Lipid raft-mediated entry is not required for Chlamydia trachomatis infection of cultured epithelial cells.

Using pharmacologic and biochemical criteria, we evaluated whether uptake of four different Chlamydia trachomatis serovars, D, E, K, and L2, was dependent upon lipid rafts. Our data suggest that lipid raft-mediated entry is not required for C. trachomatis infection of cultured epithelial cells.

Effect of low-density lipoprotein buoyant density and cholesterol content on the formation of lipoprotein(a) particles.

Lipoprotein(a) [Lp(a)] is a unique lipoprotein which resembles low-density lipoprotein (LDL) both in lipid composition and the presence of apolipoprotein B-100 (apo B-100). Lp(a) is, however, distinguishable from LDL by the presence of an additional glycoprotein apolipoprotein(a) [apo(a)], which is covalently attached to apo B-100 by a single disulfide bond. It is now generally accepted that Lp(a) assembly is a two-step process in which the initial non-covalent interaction between apo(a) and apo B-100 is mediated by the weak lysine binding sites present in kringle IV types 6, 7 and 8 of apo(a). In the present study, we have investigated the effect of LDL heterogeneity on Lp(a) assembly in a group of 111 individuals. The three parameters of LDL composition assessed in this study were the cholesterol content, the apo B content, and the relative flotation rate (a measure of LDL buoyancy and thus size). We found no correlation between the size of LDL particles and the extent of Lp(a) formation; a weak negative correlation was observed between cholesterol content of LDL and Lp(a) formation (P=0.042). This may suggest a role for free (i.e., surface-associated) cholesterol in the ability of LDL to form Lp(a) particles.

CC chemokine I-309 is the principal monocyte chemoattractant induced by apolipoprotein(a) in human vascular endothelial cells.

BACKGROUND: Lipoprotein(a) [Lp(a)] is a risk factor for atherosclerosis; however, the mechanisms are unclear. We previously reported that Lp(a) stimulated human vascular endothelial cells to produce monocyte chemotactic activity. The apolipoprotein(a) [apo(a)] portion of Lp(a) was the active moiety. METHODS AND RESULTS: We now describe the identification of the chemotactic activity as being due to the CC chemokine I-309. The carboxy-terminal domain of apo(a) containing 6 type-4 kringles (types 5 to 10), kringle V, and the protease domain was demonstrated to contain the I-309-inducing portion. Polyclonal and monoclonal anti-I-309 antibodies as well as an antibody against a portion of the extracellular domain of CCR8, the I-309 receptor, inhibited the increase in monocyte chemotactic activity induced by apo(a). I-309 antisense oligonucleotides also inhibited the induction of endothelial monocyte chemotactic activity by apo(a). I-309 mRNA was identified in human umbilical vein endothelial cells. Apo(a) induced an increase in I-309 protein in the endothelial cytoplasm and in the conditioned medium. Immunohistochemical studies have identified I-309 in endothelium, macrophages, and extracellular areas of human atherosclerotic plaques and have found that I-309 colocalized with apo(a). CONCLUSIONS: 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.

Sequences within the amino terminus of ApoB100 mediate its noncovalent association with apo(a).

Although sequences within the C terminus of apolipoprotein B (apoB) have been implicated in the formation of covalent lipoprotein(a) [Lp(a)] particles, sequences in apoB that mediate initial noncovalent interaction with apo(a) remain to be characterized. To address this question, we have used an affinity chromatography method in which 2 recombinant forms of apo(a) [r-apo(a); either a 17-kringle form (17K) or a derivative containing apo(a) kringle IV types 5-8] have been immobilized onto Sepharose beads. Conditioned media from rat hepatoma (McA-RH7777) cell lines stably expressing various carboxyl-terminally truncated forms of human apoB (ranging from full-length apoB to apoB15) were applied to the r-apo(a) affinity columns; the columns were subsequently washed and eluted with epsilon-aminocaproic acid (epsilon-ACA). Specific binding was quantified by Western blot analysis of column fractions. Of the apoB truncations examined, apoB94, apoB42, apoB37, and apoB29 exhibited complete specific binding to 17K r-apo(a). Only approximately 50% binding was observed for apoB18, whereas essentially no detectable binding was observed with apoB15. In all cases, similar results were obtained when the r-apo(a) kringle IV types 5-8-Sepharose column was used. Additionally, substitution of proline for epsilon-ACA as the eluent resulted in similar column profiles with either r-apo(a) affinity column. We also demonstrated that apoB48 present in chylomicrons bound completely to the 17K column in an epsilon-ACA-dependent manner. Taken together, these results represent the first demonstration that N-terminal sequences in apoB between amino acid residues 680 (apoB15) and 781 (apoB18) are essential for noncovalent association with apo(a) and that these sequences interact with domain(s) present within apo(a) kringle IV types 5-8.

Sequences within apolipoprotein(a) kringle IV types 6-8 bind directly to low-density lipoprotein and mediate noncovalent association of apolipoprotein(a) with apolipoprotein B-100.

