Isidre Gibert

The Ribonucleotide Reductase System of Lactococcus lactis CHARACTERIZATION OF AN NrdEF ENZYME AND A NEW ELECTRON TRANSPORT PROTEIN

Escherichia coli contains the genetic information for three separate ribonucleotide reductases. Two of them (class I enzymes), coded by the nrdAB and nrdEF genes, respectively, contain a tyrosyl radical, whose generation requires oxygen. The NrdAB enzyme is physiologically active. The function of the nrdEF gene is not known. The third enzyme (class III), coded by nrdDG, operates during anaerobiosis. The DNA of Lactococcus lactis contains sequences homologous to the nrdDG genes. Surprisingly, an nrdD mutant of L. lactis grew well under standard anaerobic growth conditions. The ribonucleotide reductase system of this mutant was shown to consist of an enzyme of the NrdEF-type and a small electron transport protein. The coding operon contains the nrdEF genes and two open reading frames, one of which (nrdH) codes for the small protein. The same gene organization is present in E. coli. We propose that the aerobic class I ribonucleotide reductases contain two subclasses, one coded by nrdAB, active in E. coli and eukaryotes (class Ia), the other coded by nrdEF, present in various microorganisms (class Ib). The NrdEF enzymes use NrdH proteins as electron transporter in place of thioredoxin or glutaredoxin used by NrdAB enzymes. The two classes also differ in their allosteric regulation by dATP.

Promoter identification and expression analysis of Salmonella typhimurium and Escherichia coli nrdEF operons encoding one of two class I ribonucleotide reductases present in both bacteria

Salmonella typhimurium and Escherichia coli cells have two different class I ribonucleotide reductases encoded by the nrdEF and nrdAB operons. Despite the presence of one additional ribonucleotide reductase, the nrdAB‐encoded enzyme is essential to the aerobic growth of the cell because nrdAB‐defective mutants of both species are not viable in the presence of oxygen. Several factors controlling nrdAB gene transcription have been analysed intensively. Nothing is known about the expression of the nrdEF genes. To study this subject, and after cloning of E. coli nrdEF genes and sequencing of their 5′ ends, the promoter of this operon has been identified by primer extension in both bacterial species. The + 1 position was 691 bp and 692 bp upstream of the translational start points of the nrdE genes of S. typhimurium and E. coli, respectively. Downstream of the + 1 position, and before the nrdE gene, two open reading frames (ORFs) of 81 and 136 amino acid residues are present in both bacteria. The synthesis of a polypeptide with a molecular mass of 9 kDa, corresponding to the first of these two ORFs, was observed by using the T7 RNA polymerase expression system. Comparison of the amino acid predicted sequence of this ORF reveals a significant similarity with glutaredoxin proteins. Competitive, reverse‐transcription polymerase chain reaction experiments indicate that transcription from the nrdEF promoter normally takes place in wild‐type cells. nrdEF transcription is increased by hydroxyurea, which inhibits class I ribonucleotide reductase activity, in both RecA+ and RecA− cells. nrdAts mutants show a higher level of nrdEF transcription than wild‐type cells at either the permissive or the restrictive temperature. nrdEF expression was unaffected by changes in DNA supercoiling whether caused by the introduction of either topA ::Tn10 and hns ::Tn10 mutations or by the inhibition of DNA gyrase with the antibiotic novobiocin. In contrast to the nrdAB genes, the nrdEF operon is not essential to the cells because nrdEF‐defective mutants are viable under both aerobic and anaerobic conditions.

Ribonucleotide Reductases: Divergent Evolution of an Ancient Enzyme

Abstract. Ribonucleotide reductases (RNRs) are uniquely responsible for converting nucleotides to deoxynucleotides in all dividing cells. The three known classes of RNRs operate through a free radical mechanism but differ in the way in which the protein radical is generated. Class I enzymes depend on oxygen for radical generation, class II uses adenosylcobalamin, and the anaerobic class III requires S-adenosylmethionine and an iron–sulfur cluster. Despite their metabolic prominence, the evolutionary origin and relationships between these enzymes remain elusive. This gap in RNR knowledge can, to a major extent, be attributed to the fact that different RNR classes exhibit greatly diverged polypeptide chains, rendering homology assessments inconclusive. Evolutionary studies of RNRs conducted until now have focused on comparison of the amino acid sequence of the proteins, without considering how they fold into space. The present study is an attempt to understand the evolutionary history of RNRs taking into account their three-dimensional structure. We first infer the structural alignment by superposing the equivalent stretches of the three-dimensional structures of representatives of each family. We then use the structural alignment to guide the alignment of all publicly available RNR sequences. Our results support the hypothesis that the three RNR classes diverged from a common ancestor currently represented by the anaerobic class III. Also, lateral transfer appears to have played a significant role in the evolution of this protein family.

