Alain Charbit

Importance of Branched-Chain Amino Acid Utilization in Francisella Intracellular Adaptation

ABSTRACT Intracellular bacterial pathogens have adapted their metabolism to optimally utilize the nutrients available in infected host cells. We recently reported the identification of an asparagine transporter required specifically for cytosolic multiplication of Francisella. In the present work, we characterized a new member of the major super family (MSF) of transporters, involved in isoleucine uptake. We show that this transporter (here designated IleP) plays a critical role in intracellular metabolic adaptation of Francisella. Inactivation of IleP severely impaired intracellular F. tularensis subsp. novicida multiplication in all cell types tested and reduced bacterial virulence in the mouse model. To further establish the importance of the ileP gene in F. tularensis pathogenesis, we constructed a chromosomal deletion mutant of ileP (ΔFTL_1803) in the F. tularensis subsp. holarctica live vaccine strain (LVS). Inactivation of IleP in the F. tularensis LVS provoked comparable intracellular growth defects, confirming the critical role of this transporter in isoleucine uptake. The data presented establish, for the first time, the importance of isoleucine utilization for efficient phagosomal escape and cytosolic multiplication of Francisella and suggest that virulent F. tularensis subspecies have lost their branched-chain amino acid biosynthetic pathways and rely exclusively on dedicated uptake systems. This loss of function is likely to reflect an evolution toward a predominantly intracellular life style of the pathogen. Amino acid transporters should be thus considered major players in the adaptation of intracellular pathogens.

The complex amino acid diet of Francisella in infected macrophages.

Francisella tularensis, the agent of the zoonotic disease tularemia, is a highly infectious bacterium for a large number of animal species and can be transmitted to humans by various means. The bacterium is able to infect a variety of cell types but replicates in mammalian hosts mainly in the cytosol of infected macrophages. In order to resist the stressful and nutrient-restricted intracellular environments, it encounters during its systemic dissemination, Francisella has developed dedicated stress resistance mechanisms and adapted its metabolic and nutritional needs. Recent data form our laboratory and from several other groups have shown that Francisella simultaneously relies on multiple host amino acid sources during its intracellular life cycle. This review will summarize how intracellular Francisella use different amino acid sources, and their role in phagosomal escape and/or cytosolic multiplication and systemic dissemination. We will first summarize the data that we have obtained on two amino acid transporters involved in Francisella phagosomal escape and cytosolic multiplication i.e., the glutamate transporter GadC and the asparagine transporter AnsP, respectively. The specific contribution of glutamate and asparagine to the physiology of the bacterium will be evoked. Then, we will discuss how Francisella has adapted to obtain and utilize host amino acid resources, and notably the contribution of host transporters and autophagy process in the establishment of a nutrient-replete intracellular niche.

Molecular and cellular targeting in the expression of foreign polypeptides in bacteria

We have developed a system allowing the insertion of foreign polypeptides into recipient proteins. We used essentially MalE, the periplasmic maltosebinding protein and LamB, the outer membrane maltoporin (or ;~ receptor) of E. coli. The insertions are performed into permissive sites so that the main biological properties of the recipient are maintained. MalE can be used as a vector to export into the periplasm and affinity purify foreign proteins in mild non denaturing conditions The fusion of sCD4, the soluble part of the lymphocyte receptor for HIV, to the Cor to the N-terminus of Male has been investigated. Easy purification and high levels of production of hybrid proteins endowed of anti viral activities have been obtained. Male and LamB can also be used as vectors for the presentation of foreign polypeptides (epitopes) to the immune system, in the form of whole bacteria or extracts or as purified proteins. We studied parameters that may influence the antigenicity and the immunogenicity of a given antigen. Some aspects will be discussed, such as the influence of the cellular localization of the epitope (cell surface or periplasrn: cellular targeting), the role of the exact location of the foreign antigen within the recipient protein (molecular targeting), or the mode of administration to the host. Our approach should lead to understand better the relation between the molecular and cellular localization of a peptide and its immunological properties. Introduction

Immune responses to hybrid maltose-binding proteins

The Escherichia coli maltose-binding protein is a highly versatile carrier protein allowing the construction of genetically engineered hybrid proteins. It accepts large fusions to both C- and N-termini as well as the insertion of shorter peptides at permissive sites within the continuity of the protein. We have genetically inserted immunogenic peptides corresponding to defined viral B- and T-cell epitopes into two permissive sites: one at amino acid site 133, the other at site 303. The hybrid proteins are easily purifiable and immunogenic, inducing peptide-specific B- and T-cell responses. When delivered by live bacteria (E. coli K12 and aroA Salmonella typhimurium) antibody responses can be induced against both the MalE carrier and the inserted B-cell epitope. We discuss the induction of T-cell responses by bacterial delivery systems.

Bacterial Vectors to Target and/or Purify Polypeptides

The construction of recombinant proteins by genetic engineering has opened new avenues in basic research (studies on protein organization, protein folding, immunogenicity of proteins, ...) and many different applications. Recombinant proteins which keep properties of both parental proteins are especially interesting. For example, if one protein--the vector protein--is targeted to a given cellular compartment, the other protein--the passenger--may be identically targeted. Also, if the vector protein can be purified by a simple affinity chromatographic procedure, this property may be extended to the passenger. The authors have developed a genetic procedure to detect permissive sites within potential vector proteins so that genetic fusion to these sites keep most or all biological properties of the vector. When they used LamB, an outer membrane protein from E. coli, foreign sequences could be expressed at the bacterial cell surface. This may lead to several types of applications: live bacterial vaccines, simple diagnostic tests, selection procedures for peptides with biological activity. When they used the MalE protein, a periplasmic maltose binding protein from E. coli, the passengers could be exported and purified in one-step high affinity chromatography in mild non-denaturing conditions. This led us to a simple preparation and purification scheme for the soluble part of the CD4 receptor for the Human Immunodeficiency Virus (HIV).