Claude Carnaud, Stephan Köhler, Maria-Teresa Alvarez-Martinez, Pascaline Fontes, Jean-Pierre Liautard, Antoine Gross, Microbiologie et Pathologie Cellulaire Infectieuse, Université Montpellier 2 - Sciences et Techniques (UM2)-Institut National de la Santé et de la Recherche Médicale (INSERM), Maladies à prions et système immunitaire, and IFR65-Institut National de la Santé et de la Recherche Médicale (INSERM)
The six Brucella species are gram-negative bacteria that cause brucellosis in human and animals, a disease also known as Malta fever. Brucella spp. are facultative intracellular pathogens and infect a variety of cells including “professional” and “nonprofessional” phagocytes (14, 19, 22). Many aspects of the pathophysiology of the disease are still unclear (establishment of chronicity, for example), but it is assumed that the intracellular location is essential for bacterial multiplication and virulence (22). After penetration inside the macrophages, Brucella-containing vacuoles traffic in a complex manner (8) to become the replicative niche of the pathogen: the brucellosome (18). Attachment to the host membrane and phagocytosis are the first steps leading to the intracellular stages, but little is known about the molecular mechanisms involved. The use of inhibitors or antibodies against putative receptors has led only to incomplete inhibition. For instance, bacterial entry into bovine macrophages was partially inhibited by the peptide RGDS, the outer membrane-peptidoglycan complex from Brucella abortus strain RB51, anti-lymphocyte function-associated antigen-1 monoclonal antibody, anti-C3 antiserum, fibronectin, purified O antigen from B. abortus lipopolysaccharide (LPS), and mannan- and heat-aggregated immunoglobulin G (5). On the other hand, recent studies have presented data suggesting that the adherence mechanism of Brucella to macrophages is mediated by cellular receptors containing sialic acid and sulfated residues, explaining the affinity for proteins of the cellular matrix (6). Recent advances in cellular biology have attracted the attention of microbiologists to the importance of membrane cellular structures, namely, lipid rafts that exhibit many specific functions, the ability to concentrate signaling molecules in particular. An increasing number of bacteria and their products have been shown to interact with lipid rafts to promote infection (20). Brucella needs functional lipid rafts to enter macrophages (24, 36), as the disruption of lipid rafts markedly inhibits internalization and intracellular replication, indicating that the path of entry into macrophages determines the intracellular fate of the bacteria and shapes phagosome maturation (24). In particular, it was suggested that raft elements incorporated into the phagosomes containing Brucella modulate their maturation into replicative vesicles, probably by the initiation of a signaling transduction cascade (36). Some of these raft elements determining intracellular fate of the bacteria have been identified as cholesterol, gangliosides (e.g., GM1), glycosphingolipids, and glycosylphosphatidylinositol (GPI)-anchored proteins. Nevertheless, it can be supposed that bacterial phagocytosis involves many other interactions between bacterial membrane and cellular partners that are still undefined. However, because penetration needs functional rafts, it has been suggested that the cellular receptor for Brucella would be a GPI-anchored protein known to be localized inside these cholesterol-rich structures. This point of view was recently adopted by Watarai et al. (35), who concluded that the cellular prion protein (PrPC) promotes infection and could thus be one receptor for the bacteria on the membrane of macrophages. PrPC is a 231-amino-acid GPI protein anchored on the outer leaflet of the plasma membrane of many cell types (17). It was remarkably conserved during mammalian evolution and is ubiquitously expressed in organisms, predominantly in the central nervous system. PrPC is the cellular, nonpathogenic homologue of PrPSc (for prion protein scrapie), which is suspected according to Prusiner's hypothesis (30) to be the unconventional agent responsible of transmissible spongiform encephalopathies. The two proteins share a common primary structure but differ in their tertiary structure: PrPSc exhibits a majority of β-sheets that aggregate into β-amyloid fibrils. On the contrary, PrPC exhibits mainly α-helix conformation (37). The physiological functions of PrPC are still poorly understood, and the protein has been implicated in many functions such as protection from oxidative insults, apoptosis, cellular signaling, membrane excitability and synaptic transmission, neuritogenesis, and copper(II) transport or metabolism (17, 21, 29). But how all these functions are achieved by the same protein is still enigmatic. PrPC is located in rafts of the plasmic membrane to which it is attached by its GPI anchor. This localization is compatible with a role as a membrane receptor and with cellular signaling. The use of PrPC by B. abortus (35) could be an interesting opportunity to better understand the function of this protein. In consequence, we decided to further analyze the mechanisms involving cellular prion protein during infection of macrophages by Brucella. Surprisingly, we were not able to find any evidence of the participation of cellular prion protein during infection process, even with different species of Brucella.