Muguette Jéhanno

NLRX1 is a mitochondrial NOD-like receptor that amplifies NF-κB and JNK pathways by inducing reactive oxygen species production

NOD‐like receptors (NLRs) are a family of intracellular sensors of microbial‐ or danger‐associated molecular patterns. Here, we report the identification of NLRX1, which is a new member of the NLR family that localizes to the mitochondria. NLRX1 alone failed to trigger most of the common signalling pathways, including nuclear factor‐κB (NF)‐κB‐ and type I interferon‐dependent cascades, but could potently trigger the generation of reactive oxygen species (ROS). Importantly, NLRX1 synergistically potentiated ROS production induced by tumour necrosis factor α, Shigella infection and double‐stranded RNA, resulting in amplified NF‐κB‐dependent and JUN amino‐terminal kinases‐dependent signalling. Together, these results identify NLRX1 as a NLR that contributes to the link between ROS generation at the mitochondria and innate immune responses.

Murine Nod1 but not its human orthologue mediates innate immune detection of tracheal cytotoxin

Tracheal cytotoxin (TCT) was originally described as the minimal effector that was able to reproduce the cytotoxic response of Bordetella pertussis on ciliated epithelial cells. This molecule triggers pleiotropic effects such as immune stimulation or slow‐wave sleep modulation. Further characterization identified TCT as a specific diaminopimelic acid (DAP)‐containing muropeptide, GlcNAc‐(anhydro)MurNAc‐L‐Ala‐D‐Glu‐mesoDAP‐D‐Ala. Here, we show that the biological activity of TCT depends on Nod1, an intracellular sensor of bacterial peptidoglycan. However, Nod1‐dependent detection of TCT was found to be host specific, as human Nod1 (hNod1) poorly detected TCT, whereas mouse Nod1 (mNod1) did so efficiently. More generally, hNod1 required a tripeptide (L‐Ala‐D‐Glu‐mesoDAP) for efficient sensing of peptidoglycan, whereas mNod1 detected a tetrapeptide structure (L‐Ala‐D‐Glu‐mesoDAP‐D‐Ala). In murine macrophages, TCT stimulated cytokine secretion and NO production through Nod1. Finally, in vivo, injection of the tetrapeptide structure in mice triggered a transient yet strong release of cytokines into the bloodstream and the maturation of macrophages, in a Nod1‐dependent manner. This study thereby identifies Nod1 as the long sought after sensor of TCT in mammals.

Antigenicity and immunogenicity of the HIV-1 gp41 epitope ELDKWA inserted into permissive sites of the MalE protein

The highly conserved amino acid sequence ELDKWA of HIV-1 gp41 has been inserted into Escherichia coli MalE protein which had been shown to be an adequate carrier to present foreign epitopes to the immune system. We first investigated whether eight different permissive sites of MalE are able to tolerate an insertion of 7-50 residues encoding this epitope. Secondly, antigenicity of the epitope inserted in MalE protein was estimated from monoclonal antibody 2F5 binding analysis using the BIAcore(R) technology and its immunogenicity in mice was measured as the ability of hybrid proteins to elicit antibodies against a synthetic peptide containing this epitope. This study revealed a good correlation between the antigenicity of the inserted epitope and its immunogenicity. Increasing the length of the inserted epitope, as well as inserting multicopies of this epitope increased both its antigenicity and immunogenicity. However, none of the MalE hybrid proteins tested induced anti-HIV-1 neutralizing antibodies. This study strongly suggests that the capacity of the 2F5 epitope to induce neutralizing antibodies depends on the molecular context in which it is presented.

Identification of the critical residues involved in peptidoglycan detection by Nod1

Nod1 is an intracellular pattern recognition molecule activated following bacterial infection, which senses a specific muropeptide (l-Ala-d-Glu-meso-DAP (diaminopimelic acid); “TriDAP”) from peptidoglycan. Here we investigated the molecular basis of TriDAP sensing by human (h) Nod1. Our results identified the domain responsible for TriDAP detection in the center of the concave surface of hNod1 leucine-rich repeat domain. Amino acid residues critical for sensing define a contiguous surface patch that is largely conserved in Nod1 proteins from different species. Accordingly, the distinct specificities of human versus murine Nod1 toward muropeptide detection were also found to lie in this central cleft. Several splicing variants of Nod1 lacking repeats 7-9 have been characterized recently, the relative balance of which is thought to correlate with the onset of asthma or inflammatory bowel disease. We demonstrated that these isoforms failed to transduce NF-κB activation upon muropeptide stimulation. This study provided insights into the molecular mechanisms responsible for the detection of bacterial peptidoglycan by Nod1 and suggested that defects in Nod1-dependent peptidoglycan sensing may contribute to elicit certain inflammatory disorders.

