Lipoprotein(a) [Lp(a)] has been measured in numerous clinical and epidemiological studies by a variety of immunochemical methods. However, little, if any, consideration has been given to the confounding effect of the size heterogeneity of apolipoprotein(a) [apo(a)] on the measurement of Lp(a). We developed three direct-binding enzyme-linked immunosorbent assays (ELISAs) with detecting antibodies of different specificities to evaluate the effect of apo(a) size on Lp(a) measurement. The three assays used the same monoclonal antibody to capture the apo(a)-containing particles and were calibrated (in nanomoles per liter) with a serum containing apo(a) with 21 kringle 4 domains. Using all three ELISAs, we measured Lp(a) in a group of 723 subjects selected to have a single apo(a) band, as determined by a high-resolution phenotyping system. Essentially identical results were obtained by the two methods that measured Lp(a) by use of either a polyclonal antibody against apo B or a monoclonal antibody against apo(a) that does not recognize the kringle 4 type 2 repeats. In contrast, the ELISA using a monoclonal antibody specific for apo(a) kringle 4 type 2 repeats overestimated Lp(a) concentration in samples containing apo(a) with more than 21 kringle 4 domains and underestimated Lp(a) samples containing apo(a) with fewer than 21 kringle 4 domains. Thus, these differences in Lp(a) values varied as a function of apo(a) size. We conclude that antibody specificity and apo(a) size heterogeneity can significantly affect Lp(a) measurements.
*Chlamydia infections cause substantial morbidity worldwide and effective prevention will depend on a vaccine. Since Chlamydia immunity is T cell-mediated, a major impediment to developing a molecular vaccine has been the difficulty in identifying relevant T cell Ags. In this study, we used a combination of affinity chromatography and tandem mass spectrometry to identify 13 Chlamydia peptides among 331 self-peptides presented by MHC class II (I-A b ) molecules from bone marrow-derived murine dendritic cells infected with Chlamydia muridarum. These MHC class II-bound peptides were recognized by Chlamydia-specific CD4 T cells harvested from immune mice and adoptive transfer of dendritic cells pulsed ex vivo with the peptides partially protected mice against intranasal and genital tract Chlamydia infection. The results provide evidence for lead vaccine candidates for a T cell-based subunit molecular vaccine against Chlamydia infection suitable for human study. The Journal of Immunology, 2008, 180: 2459 -2465. W orld-wide Chlamydia trachomatis is annually responsible for Ͼ92 million sexually transmitted infections and 85 million ocular infections (1). Public health programs have targeted C. trachomatis as a major problem because the organism causes long-term sequelae such as infertility, ectopic pregnancy, and blindness. Sexually transmitted C. trachomatis is also a potent cofactor facilitating the transmission of HIV (2) and interacts with oncogenic human papilloma virus in the pathogenesis of cervical neoplasia (3). In developed countries, public health measures to control Chlamydia are failing as case rates continue to rise, perhaps due to early antibiotic treatment interfering with the acquisition of immunity (4); these approaches to control Chlamydia are not feasible for much of the developing world. Thus, a new approach, such as an effective vaccine, is needed if Chlamydia control is to be achieved in the developing and developed world.Previous vaccine research using inactivated Chlamydia bacterial cells demonstrated partial short-term protection which may have been complicated by immunopathology during breakthrough infection (5). These vaccine trials yielded important lessons for the modern era of Chlamydia vaccinology, namely, that an effective Chlamydia vaccine will need to be molecularly defined and engender long-lived protective immune responses. Immunity to C. trachomatis is now known to depend on cell-mediated immune (CMI) 3 responses, especially Th1-polarized cytokine responses (6). Abs appear to play a secondary role (7). Experience has shown that developing vaccines for intracellular pathogens that require protective CMI is more difficult than for pathogens that simply require protective Ab (8). Part of the problem has been the identification of Ags that induce CMI responses because such Ags need to be presented to T cells by MHC molecules, and identifying MHC-bound microbial epitopes has been notoriously difficult (6). Since T cell responses mainly recognize protein Ags, protective vaccine candida...
