Martine Roovers

Detection of enzymatic activity of transfer RNA modification enzymes using radiolabeled tRNA substrates.

The presence of modified ribonucleotides derived from adenosine, guanosine, cytidine, and uridine is a hallmark of almost all cellular RNA, and especially tRNA. The objective of this chapter is to describe a few simple methods that can be used to identify the presence or absence of a modified nucleotide in tRNA and to reveal the enzymatic activity of particular tRNA-modifying enzymes in vitro and in vivo. The procedures are based on analysis of prelabeled or postlabeled nucleotides (mainly with [(32)P] but also with [(35)S], [(14)C] or [(3)H]) generated after complete digestion with selected nucleases of modified tRNA isolated from cells or incubated in vitro with modifying enzyme(s). Nucleotides of the tRNA digests are separated by two-dimensional (2D) thin-layer chromatography on cellulose plates (TLC), which allows establishment of base composition and identification of the nearest neighbor nucleotide of a given modified nucleotide in the tRNA sequence. This chapter provides useful maps for identification of migration of approximately 70 modified nucleotides on TLC plates by use of two different chromatographic systems. The methods require only a few micrograms of purified tRNA and can be run at low cost in any laboratory.

Formation of the conserved pseudouridine at position 55 in archaeal tRNA

Pseudouridine (Ψ) located at position 55 in tRNA is a nearly universally conserved RNA modification found in all three domains of life. This modification is catalyzed by TruB in bacteria and by Pus4 in eukaryotes, but so far the Ψ55 synthase has not been identified in archaea. In this work, we report the ability of two distinct pseudouridine synthases from the hyperthermophilic archaeon Pyrococcus furiosus to specifically modify U55 in tRNA in vitro. These enzymes are pfuCbf5, a protein known to play a role in RNA-guided modification of rRNA, and pfuPsuX, a previously uncharacterized enzyme that is not a member of the TruB/Pus4/Cbf5 family of pseudouridine synthases. pfuPsuX is hereafter renamed pfuPus10. Both enzymes specifically modify tRNA U55 in vitro but exhibit differences in substrate recognition. In addition, we find that in a heterologous in vivo system, pfuPus10 efficiently complements an Escherichia coli strain deficient in the bacterial Ψ55 synthase TruB. These results indicate that it is probable that pfuCbf5 or pfuPus10 (or both) is responsible for the introduction of pseudouridine at U55 in tRNAs in archaea. While we cannot unequivocally assign the function from our results, both possibilities represent unexpected functions of these proteins as discussed herein.

The yggH Gene of Escherichia coli Encodes a tRNA (m7G46) Methyltransferase

We cloned, expressed, and purified the Escherichia coli YggH protein and show that it catalyzes the S-adenosyl-L-methionine-dependent formation of N(7)-methylguanosine at position 46 (m(7)G46) in tRNA. Additionally, we generated an E. coli strain with a disrupted yggH gene and show that the mutant strain lacks tRNA (m(7)G46) methyltransferase activity.

The evolutionary history of carbamoyltransferases: A complex set of paralogous genes was already present in the last universal common ancestor.

Abstract. Forty-four sequences of ornithine carbamoyltransferases (OTCases) and 33 sequences of aspartate carbamoyltransferases (ATCases) representing the three domains of life were multiply aligned and a phylogenetic tree was inferred from this multiple alignment. The global topology of the composite rooted tree (each enzyme family being used as an outgroup to root the other one) suggests that present-day genes are derived from paralogous ancestral genes which were already of the same size and argues against a mechanism of fusion of independent modules. A closer observation of the detailed topology shows that this tree could not be used to assess the actual order of organismal descent. Indeed, this tree displays a complex topology for many prokaryotic sequences, with polyphyly for Bacteria in both enzyme trees and for the Archaea in the OTCase tree. Moreover, representatives of the two prokaryotic Domains are found to be interspersed in various combinations in both enzyme trees. This complexity may be explained by assuming the occurrence of two subfamilies in the OTCase tree (OTC α and OTC β) and two other ones in the ATCase tree (ATC I and ATC II). These subfamilies could have arisen from duplication and selective losses of some differentiated copies during the successive speciations. We suggest that Archaea and Eukaryotes share a common ancestor in which the ancestral copies giving the present-day ATC II/OTC β combinations were present, whereas Bacteria comprise two classes: one containing the ATC II/OTC α combination and the other harboring the ATC I/OTC β combination. Moreover, multiple horizontal gene transfers could have occurred rather recently amongst prokaryotes. Whichever the actual history of carbamoyltransferases, our data suggest that the last common ancestor to all extant life possessed differentiated copies of genes coding for both carbamoyltransferases, indicating it as a rather sophisticated organism.

Molecular interactions in the control region of the carAB operon encoding Escherichia coli carbamoylphosphate synthetase

The control region of the carAB operon, encoding carbamoylphosphate synthetase, comprises two tandem promoters (P1, upstream and P2, downstream) located 67 base-pairs apart and repressed respectively by pyrimidines and arginine. RNA polymerase and pure arginine repressor bind to the P2 region in mutually exclusive ways. Repressor protects the two adjacent palindromic ARG boxes overlapping P2 against DNase I. Binding of RNA polymerase to P1 is abnormal; the region protected against DNase I is shifted upstream by about 20 nucleotides with respect to the position expected from the transcription startpoint. This pattern is not due to interference with polymerase binding at P2, since it is observed also in the presence of repressor and on an isolated P1 region. Binding of RNA polymerase is relatively weak and heparin-sensitive suggesting that, in vivo, an ancillary factor is required to promote the formation of an open complex. S1 nuclease mapping experiments show that the simultaneous presence of pyrimidines and arginine represses the downstream arginine-specific promoter (P2) more efficiently than arginine alone. This effect is not due to a direct regulatory interaction between pyrimidines and P2, since it is not observed when P1 is inactivated by insertion mutations or partial deletion. It has been shown that transcription initiated at P1 can proceed even when arginine represses P2. We therefore suggest that P2 operator-arginine repressor complex is destabilized by RNA polymerase binding at P1 or transcription from P1. We describe a novel technique to select for expression-down mutants in a lac fusion context.