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.

Expression of apolipoprotein(a) kringle IV type 9 in Escherichia coli: demonstration of a specific interaction between kringle IV type 9 and apolipoproteinB-100.

A number of studies have provided evidence that lipoprotein(a) [Lp(a)] assembly is a two-step process in which initial non-covalent interactions between apolipoprotein(a) [apo(a)] and apolipoproteinB-100 (apoB-100) precede specific disulfide bond formation. We have designed a construct encoding apo(a) kringle IV type 9 (KIV9) in which the unpaired cysteine at position 67 in this kringle is replaced with a tyrosine. The single kringle was expressed in bacteria and purified to homogeneity from cell homogenates. The purified derivative (designated KIV9deltaCys) was assessed for its ability to bind to purified human LDL. This interaction was detected either by ELISA using immobilized LDL or by column chromatography in which LDL binding to KIV9deltaCys immobilized on Ni2+-Sepharose was determined. In both cases, the interaction of KIV9deltaCys and LDL was observed. Further, we demonstrated that the binding interaction was sensitive to the addition of amino acids including lysine, the lysine analogue epsilon-aminocaproic acid, arginine, phenylalanine and proline, with arginine and lysine having the greatest inhibitory effect. Binding of KIV9deltaCys to an immobilized apoB peptide spanning residues 3732-3745 of apoB was also demonstrated by ELISA. As was the case for LDL, this binding interaction was sensitive to the addition of arginine and lysine. Computer modeling of KIV9 demonstrated an excellent fit with residues 3732-3738 (PSCKLDF) of the apoB peptide. The modeling predicts the presence of overlapping lysine and phenylalanine-binding pockets in KIV9 which explains the inhibitory effects of lysine, arginine and phenylalanine which were observed in the binding assays. In summary, this study represents the first demonstration that KIV9 can interact directly with LDL through non-covalent interactions which may contribute to the first step of Lp(a) formation.

The solution phase interaction between apolipoprotein(a) and plasminogen inhibits the binding of plasminogen to a plasmin-modified fibrinogen surface.

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.

Lipoprotein[a] is not present in the plasma of patients with some peroxisomal disorders.

Peroxisomal disorders arise either from defects in the biogenesis of peroxisomes or from the defective synthesis of one or more peroxisomal enzymes. These defects result in metabolic disturbances in peroxisomal beta-oxidation of various fatty acids and derivatives and/or in the biosynthesis of ether lipids. In the current study, lipoprotein levels were determined in plasma samples from patients diagnosed with one of four different peroxisomal disorders. While low density lipoprotein (LDL) levels were found to be within the normal range, lipoprotein[a] (Lp[a]) could not be detected by enzyme-linked immunosorbent assay (ELISA) in plasma from patients with cerebro-hepato-renal (Zellweger) syndrome (ZS) and rhizomelic chondrodysplasia punctata (RCDP). Conversely, Lp[a] was clearly present in control plasma obtained from healthy newborns and from patients affected with one of two other peroxisomal disorders, X-linked adrenoleukodystrophy (X-ALD) and Refsum disease (RD) as determined by ELISA. The lack of Lp[a] in plasma of patients with ZS may result from defective secretion of apolipoprotein[a] (apo[a]) (the distinguishing protein component of Lp[a]), as apo[a] mRNA transcripts were clearly present in ZS livers as assessed by PCR, and intracellular apo[a] protein was detected in total liver homogenates from ZS patients as determined by Western blot analysis. Furthermore, LDL present in the plasma of ZS patients was able to associate with recombinant apo[a] in an in vitro Lp[a] assembly assay.

Analysis of the mechanism of lipoprotein(a) assembly.

We have assessed the ability of a battery of purified recombinant apolipoprotein(a) (r-apo(a)) derivatives to bind to immobilized low-density lipoprotein (LDL) by ELISA. Removal of the apo(a) kringle IV type 8 and type 9 sequences dramatically reduced apo(a) binding to LDL. The binding of apo(a) to LDL was effectively inhibited by arginine, lysine, the lysine analogue epsilon-aminocaproic acid and proline; comparable inhibition was observed using the 17K and KIV5-8 r-apo(a) derivatives, suggesting a direct role for sequences contained in the latter species in mediating the initial non-covalent interactions which precede specific disulfide bond formation. We also determined that r-apo(a) binds directly to a synthetic apoB peptide spanning amino acid residues 3732-3745; this interaction appeared to be mediated by sequences present in apo(a) kringle IV types 8 and 9, and could be inhibited by arginine, lysine and proline. The results of this study indicate that the efficiency of Lp(a) assembly is a direct function of the initial non-covalent interactions between apo(a) and LDL; in addition, these studies suggest that Cys3734 in apoB mediates covalent linkage with apo(a) by virtue of the ability of the apoB sequences surrounding this residue to directly interact with apo(a) KIV type 9.

Lipoprotein(a) assembly. Quantitative assessment of the role of apo(a) kringle IV types 2-10 in particle formation.