In vitro interaction between components of the inner membrane complex of the maltose ABC transporter of Escherichia coli : modulation by ATP

Interactions between domains of ATP‐binding cassette (ABC) transporters are of great functional importance and yet are poorly understood. To gain further knowledge of these protein–protein interactions, we studied the inner membrane complex of the maltose transporter of Escherichia coli. We focused on interactions between the nucleotide‐binding protein, MalK, and the transmembrane proteins, MalF and MalG. We incubated purified MalK with inverted membrane vesicles containing MalF and MalG. MalK bound specifically to MalF and MalG and reconstituted a functional complex. We used this approach and limited proteolysis with trypsin to show that binding and hydrolysis of ATP, inducing conformational changes in MalK, modulate its interaction with MalF and MalG. MalK in the reconstituted complex was less sensitive to protease added from the cytoplasmic side of the membrane, and one proteolytic cleavage site located in the middle of a putative helical domain of MalK was protected. These results suggest that the putative helical domain of the nucleotide‐binding domains is involved, through its conformational changes, in the coupling between the transmembrane domains and ATP binding/hydrolysis at the nucleotide‐binding domains.

Secretion of a bacterial protein by mammalian cells

The MalE protein is a periplasmic maltooligosaccharide binding protein from Escherichia coli. This protein is widely used as a model for protein export in bacteria and as a vector for the export and one-step affinity purification of foreign polypeptides. Expression of MalE was studied in various animal cell lines. The protein was exported into the culture medium, following the classical pathway of eukaryotic protein secretion. This was shown by a combination of approaches including the use of inhibitors of the Golgi complex and immunocytological methods. The signal sequence of MalE is required for secretion and a specific signal can be added to MalE that targets it to the endoplasmic reticulum. This work opens the way to the study of the secretion of a bacterial protein and to its use as a vector for protein secretion and purification from mammalian cells.

β-galactosidase overexpression in SV40-transformed Chinese hamster fibroblasts exposed to mutagens as a result of amplification of transfected bacterial lacZ DNA sequences

Genetic constructions in which the bacterial lacZ gene, encoding the enzyme beta-galactosidase, is fused to a viral (SV40) origin of replication have been introduced in an SV40-transformed hamster cell line (C1102). We have studied in detail 3 clones in which beta-galactosidase-specific activity increases after treatment with genotoxic agents. We show that this increase is dependent on the activity of the viral T protein and correlates with an amplification of lac sequences. This system provides a basis for the study of the induction of gene amplification by genotoxic agents in mammalian cells.

Control by H-2 genes of the Th1 response induced against a foreign antigen expressed by attenuated Salmonella typhimurium

Attenuated salmonellae represent an attractive vehicle for the delivery of heterologous protective antigens to the immune system. Here, we have investigated the influence of the genetic background of the host which regulates the growth and elimination of Salmonella cells on the cellular response induced against a foreign antigen delivered by an aroA Salmonella strain. We have tested CD4+ T-cell responses (cell proliferation and cytokine production) in various mouse strains following immunization with Salmonella typhimurium SL3261 expressing a high level of the recombinant Escherichia coli MalE protein. We were able to detect a CD4+ T-cell response against the recombinant MalE protein only in a restricted number of mouse strains, whereas all mice produced good levels of anti-MalE immunoglobulin G antibodies. The Ity gene did not play a major role in these differences in T-cell responses, since both Ity-resistant and -susceptible strains of mice were found to be unresponsive to MalE delivered by recombinant salmonellae. In contrast, when B10 congenic mice were used, a correlation was established between MalE-specific T-cell unresponsiveness and H-2 genes. The discrepancies described in this paper in the ability of various strains of mice to develop an efficient Th1 response against a recombinant antigen displayed by a live Salmonella vaccine underscore the difficulties that can be encountered in the vaccination of human populations by such a strategy.