Experimental Evolution of Enzyme Temperature Activity Profile: Selection In Vivo and Characterization of Low-Temperature-Adapted Mutants of Pyrococcus furiosus Ornithine Carbamoyltransferase

We have obtained mutants of Pyrococcus furiosus ornithine carbamoyltransferase active at low temperatures by selecting for complementation of an appropriate yeast mutant after in vivo mutagenesis. The mutants were double ones, still complementing at 15 degrees C, a temperature already in the psychrophilic range. Their kinetic analysis is reported.

New archaeal methyltransferases forming 1-methyladenosine or 1-methyladenosine and 1-methylguanosine at position 9 of tRNA

Two archaeal tRNA methyltransferases belonging to the SPOUT superfamily and displaying unexpected activities are identified. These enzymes are orthologous to the yeast Trm10p methyltransferase, which catalyses the formation of 1-methylguanosine at position 9 of tRNA. In contrast, the Trm10p orthologue from the crenarchaeon Sulfolobus acidocaldarius forms 1-methyladenosine at the same position. Even more surprisingly, the Trm10p orthologue from the euryarchaeon Thermococcus kodakaraensis methylates the N1-atom of either adenosine or guanosine at position 9 in different tRNAs. This is to our knowledge the first example of a tRNA methyltransferase with a broadened nucleoside recognition capability. The evolution of tRNA methyltransferases methylating the N1 atom of a purine residue is discussed.

Cloning and identification of the Sulfolobus solfataricus lrp gene encoding an archaeal homologue of the eubacterial leucine-responsive global transcriptional regulator Lrp.

The lrp gene of the extreme thermophilic archaeon Sulfolofus solfataricus, encoding a homologue of the eubacterial global leucine-responsive regulatory protein, was identified by DNA sequencing and sequence comparisons on a 6.9-kb genomic fragment cloned into Escherichia coli. The S. solfataricus Lrp subunit is a 155-aa polypeptide that bears between 24.5 and 29% sequence identity with eubacterial regulatory proteins of the Lrp/AsnC family and 30.6% and 25.8% with the archaeal homologues of respectively Methanococcus jannaschii and Pyrococcus furiosus. Transcription initiation from the strong S. solfataricus lrp promoter was analyzed by primer extension mapping. The abundance of the S. solfataricus lrp messenger strongly suggests that this protein might function in archaea as a global transcriptional regulator and genome organizer, as proposed for E. coli Lrp, rather than as a local, specific regulatory protein. Our findings suggest the presence of a eubacterial type of regulatory mechanism in archaea, a situation that is noteworthy indeed, since the transcriptional machinery of archaea is more closely related to that of eukaryotes, whereas these latter apparently do not possess a homologue of Lrp.

Integration Host Factor (IHF) modulates the expression of the pyrimidine-specific promoter of the carAB operons of Escherichia coli K12 and Salmonella typhimurium LT2

SummaryWe report the identification of Integration Host Factor (IHF) as a new element involved in modulation of P1, the upstream pyrimidine-specific promoter of the Escherichia coli K12 and Salmonella typhimurium carAB operons. Band-shift assays, performed with S-30 extracts of the wild type and a himA, hip double mutant or with purified IHF demonstrate that, in vitro, this factor binds to a region 300 by upstream of the transcription initiation site of P1 in both organisms. This was confirmed by deletion analysis of the target site. DNase I, hydroxyl radical and dimethylsulphate footprinting experiments allowed us to allocate the IHF binding site to a 38 bp, highly A + T-rich stretch, centred around nucleotide −305 upstream of the transcription initiation site. Protein-DNA contacts are apparently spread over a large number of bases and are mainly located in the minor groove of the helix. Measurements of carbamoyl-phosphate synthetase (CPSase) and β-galactosidase specific activities from car-lacZ fusion constructs of wild type or IHF target site mutants introduced into several genetic backgrounds affected in the himA gene or in the pyrimidine-mediated control of P1 (carP6 or pyrH±), or in both, indicate that, in vivo, IHF influences P1 activity as well as its control by pyrimidines. IHF stimulates P1 promoter activity in minimal medium, but increases the repressibility of this promoter by pyrimidines. These antagonistic effects result in a two- to threefold reduction in the repressibility of promoter P 1 by pyrimidines in the absence of IHF binding. IHF thus appears to be required for maximal expression as well as for establishment of full repression. IHF could exert this function by modulating the binding of a pyrimidine-specific regulatory molecule.

CarP, a novel gene regulating the transcription of the carbamoylphosphate synthetase operon of Escherichia coli☆

The carAB operon, encoding carbamoylphosphate synthetase (CPSase; EC 6.3.5.5) is transcribed from two tandem promoters. The upstream promoter (P1) is controlled by pyrimidines and the downstream promoter (P2) is controlled by arginine. We have isolated a new type of constitutive mutation (carP) that specifically affects the control of the pyrimidine-sensitive promoter but does not appear to influence other genes of the pyrimidine pathway. The carP mutation acts in trans and is dominant, which suggests that the carP product is an activator of car transcription. The downstream promoter P2, which is repressed by arginine, overlaps two operator modules characteristic of the arginine regulon. We have isolated two operator-constitutive mutations that specifically affect P2; both map in the upstream ARG box at a strongly conserved position.