Distribution of insertion sequence IS200 in Salmonella and Shigella

Two DNA probes for the detection of insertion sequence IS200 by either Southern blotting or colony hybridization were constructed. One of the probes is a 300 bp EcoRI-HindIII fragment of IS200 cloned onto pBluescript KS(+); the other is a tail-to-tail dimer of the same fragment cloned onto pUC19. A survey of the presence of IS200 among enteric bacteria revealed that more than 90% of the pathogenic or food-poisoning isolates of Salmonella spp. examined contained one or more copies of insertion sequence IS200, with the exception of the subgenus I serovar S. agona in which IS200 is not found. Although insertion sequence IS200 was first considered a Salmonella-specific element, it also exists in many isolates of Shigella sonnei and Shigella flexneri, but not in Shigella dysenteriae.

The Active Form of the R2F Protein of Class Ib Ribonucleotide Reductase from Corynebacterium ammoniagenes Is a Diferric Protein

Corynebacterium ammoniagenes contains a ribonucleotide reductase (RNR) of the class Ib type. The small subunit (R2F) of the enzyme has been proposed to contain a manganese center instead of the dinuclear iron center, which in other class I RNRs is adjacent to the essential tyrosyl radical. The nrdF gene of C. ammoniagenes, coding for the R2F component, was cloned in an inducibleEscherichia coli expression vector and overproduced under three different conditions: in manganese-supplemented medium, in iron-supplemented medium, and in medium without addition of metal ions. A prominent typical tyrosyl radical EPR signal was observed in cells grown in rich medium. Iron-supplemented medium enhanced the amount of tyrosyl radical, whereas cells grown in manganese-supplemented medium had no such radical. In highly purified R2F protein, enzyme activity was found to correlate with tyrosyl radical content, which in turn correlated with iron content. Similar results were obtained for the R2F protein of Salmonella typhimurium class Ib RNR. The UV-visible spectrum of the C. ammoniagenes R2F radical has a sharp 408-nm band. Its EPR signal at g = 2.005 is identical to the signal of S. typhimurium R2F and has a doublet with a splitting of 0.9 millitesla (mT), with additional hyperfine splittings of 0.7 mT. According to X-band EPR at 77–95 K, the inactive manganese form of the C. ammoniagenes R2F has a coupled dinuclear Mn(II) center. Different attempts to chemically oxidize Mn-R2F showed no relation between oxidized manganese and tyrosyl radical formation. Collectively, these results demonstrate that enzymatically active C. ammoniagenes RNR is a generic class Ib enzyme, with a tyrosyl radical and a diferric metal cofactor.

NrdI Essentiality for Class Ib Ribonucleotide Reduction in Streptococcus pyogenes

The Streptococcus pyogenes genome harbors two clusters of class Ib ribonucleotide reductase genes, nrdHEF and nrdF*I*E*, and a second stand-alone nrdI gene, designated nrdI2. We show that both clusters are expressed simultaneously as two independent operons. The NrdEF enzyme is functionally active in vitro, while the NrdE*F* enzyme is not. The NrdF* protein lacks three of the six highly conserved iron-liganding side chains and cannot form a dinuclear iron site or a tyrosyl radical. In vivo, on the other hand, both operons are functional in heterologous complementation in Escherichia coli. The nrdF*I*E* operon requires the presence of the nrdI* gene, and the nrdHEF operon gained activity upon cotranscription of the heterologous nrdI gene from Streptococcus pneumoniae, while neither nrdI* nor nrdI2 from S. pyogenes rendered it active. Our results highlight the essential role of the flavodoxin NrdI protein in vivo, and we suggest that it is needed to reduce met-NrdF, thereby enabling the spontaneous reformation of the tyrosyl radical. The NrdI* flavodoxin may play a more direct role in ribonucleotide reduction by the NrdF*I*E* system. We discuss the possibility that the nrdF*I*E* operon has been horizontally transferred to S. pyogenes from Mycoplasma spp.

The anaerobic (Class III) ribonucleotide reductase from Lactococcus lactis: Catalytic properties and allosteric regulation of the pure enzyme system

Lactococcus lactis contains an operon with the genes (nrdD and nrdG) for a class III ribonucleotide reductase. Strict anaerobic growth depends on the activity of these genes. Both were sequenced, cloned, and overproduced in Escherichia coli. The corresponding proteins, NrdD and NrdG, were purified close to homogeneity. The amino acid sequences of NrdD (747 residues, 84.1 kDa) and NrdG (199 residues, 23.3 kDa) are 53 and 42% identical with the respective E. coli proteins. Together, they catalyze the reduction of ribonucleoside triphosphates to the corresponding deoxyribonucleotides in the presence ofS-adenosylmethionine, reduced flavodoxin or reduced deazaflavin, potassium ions, dithiothreitol, and formate. EPR experiments demonstrated a [4Fe-4S]+ cluster in reduced NrdG and a glycyl radical in activated NrdD, similar to the E. coli NrdD and NrdG proteins. Different from E. coli, the two polypeptides of NrdD and the proteins in the NrdD-NrdG complex were only loosely associated. Also the FeS cluster was easily lost from NrdG. The substrate specificity and overall activity of the L. lactis enzyme was regulated according to the general rules for ribonucleotide reductases. Allosteric effectors bound to two separate sites on NrdD, one binding dATP, dGTP, and dTTP and the other binding dATP and ATP. The two sites showed an unusually high degree of cooperativity with complex interactions between effectors and a fine-tuning of their physiological effects. The results with theL. lactis class III reductase further support the concept of a common origin for all present day ribonucleotide reductases.

