 protein is responsible for the dephosphorylation step of tRNA splicing in vivo because, during nonpermissive growth, conditional lethal tpt1 mutants accumulate 2'-phosphorylated tRNAs from eight different tRNA species that are known to be spliced. We show also that several of these tRNAs are undermodified at the splice junction residue, which is always located at the hypermodified position one base 3' of the anticodon. This result is consistent with previous results indicating that modification of the hypermodified position occurs after intron excision in the tRNA processing pathway, and implies that modification normally follows the dephosphorylation step of tRNA splicing in vivo.

Cytochrome c methyltransferase, Ctm1p, of yeast.

Cytochromes c from plants and fungi, but not higher animals, contain methylated lysine residues at specific positions, including for example, the trimethylated lysine at position 72 in iso-1-cytochrome c of the yeast Saccharomyces cerevisiae. Testing of 6,144 strains of S. cerevisiae, each overproducing a different open reading frame fused to glutathione S-transferase, previously revealed that YHR109w was associated with an activity that methylated horse cytochrome c. We show here that this open reading frame, denoted Ctm1p, is specifically responsible for trimethylating lysine 72 of iso-1-cytochrome c. Unmethylated forms of cytochrome c but not other proteins or nucleic acids are methylated in vitro by Ctm1p produced in S. cerevisiae or Escherichia coli. Iso-1-cytochrome c purified from a ctm1-Delta strain is not trimethylated in vivo, whereas the K72R mutant form, or the trimethylated Lys-72 form of iso-1-cytochrome c, are not significantly methylated by Ctm1p in vitro. Like apocytochrome c, but in contrast to holocytochrome c, Ctm lp is located in the cytosol, consistent with the view that the natural substrate is apocytochrome c. The ctm1-Delta strain lacking the methyltransferase did not exhibit any growth defect on a variety of media and growth conditions, and the unmethylated iso-1-cytochrome c was produced at the normal level and exhibited the normal activity in vivo. Ctm1p and cytochrome c were coordinately regulated during anaerobic to aerobic transition, a finding consistent with the view that this methyltransferase evolved to act on cytochrome c.