Chlamydia pneumoniae, a human pathogen causing respiratory infections and probably contributing to the development of atherosclerosis and heart disease, is an obligate intracellular parasite which for replication needs to productively interact with and enter human cells. Because of the intrinsic difficulty in working with C. pneumoniae and in the absence of reliable tools for its genetic manipulation, the molecular definition of the chlamydial cell surface is still limited, thus leaving the mechanisms of chlamydial entry largely unknown. In an effort to define the surface protein organization of C. pneumoniae, we have adopted a combined genomicproteomic approach based on (i) in silico prediction from the available genome sequences of peripherally located proteins, (ii) heterologous expression and purification of selected proteins, (iii) production of mouse immune sera against the recombinant proteins to be used in Western blotting and fluorescence-activated cell sorter (FACS) analyses for the identification of surface antigens, and (iv) mass spectrometry analysis of two-dimensional electrophoresis (2DE) maps of chlamydial protein extracts to confirm the presence of the FACS-positive antigens in the chlamydial cell. Of the 53 FACS-positive sera, 41 recognized a protein species with the expected size on Western blots, and 28 of the 53 antigens shown to be surface-exposed by FACS were identified on 2DE maps of elementary-body extracts. This work represents the first systematic attempt to define surface protein organization in C. pneumoniae.Chlamydia pneumoniae is an obligate intracellular bacterium and a common human pathogen (48). It is a significant cause of pneumonia in both hospital and outpatient settings, accounting for approximately 7 to 10% of cases of community-acquired pneumonia among adults. C. pneumoniae has also been associated with atherosclerotic and cardiovascular disease, as suggested by results of seroepidemiologic studies, detection of the organism in atherosclerotic plaque specimens, experimental in vitro cell culture studies, animal model studies, and two small secondary prevention antibiotic treatment trials (12,13,15,19,20,28,45).Like all obligate intracellular parasites, for its survival and propagation C. pneumoniae must accomplish several essential tasks which include adhering to and entering host cells, creating an intracellular niche for replication, exiting host cells for subsequent invasion of neighboring cells, and also avoiding host defense mechanisms. To carry out all these functions, C. pneumoniae has developed a unique biphasic life cycle involving two developmental forms, a spore-like infectious form (elementary bodies [EBs]) and an intracelluar replicative form (reticulate bodies [RBs]). Adhesion, host cell colonization capabilities, and the ability to cope with host defense mechanisms when outside the cell presumably rely in large part on EB surface organization.Because of the intrinsic difficulty in working with C. pneumoniae and the lack of adequate methods for its genetic ma...