Measurement of in vivo expression of nrdA and nrdB genes of Escherichia coli by using IacZ gene fusions

SummaryBy using a promoter probe plasmid we investigated expression of the linked nrdA and nrdB genes coding for the two different subunits of the ribonucleoside diphosphate reductase enzyme of Escherichia coli. For this reason, nrdA-lacZ, nrdAB-lacZ and nrdB-lacZ fusions were constructed. Results obtained indicate that the nrdB gene has a promoter from which it may be transcribed independently of the nrdA gene. Furthermore, the nrdB gene may also be transcribed from the nrdA promoter. The expression of the nrdB gene is about 14-fold higher from the nrdA promoter than from its own promoter. The induction of both nrdA and nrdB genes by DNA-damaging agents in the wild-type strain as well as in several SOS mutants was also studied; nrdA gene expression was increased by these treatments in RecA–, RecA−, and LexAInd− strains, although in both RecA− and LexAInd− mutants the nrdA gene expression was considerably lower than that in RecA– cells. nrdB gene expression was stimulated by DNA damage only when its transcription was from the nrdA promoter, but there was no effect when nrdB was transcribed from its own promoter. In addition, the basal level of nrdA-lacZ and nrdAB-lacZ fusions was reduced in strains containing either RecA− and LexAInd− mutations or a multicopy plasmid carrying the lexA– gene, whereas the presence of a LexA5lDef mutation increased the constitutive expression of both fusions. On the contrary, the basal level of the nrdB-lacZ fusion remained constant in all these strains. Together these results indicate that induction of the SOS response enhances expression of the nrd genes from the nrdA promoter.

Animals devoid of pulmonary system as infection models in the study of lung bacterial pathogens.

Biological disease models can be difficult and costly to develop and use on a routine basis. Particularly, in vivo lung infection models performed to study lung pathologies use to be laborious, demand a great time and commonly are associated with ethical issues. When infections in experimental animals are used, they need to be refined, defined, and validated for their intended purpose. Therefore, alternative and easy to handle models of experimental infections are still needed to test the virulence of bacterial lung pathogens. Because non-mammalian models have less ethical and cost constraints as a subjects for experimentation, in some cases would be appropriated to include these models as valuable tools to explore host–pathogen interactions. Numerous scientific data have been argued to the more extensive use of several kinds of alternative models, such as, the vertebrate zebrafish (Danio rerio), and non-vertebrate insects and nematodes (e.g., Caenorhabditis elegans) in the study of diverse infectious agents that affect humans. Here, we review the use of these vertebrate and non-vertebrate models in the study of bacterial agents, which are considered the principal causes of lung injury. Curiously none of these animals have a respiratory system as in air-breathing vertebrates, where respiration takes place in lungs. Despite this fact, with the present review we sought to provide elements in favor of the use of these alternative animal models of infection to reveal the molecular signatures of host–pathogen interactions.

Abundance of the Quorum-Sensing Factor Ax21 in Four Strains of Stenotrophomonas maltophilia Correlates with Mortality Rate in a New Zebrafish Model of Infection

Stenotrophomonas maltophilia is a Gram-negative pathogen with emerging nosocomial incidence. Little is known about its pathogenesis and the genomic diversity exhibited by clinical isolates complicates the study of pathogenicity and virulence factors. Here, we present a strategy to identify such factors in new clinical isolates of S. maltophilia, incorporating an adult-zebrafish model of S. maltophilia infection to evaluate relative virulence coupled to 2D difference gel electrophoresis to explore underlying differences in protein expression. In this study we report upon three recent clinical isolates and use the collection strain ATCC13637 as a reference. The adult-zebrafish model shows discrimination capacity, i.e. from very low to very high mortality rates, with clinical symptoms very similar to those observed in natural S. maltophilia infections in fish. Strain virulence correlates with resistance to human serum, in agreement with previous studies in mouse and rat and therefore supporting zebrafish as a replacement model. Despite its clinical origin, the collection strain ATCC13637 showed obvious signs of attenuation in zebrafish, with null mortality. Multilocus-sequence-typing analysis revealed that the most virulent strains, UV74 and M30, exhibit the strongest genetic similitude. Differential proteomic analysis led to the identification of 38 proteins with significantly different abundance in the three clinical strains relative to the reference strain. Orthologs of several of these proteins have been already reported to have a role in pathogenesis, virulence or resistance mechanisms thus supporting our strategy. Proof of concept is further provided by protein Ax21, whose abundance is shown here to be directly proportional to mortality in the zebrafish infection model. Indeed, recent studies have demonstrated that this protein is a quorum-sensing-related virulence factor.