We have developed a system for the quantitative assessment of the efficiency of lipoprotein(a) [Lp(a)] formation in vitro. Amino-terminally truncated derivatives of a 17-kringle form of recombinant apo(a) [r-apo(a)] were transiently expressed in human embryonic kidney cells. Equimolar amounts of r-apo(a) derivatives were incubated with a fourfold molar excess of purified human low density lipoprotein, and r-Lp(a) formation was assessed by densitometric analysis of Western blots. Although r-Lp(a) formation was observed with each r-apo(a) derivative, both the rate and extent of particle formation were greatly lower on removal of kringle IV type 7. Additional substantial decreases in these parameters were observed on removal of kringle IV type 8, thereby suggesting a major role for these two kringles in Lp(a) assembly. We directly demonstrated that the lysine-binding sites (LBSs) within kringle IV types 5-9 are "masked" in the context of the Lp(a) particle and are consequently unavailable for interaction with lysine-Sepharose. Using site-directed mutagenesis, we also demonstrated that the previously described LBS in kringle IV type 10 is not required for r-Lp(a) formation: r-Lp(a) formation using a mutated form of apo(a) that lacks this LBS is comparable in efficiency to that of wild-type r-apo(a) and can be inhibited to a similar extent by epsilon-amino-n-caproic acid. In summary, the results of our study indicate that apo(a) kringle IV types 7 and 8 are required for maximal efficiency of Lp(a) formation, likely by virtue of their ability to mediate lysine-dependent non-covalent interactions with apoB-100 that precede disulfide bond formation.

The binding activity of the macrophage lipoprotein(a)/apolipoprotein(a) receptor is induced by cholesterol via a post-translational mechanism and recognizes distinct kringle domains on apolipoprotein(a).

Elevated plasma levels of lipoprotein(a) (Lp(a)) can be a risk factor for atherosclerosis, and the interaction of Lp(a) with cholesterol-loaded macrophages (foam cells) in atheromata may be important in Lp(a)-induced atherogenesis. We have previously shown that when cultured macrophages are loaded with cholesterol, they acquire the ability to internalize and lysosomally degrade Lp(a) via interaction between a novel cell-surface receptor activity and the apolipoprotein(a) (apo(a)) moiety of Lp(a). Herein we explore the cell-surface binding of recombinant apo(a) (r-apo(a)) by foam cells. Whereas the induction of degradation of r-apo(a) by cholesterol loading of macrophages depended on new protein synthesis, the induction of binding of r-apo(a) did not. Furthermore, J774 macrophages bound r-apo(a) in a cholesterol-regulatable and specific manner but degraded r-apo(a) poorly. Thus, the binding and internalization/degradation functions of the receptor activity are distinct. To explore which domains on r-apo(a) interact with the foam cell receptor, we conducted a series of competitive and direct binding and degradation experiments using 12 r-apo(a) constructs that differed in their content of specific kringle subtypes. These data, as well as complementary data with anti-apo(a) monoclonal antibodies, indicated that the region centered around kringle type IV, subtypes 6-7 (KIV6-7) is important in receptor binding. Remarkably, a cholesterol-induced receptor activity with similar structural specificity was also found on Chinese hamster ovary cells. In conclusion, the foam cell Lp(a)/apo(a) receptor consists of a cholesterol-regulatable binding activity and a short-lived component necessary for internalization or lysosomal degradation; the binding activity interacts with a distinct region of apo(a) that is different from that involved in competition for plasminogen binding.

Analysis of the proteolytic activity of a recombinant form of apolipoprotein(a).

We have analyzed the proteolytic activity of a recombinant form of apolipoprotein(a) [r-apo-(a)]. A mutant 17-kringle from of r-apo(a) was engineered that contained a serine to arginine substitution which reinstates the tissue-type plasminogen activator (tPA) as determined by SDS-PAGE and fluorography and by Western blot analysis. However, tPA cleavage did not result in an active protease as both wildtype r-apo(a) and the mutant, either free or incorporated into r-Lp(a) particles, were uniformly inactive against a variety of chromogenic serine protease tripeptide substrates. To assess whether the large number of kringle IV repeats present in apo(a) inhibits proteolytic activity, we generated truncated forms of the Ser-->Arg proteolytic activity, we generated truncated forms of the Ser-->Arg mutant containing one or 10 kringle IV repeats. These truncated versions of r-apo(a) were susceptible to cleavage by tPA but were inactive against the plasmin substrate S-2251. Treatment of the Ser-->Arg mutant of the 17-kringle r-apo(a) with tPA and diisopropylflurophosphate (DFP) did not result in modification of the mutant protease domain by DFP. Finally, we incubated r-apo(a) or r-Lp(a) particles formed in vitro with purified human LDL; no degradation of LDL was observed after 16 h at 37 degrees C. The results of this study suggest that one or more of the substitutions present in the protease domain of apo(a), in addition to the Arg-->Ser substitution, render apo(a) proteolytically inactive.