Lipoprotein(a) [Lp(a)] particle formation is a two-step process in which initial noncovalent interactions between apolipoprotein(a) [apo(a)] and the apolipoprotein B-100 (apoB-100) component of low-density lipoprotein (LDL) precede disulfide bond formation. To identify kringle (K) domains in apo(a) that bind noncovalently to apoB-100, the binding of a battery of purified recombinant apo(a) [r-apo(a)] species to immobilized human LDL has been assessed. The 17K form of r-apo(a) (containing all 10 types of kringle IV sequences) as well as other truncated r-apo(a) derivatives exhibited specific binding to a single class of sites on immobilized LDL, with Kd values ranging from approximately 340 nM (12K) to approximately 7900 nM (KIV5-8). The contribution of kringle IV types 6-8 to the noncovalent interaction of r-apo(a) with LDL was demonstrated by the decrease in binding affinity observed upon sequential removal of these kringle domains (Kd approximately 700 nM for KIV6-P, Kd approximately 2000 nM for KIV7-P, Kd approximately 5100 nM for KIV8-P, and no detectable specific binding of KIV9-P). Interestingly, KIV9 also appears to participate in the noncovalent binding of apo(a) to LDL since the binding of KIV5-8 (Kd approximately 7900 nM) was considerably weaker than that of KIV5-9 (Kd approximately 2000 nM). Finally, it is demonstrated that inhibition of Lp(a) assembly by proline, lysine, and lysine analogues, as well as by arginine and phenylalanine, is due to their ability to inhibit noncovalent association of apo(a) and apoB-100 and that these compounds directly exert their effects primarily through interactions with sequences contained within apo(a) kringle IV types 6-8. On the basis of the obtained data, a model is proposed for the interaction of apo(a) and LDL in which apo(a) contacts the single high-affinity binding site on apoB-100 through multiple, discrete interactions mediated primarily by kringle IV types 6-8.
These data establish that I-309 is responsible for the monocyte chemotactic activity induced in human umbilical vein endothelial cells by Lp(a). The identification of the endothelial cell as a source for I-309 suggests that this chemokine may participate in vessel wall biology. Our data also suggest that I-309 may play a role in mediating the effects of Lp(a) in atherosclerosis.
In the present study, we assessed the binding of recombinant forms of apolipoprotein(a) [r-apo(a)] to plasminogen. Apo(a)-plasminogen interactions were demonstrated to be lysine-dependent, as they were abolished by the addition of epsilon-aminocaproic acid. Binding of r-apo(a) and plasma-derived Lp(a) to Glu-plasminogen was assessed in solution using a mutant form of recombinant plasminogen [Plg(S741C)] labeled at the active site with 5'-(iodoacetamido)fluorescein. High-affinity binding of apo(a) to plasminogen was observed with the 17-kringle r-apo(a) (Kd = 20.1 +/- 3.3 nM) as well as with plasma-derived Lp(a) (Kd = 5.58 +/- 0.08 nM). Binding studies using various truncated and mutant forms of r-apo(a) demonstrated that sequences within apo(a) kringle IV types 2-9 and the strong lysine binding site (LBS) in apo(a) kringle IV type 10 are not required for high-affinity binding to plasminogen. In all cases, the binding stoichiometry for the apo(a)-plasminogen interaction was determined to be 1:1. Binding data obtained using a 17-kringle r-apo(a) derivative lacking the protease-like domain (17KDeltaP; Kd = 3158 +/- 138 nM) indicate that sequences within the protease-like domain of apo(a) mediate its interaction with LBS in plasminogen. We determined that r-apo(a) and plasminogen bind to distinct sites on plasmin-modified fibrinogen with the concentration of plasminogen binding sites exceeding the concentration of r-apo(a) sites by a factor of 10. Furthermore, r-apo(a) is capable of inhibiting the binding of plasminogen to plasmin-modified fibrinogen surfaces, an effect which we show is attributable to the formation of a solution phase apo(a)/plasminogen complex which exhibits a greatly reduced affinity for plasminogen binding sites on plasmin-modified fibrinogen. The results of this study provide new insights into the mechanism by which apo(a) and Lp(a) may inhibit fibrinolysis, thus contributing to the atherothrombotic risk associated with this lipoprotein.
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