Isabelle Auzat

The NADH oxidase of Streptococcus pneumoniae : its involvement in competence and virulence

A soluble flavoprotein that reoxidizes NADH and reduces molecular oxygen to water was purified from the facultative anaerobic human pathogen Streptococcus pneumoniae. The nucleotide sequence of nox, the gene which encodes it, has been determined and was characterized at the functional and physiological level. Several nox mutants were obtained by insertion, nonsense or missense mutation. In extracts from these strains, no NADH oxidase activity could be measured, suggesting that a single enzyme encoded by nox, having a C44 in its active site, was utilizing O2 to oxidize NADH in S. pneumoniae. The growth rate and yield of the NADH oxidase‐deficient strains were not changed under aerobic or anaerobic conditions, but the efficiency of development of competence for genetic transformation during growth was markedly altered. Conditions that triggered competence induction did not affect the amount of Nox, as measured using Western blotting, indicating that nox does not belong to the competence‐regulated genetic network. The decrease in competence efficiency due to the nox mutations was similar to that due to the absence of oxygen in the nox+ strain, suggesting that input of oxygen into the metabolism via NADH oxidase was important for controlling competence development throughout growth. This was not related to regulation of nox expression by O2. Interestingly, the virulence and persistence in mice of a blood isolate was attenuated by a nox insertion mutation. Global cellular responses of S. pneumoniae, such as competence for genetic exchange or virulence in a mammalian host, could thus be modulated by oxygen via the NADH oxidase activity of the bacteria, although the bacterial energetic metabolism is essentially anaerobic. The enzymatic activity of the NADH oxidase coded by nox was probably involved in transducing the external signal, corresponding to O2 availability, to the cell metabolism and physiology; thus, this enzyme may function as an oxygen sensor. This work establishes, for the first time, the role of O2 in the regulation of pneumococcal transformability and virulence.

Structure of bacteriophage SPP1 tail reveals trigger for DNA ejection

The majority of known bacteriophages have long noncontractile tails (Siphoviridae) that serve as a pipeline for genome delivery into the host cytoplasm. The tail extremity distal from the phage head is an adsorption device that recognises the bacterial receptor at the host cell surface. This interaction generates a signal transmitted to the head that leads to DNA release. We have determined structures of the bacteriophage SPP1 tail before and after DNA ejection. The results reveal extensive structural rearrangements in the internal wall of the tail tube. We propose that the adsorption device–receptor interaction triggers a conformational switch that is propagated as a domino‐like cascade along the 1600 Å‐long helical tail structure to reach the head‐to‐tail connector. This leads to opening of the connector culminating in DNA exit from the head into the host cell through the tail tube.

Crystal structures of the small G protein Rap2A in complex with its substrate GTP, with GDP and with GTPgammaS.

The small G protein Rap2A has been crystallized in complex with GDP, GTP and GTPγS. The Rap2A–GTP complex is the first structure of a small G protein with its natural ligand GTP. It shows that the hydroxyl group of Tyr32 forms a hydrogen bond with the γ‐phosphate of GTP and with Gly13. This interaction does not exist in the Rap2A–GTPγS complex. Tyr32 is conserved in many small G proteins, which probably also form this hydrogen bond with GTP. In addition, Tyr32 is structurally equivalent to a conserved arginine that binds GTP in trimeric G proteins. The actual participation of Tyr32 in GTP hydrolysis is not yet clear, but several possible roles are discussed. The conformational changes between the GDP and GTP complexes are located essentially in the switch I and II regions as described for the related oncoprotein H‐Ras. However, the mobile segments vary in length and in the amplitude of movement. This suggests that even though similar regions might be involved in the GDP–GTP cycle of small G proteins, the details of the changes will be different for each G protein and will ensure the specificity of its interaction with a given set of cellular proteins.

