Lung vascular targeting using antibody to aminopeptidase P: CT-SPECT imaging, biodistribution and pharmacokinetic analysis.

BACKGROUND/AIMS: Aminopeptidase P (APP) is specifically enriched in caveolae on the luminal surface of pulmonary vascular endothelium. APP antibodies bind lung endothelium in vivo and are rapidly and actively pumped across the endothelium into lung tissue. Here we characterize the immunotargeting properties and pharmacokinetics of the APP-specific recombinant antibody 833c. METHODS: We used in situ binding, biodistribution analysis and in vivo imaging to assess the lung targeting of 833c. RESULTS: More than 80% of 833c bound during the first pass through isolated perfused lungs. Dynamic SPECT acquisition showed that 833c rapidly and specifically targeted the lungs in vivo, reaching maximum levels within 2 min after intravenous injection. CT-SPECT imaging revealed specific targeting of 833c to the thoracic cavity and co-localization with a lung perfusion marker, Tc99m-labeled macroaggregated albumin. Biodistribution analysis confirmed lung-specific uptake of 833c which declined by first-order kinetics (t(½) = 110 h) with significant levels of 833c still present 30 days after injection. CONCLUSION: These data show that APP expressed in endothelial caveolae appears to be readily accessible to circulating antibody rather specifically in lung. Targeting lung-specific caveolar APP provides an extraordinarily rapid and specific means to target pulmonary vasculature and potentially deliver therapeutic agents into the lung tissue.

Dynamin at the neck of caveolae mediates their budding to form transport vesicles by GTP-driven fission from the plasma membrane of endothelium.

The molecular mechanisms mediating cell surface trafficking of caveolae are unknown. Caveolae bud from plasma membranes to form free carrier vesicles through a "pinching off" or fission process requiring cytosol and driven by GTP hydrolysis (Schnitzer, J.E., P. Oh, and D.P. McIntosh. 1996. Science. 274:239-242). Here, we use several independent techniques and functional assays ranging from cell-free to intact cell systems to establish a function for dynamin in the formation of transport vesicles from the endothelial cell plasma membrane by mediating fission at the neck of caveolae. This caveolar fission requires interaction with cytosolic dynamin as well as its hydrolysis of GTP. Expression of dynamin in cytosol as well as purified recombinant dynamin alone supports GTP-induced caveolar fission in a cell-free assay whereas its removal from cytosol or the addition to the cytosol of specific antibodies for dynamin inhibits this fission. Overexpression of mutant dynamin lacking normal GTPase activity not only inhibits GTP-induced fission and budding of caveolae but also prevents caveolae-mediated internalization of cholera toxin B chain in intact and permeabilized endothelial cells. Analysis of endothelium in vivo by subcellular fractionation and immunomicroscopy shows that dynamin is concentrated on caveolae, primarily at the expected site of action, their necks. Thus, through its ability to oligomerize, dynamin appears to form a structural collar around the neck of caveolae that hydrolyzes GTP to mediate internalization via the fission of caveolae from the plasma membrane to form free transport vesicles.

Filipin-sensitive caveolae-mediated transport in endothelium: reduced transcytosis, scavenger endocytosis, and capillary permeability of select macromolecules.

Caveolae or noncoated plasmalemmal vesicles found in a variety of cells have been implicated in a number of important cellular functions including endocytosis, transcytosis, and potocytosis. Their function in transport across endothelium has been especially controversial, at least in part because there has not been any way to selectively inhibit this putative pathway. We now show that the ability of sterol binding agents such as filipin to disassemble endothelial noncoated but not coated plasmalemmal vesicles selectively inhibits caveolae-mediated intracellular and transcellular transport of select macromolecules in endothelium. Filipin significantly reduces the transcellular transport of insulin and albumin across cultured endothelial cell monolayers. Rat lung microvascular permeability to albumin in situ is significantly decreased after filipin perfusion. Conversely, paracellular transport of the small solute inulin is not inhibited in vitro or in situ. In addition, we show that caveolae mediate the scavenger endocytosis of conformationally modified albumins for delivery to endosomes and lysosomes for degradation. This intracellular transport is inhibited by filipin both in vitro and in situ. Other sterol binding agents including nystatin and digitonin also inhibit this degradative process. Conversely, the endocytosis and degradation of activated alpha 2-macroglobulin, a known ligand of the clathrin-dependent pathway, is not affected. Interestingly, filipin appears to inhibit insulin uptake by endothelium for transcytosis, a caveolae-mediated process, but not endocytosis for degradation, apparently mediated by the clathrin-coated pathway. Such selective inhibition of caveolae not only provides critical evidence for the role of caveolae in the intracellular and transcellular transport of select macromolecules in endothelium but also may be useful for distinguishing transport mediated by coated versus noncoated vesicles.

Role of GTP hydrolysis in fission of caveolae directly from plasma membranes.