Crystal Structure of Bacteriophage SPP1 Distal Tail Protein (gp19.1) A BASEPLATE HUB PARADIGM IN GRAM-POSITIVE INFECTING PHAGES

Siphophage SPP1 infects the Gram-positive bacterium Bacillus subtilis using its long non-contractile tail and tail-tip. Electron microscopy (EM) previously allowed a low resolution assignment of most orf products belonging to these regions. We report here the structure of the SPP1 distal tail protein (Dit, gp19.1). The combination of x-ray crystallography, EM, and light scattering established that Dit is a back-to-back dimer of hexamers. However, Dit fitting in the virion EM maps was only possible with a hexamer located between the tail-tube and the tail-tip. Structure comparison revealed high similarity between Dit and a central component of lactophage baseplates. Sequence similarity search expanded its relatedness to several phage proteins, suggesting that Dit is a docking platform for the tail adsorption apparatus in Siphoviridae infecting Gram-positive bacteria and that its architecture is a paradigm for these hub proteins. Dit structural similarity extends also to non-contractile and contractile phage tail proteins (gpVN and XkdM) as well as to components of the bacterial type 6 secretion system, supporting an evolutionary connection between all these devices.

Role of bacteriophage SPP1 tail spike protein gp21 on host cell receptor binding and trigger of phage DNA ejection

Bacteriophages recognize and bind specific receptors to infect suitable hosts. Bacteriophage SPP1 targets at least two receptors of the Bacillus subtilis cell envelope, the glucosylated wall teichoic acids and the membrane protein YueB. Here, we identify a key virion protein for YueB binding and for the trigger of DNA ejection. Extracts from B. subtilis‐infected cells applied to a YueB affinity matrix led to preferential capturing of gp21 from SPP1. To assess the significance of this interaction, we isolated mutant phages specifically affected in YueB binding. The mutants exhibited a very low inactivation rate and a strong defect to eject DNA when challenged with YueB. The phenotype correlated with presence of a single amino acid substitution in the gp21 carboxyl terminus, defining a region involved in YueB binding. Immunoelectron microscopy located the gp21 N‐terminus in the SPP1 cap and probably in the adjacent tail spike region whereas the gp21 C‐terminus was mapped further down in the spike structure. Antibodies against this part of gp21 interfered with the interaction of YueB with SPP1 and triggered DNA ejection. The gp21 C‐terminal region thus plays a central role in two early key events that commit the virus to deliver its genome into host cells.

The Opening of the SPP1 Bacteriophage Tail, a Prevalent Mechanism in Gram-positive-infecting Siphophages

The SPP1 siphophage uses its long non-contractile tail and tail tip to recognize and infect the Gram-positive bacterium Bacillus subtilis. The tail-end cap and its attached tip are the critical components for host recognition and opening of the tail tube for genome exit. In the present work, we determined the cryo-electron microscopic (cryo-EM) structure of a complex formed by the cap protein gp19.1 (Dit) and the N terminus of the downstream protein of gp19.1 in the SPP1 genome, gp211–552 (Tal). This complex assembles two back-to-back stacked gp19.1 ring hexamers, interacting loosely, and two gp211–552 trimers interacting with gp19.1 at both ends of the stack. Remarkably, one gp211–552 trimer displays a “closed” conformation, whereas the second is “open” delineating a central channel. The two conformational states dock nicely into the EM map of the SPP1 cap domain, respectively, before and after DNA release. Moreover, the open/closed conformations of gp19.1-gp211–552 are consistent with the structures of the corresponding proteins in the siphophage p2 baseplate, where the Tal protein (ORF16) attached to the ring of Dit (ORF15) was also found to adopt these two conformations. Therefore, the present contribution allowed us to revisit the SPP1 tail distal-end architectural organization. Considering the sequence conservation among Dit and the N-terminal region of Tal-like proteins in Gram-positive-infecting Siphoviridae, it also reveals the Tal opening mechanism as a hallmark of siphophages probably involved in the generation of the firing signal initiating the cascade of events that lead to phage DNA release in vivo.

Origin and function of the two major tail proteins of bacteriophage SPP1

The majority of bacteriophages have a long non‐contractile tail (Siphoviridae) that serves as a conduit for viral DNA traffic from the phage capsid to the host cell at the beginning of infection. The 160‐nm‐long tail tube of Bacillus subtilis bacteriophage SPP1 is shown to be composed of two major tail proteins (MTPs), gp17.1 and gp17.1*, at a ratio of about 3:1. They share a common amino‐terminus, but the latter species has ∼10 kDa more than gp17.1. A CCC.UAA sequence with overlapping proline codons at the 3′ end of gene 17.1 drives a programmed translational frameshift to another open reading frame. The recoding event generates gp17.1*. Phages carrying exclusively gp17.1 or gp17.1* are viable, but tails are structurally distinct. gp17.1 and the carboxyl‐terminus of gp17.1* have a distinct evolutionary history correlating with different functions: the polypeptide sequence identical in the two proteins is responsible for assembly of the tail tube while the additional module of gp17.1* shields the structure exterior exposed to the environment. The carboxyl‐terminal extension is an elaboration present in some tailed bacteriophages. Different extensions were found to combine in a mosaic fashion with the MTP essential module in a subset of Siphoviridae genomes.