Caveolae are specialized invaginated cell surface microdomains of undefined function. A cell-free system that reconstituted fission of caveolae from lung endothelial plasma membranes was developed. Addition of cytosol and the hydrolysis of guanosine triphosphate (GTP) induced caveolar fission. The budded caveolae were isolated as vesicles rich in caveolin and the sialoglycolipid GM1 but not glycosyl-phosphatidylinositol (GPI)-anchored proteins. These vesicles contained the molecular machinery for endocytosis and transcytosis. In permeabilized endothelial cells, GTP stimulated, whereas GTPgammaS prevented, caveolar budding and endocytosis of the cholera toxin B chain to endosomes. Thus, caveolae may bud to form discrete carrier vesicles that participate in membrane trafficking.

Separation of caveolae from associated microdomains of GPI-anchored proteins.

In situ coating of the surface of endothelial cells in rat lung with cationic colloidal silica particles was used to separate caveolae from detergent-insoluble membranes rich in glycosyl phosphatidylinositol (GPI)-anchored proteins but devoid of caveolin. Immunogold electron microscopy showed that ganglioside GM1-enriched caveolae associated with an annular plasmalemmal domain enriched in GPI-anchored proteins. The purified caveolae contained molecular components required for regulated transport, including various lipid-anchored signaling molecules. Such specialized distinct microdomains may exist separately or together in the plasma membrane to organize signaling molecules and to process surface-bound ligands differentially.

Vascular proteomic mapping in vivo.

Molecular targeting of drugs and imaging agents remain important yet elusive goals in modern medicine. Technological advancements in genomics and proteomics methods have detected differentially expressed genes and proteins, uncovering many new candidate targets in a wide array of diseases and tissues. However, methods to validate potential targets in vivo tend to be quite laborious so that the validation and testing phase has become rate-limiting in bringing treatments to the clinic. There is a critical need for integrated approaches combining state-of-the-art methodologies in proteomics and in vivo imaging to accelerate validation of newly discovered vascular targets for nanomedicines, drugs, imaging agents, and gene vectors. This paper is a review of vascular targeting and proteomics, and will present recent developments in proteomic imaging. A new in vivo organellar proteomic imaging platform will be discussed, which combines subcellular fractionation, mass spectrometry, bioinformatic database interrogation, monoclonal antibody technology and a battery of imaging modalities to rapidly discover and validate tissue-specific endothelial protein targets in vivo. Technological advancements are permitting large-scale proteomic mapping to be performed. New targets have been discovered that permit organ-specific targeting in vivo. Improvements in imaging are creating standards for validation of targets in vivo. Tumor imaging and radioimmunotherapy have also been improved through these efforts. Although we are moving towards a comprehensive mapping of the protein expression by the endothelium, much more needs to be done.

Segregation of heterotrimeric G proteins in cell surface microdomains. G(q) binds caveolin to concentrate in caveolae, whereas G(i) and G(s) target lipid rafts by default.

Select lipid-anchored proteins such as glycosylphosphatidylinositol (GPI)-anchored proteins and nonreceptor tyrosine kinases may preferentially partition into sphingomyelin-rich and cholesterol-rich plasmalemmal microdomains, thereby acquiring resistance to detergent extraction. Two such domains, caveolae and lipid rafts, are morphologically and biochemically distinct, contain many signaling molecules, and may function in compartmentalizing cell surface signaling. Subfractionation and confocal immunofluorescence microscopy reveal that, in lung tissue and in cultured endothelial and epithelial cells, heterotrimeric G proteins (G(i), G(q), G(s), and G(betagamma)) target discrete cell surface microdomains. G(q) specifically concentrates in caveolae, whereas G(i) and G(s) concentrate much more in lipid rafts marked by GPI-anchored proteins (5' nucleotidase and folate receptor). G(q), apparently without G(betagamma) subunits, stably associates with plasmalemmal and cytosolic caveolin. G(i) and G(s) interact with G(betagamma) subunits but not caveolin. G(i) and G(s), unlike G(q), readily move out of caveolae. Thus, caveolin may function as a scaffold to trap, concentrate, and stabilize G(q) preferentially within caveolae over lipid rafts. In N2a cells lacking caveolae and caveolin, G(q), G(i), and G(s) all concentrate in lipid rafts as a complex with G(betagamma). Without effective physiological interaction with caveolin, G proteins tend by default to segregate in lipid rafts. The ramifications of the segregated microdomain distribution and the G(q)-caveolin complex without G(betagamma) for trafficking, signaling, and mechanotransduction are discussed.

Tumor cell growth inhibition by caveolin re-expression in human breast cancer cells.

Cancer development is a multistage process that results from the step-wise acquisition of somatic alterations in diverse genes. Recent studies indicate that caveolin-1 expression correlates with the level of oncogenic transformation in NIH3T3 cells, suggesting that caveolin in caveolae may regulate normal cell proliferation. In order to better understand potential functions of caveolin-1 in cancer development, we have studied expression levels of caveolin-1 in human breast cancer cells, and have found that caveolin expression is significantly reduced in human breast cancer cells compared with their normal mammary epithelial counterparts. When the caveolin cDNA linked to the CMV promoter is transfected into human mammary cancer cells having no detectable endogenous caveolin, overexpression of caveolin-1 resulted in substantial growth inhibition, as seen by the 50% decrease in growth rate and by approximately 15-fold reduction in colony formation in soft agar. In addition, characterization of caveolin-1 expression during cell cycle progression indicates that expression of alpha-caveolin-1 is regulated during cell cycle. Furthermore p53-deficient cells showed a loss in caveolin expression. In summary, the overall expression patterns, its ability to inhibit tumor growth in culture, its regulation during the cell cycle, and the loss of expression in p53-deficient cells all are consistent with an important growth regulating function for caveolin-1 in normal human mammary cells, that needs to be repressed in oncogenic transformation and tumor cell growth.