The role of Glu187 in the regulation of phosphofructokinase by phosphoenolpyruvate.

In bacterial phosphofructokinases, either a glutamic or an aspartic residue is present at position 187, and the mechanism of inhibition by phosphoenolpyruvate seems to be correlated to the nature of residue 187. Upon binding phosphoenolpyruvate, only the enzymes with a Glu187 would undergo a major allosteric conformational change from an active into an inactive state, whereas the enzymes with an Asp187 would only show a simple upward shift in their pH-profile of activity. The phosphofructokinase from Spiroplasma citri, which has an Asp187, has been purified and its properties follow this pattern. The behaviour of mutants of the enzyme from Escherichia coli in which Glu187 is replaced by either aspartate or leucine confirms the importance of residue 187. The major allosteric transition of E. coli phosphofructokinase is abolished by the substitution Glu187-->Asp, suggesting that a glutamate at position 187 is necessary (but not sufficient) for the protein to undergo the change from the active into the inactive state induced by phosphenolpyruvate. In addition, the presence of an acidic residue, aspartate or glutamate, at position 187 is required (but not sufficient) for the binding of ADP (or GDP). This requirement of a negative charge for ADP binding could explain the striking conservation of an aspartate residue at position 187 in all the eukaryotic phosphofructokinases.

Solution structure of gp17 from the Siphoviridae bacteriophage SPP1: insights into its role in virion assembly.

Solution structure of gp17 from the Siphoviridae bacteriophage SPP1: Insights into its role in virion assembly Benjamin Chagot, Isabelle Auzat, Matthieu Gallopin, Isabelle Petitpas, Bernard Gilquin, Paulo Tavares, and Sophie Zinn-Justin* 1 Laboratoire de Biologie Structurale et Radiobiologie, iBiTec-S and URA CNRS 2096, CEA Saclay, Gif-sur-Yvette, France 2 Laboratoire de Virologie Moléculaire et Structurale, Centre de Recherche de Gif, CNRS UPR 3296 and IFR 115, 91198 Gif-sur-Yvette, France

Bacteriophage SPP1 tail tube protein self-assembles into β-structure-rich tubes.

Background: In most bacteriophages, a long tail primarily built from tail tube proteins serves as a conduit for DNA delivery into the bacteria. Results: The tail tube protein of phage SPP1 self-assembles into tubes exhibiting a phage tail-like helical architecture. Conclusion: A three-dimensional model is proposed for the self-assembled tubes. Significance: This work opens the way for the generation of artificial tubular structures. The majority of known bacteriophages have long tails that serve for bacterial target recognition and viral DNA delivery into the host. These structures form a tube from the viral capsid to the bacterial cell. The tube is formed primarily by a helical array of tail tube protein (TTP) subunits. In phages with a contractile tail, the TTP tube is surrounded by a sheath structure. Here, we report the first evidence that a phage TTP, gp17.1 of siphophage SPP1, self-assembles into long tubes in the absence of other viral proteins. gp17.1 does not exhibit a stable globular structure when monomeric in solution, even if it was confidently predicted to adopt the β-sandwich fold of phage λ TTP. However, Fourier transform infrared and nuclear magnetic resonance spectroscopy analyses showed that its β-sheet content increases significantly during tube assembly, suggesting that gp17.1 acquires a stable β-sandwich fold only after self-assembly. EM analyses revealed that the tube is formed by hexameric rings stacked helicoidally with the same organization and helical parameters found for the tail of SPP1 virions. These parameters were used to build a pseudo-atomic model of the TTP tube. The large loop spanning residues 40–56 is located on the inner surface of the tube, at the interface between adjacent monomers and hexamers. In line with our structural predictions, deletion of this loop hinders gp17.1 tube assembly in vitro and interferes with SPP1 tail assembly during phage particle morphogenesis in bacteria.