Update on the cellular and molecular basis of capillary permeability.

The attenuated layer of endothelial cells lining the blood vessels forms the critical barrier controlling the exchange of molecules from the blood to the interstitial fluid. The interactions of normally circulating blood molecules with the endothelial glycocalyx can either restrict transcapillary exchange in general or selectively increase transendothelial transport of a specific group of ligands. Investigations into the mechanisms responsible for the effects of serum have identified specific receptors, some of which appear to be involved in receptor-mediated transcytosis and endocytosis via noncoated plasmalemma vesicles (also known as caveolae). Such studies suggest that regional differences in endothelial expression of cell surface glycoproteins can be exploited for the development of tissue-directed drug therapies.

Lectin analysis of common glycoproteins detected on the surface of continuous microvascular endothelium in situ and in culture: identification of sialoglycoproteins.

For many years, molecular interactions with vascular endothelium have been studied in vitro on cultured endothelial cells. Yet, it is clear that the different environmental conditions in vivo vs. in vitro may cause phenotypic drift and altered expression of cell surface molecules. In this study, we identify several endothelial surface proteins of similar apparent molecular mass by radioiodination of cultured microvascular cells and by intravascular radioiodination of rat heart endothelium in situ. The radioiodinated surface polypeptides detected by sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) (followed by autoradiography) were subjected to lectin affinity chromatography in order to provide an additional screen for identifying common surface glycoproteins and a means for partial characterization of their glycans. With a battery of 18 lectins, seven major (gp140, gp120, gp100, gp85, gp75, gp60, gp47) and 6 minor (gp330, gp300, gp180, gp160, gp150, gp42) glycoproteins were identified on the cultured cells each with a different lectin binding profile. The lectin binding profiles of many endothelial glycoproteins in situ were similar to those of their counterparts in culture. A common set of seven major glycoproteins with the same apparent molecular masses was found in situ as well as in vitro. These common glycoproteins were characterized further using both sialidase digestion and sequential lectin affinity chromatography of cell lysates. Most of the glycoproteins appear to have both complex-type N-linked and O-linked glycans except for gp60 with only O-linked glycans, gp47 with only complex N-linked sugars, and gp42 with only simple N-linked sugars. A subset of sialoglycoproteins (gp140, gp120, gp100, gp60, gp47) was identified. One of them, gp120, is podocalyxin based on immunoprecipitation with specific antiserum and another one, gp60, is a recently identified albumin binding protein on the surface of cultured microvascular endothelial cells. This study shows that gp60 is indeed present on the surface of endothelium in situ and that it is a sialoglycoprotein with typical O-linked glycans. It is apparent that the continuous type of microvascular endothelium can indeed express in culture and in situ a common set of major glycoproteins.

Isolation and partial characterization of the luminal plasmalemma of microvascular endothelium from rat lungs.

This paper describes a procedure for isolating in high yield and at a high degree of purity the endothelial luminal plasmalemma from the microvasculature of the rat lung. The procedure relies on the modification of the density of the luminal plasmalemma obtained by coating it by perfusion in situ first, with cationized colloidal silica and then with Na polyacrylate. These steps generate a strongly adhering coat to the luminal plasmalemma that resists tissue homogenization to yield, upon repeated centrifugation through Nycodenz density gradients, a nearly homogeneous fraction of coated luminal plasmalemmal fragments still carrying their associated plasmalemmal vesicles. The fraction is enriched in the luminal plasmalemmal antigen, angiotensin converting enzyme, contains gp60, an antigen expected to occur on both plasmalemmal domains, is not enriched in either alkaline phosphatase or 5'-nucleotidase activity and is free of the mitochondrial and endoplasmic reticulum antigens so far tested. This procedure, that can be extended--in principle--to any vascular bed, obviates the use of cultured cells for studying the biochemistry of the endothelium, at least as far as the luminal endothelial plasmalemma is concerned.

Caveolae: from basic trafficking mechanisms to targeting transcytosis for tissue-specific drug and gene delivery in vivo.

Continuous endothelium and epithelium create formidable barriers to endogenous molecules as well as targeted drug and gene therapies in vivo. Caveolae represent a possible vesicular trafficking pathway through cell barriers. Here we discuss recent discoveries regarding the basic function of caveolae in transport including transcellular trafficking, intracellular trafficking to distinct endosomes, and molecular mechanisms mediating their budding, docking and fusion (dynamin and SNARE machinery). New technologies to purify and map caveolae as well as generate new probes selectively targeting caveolae in vivo provide valuable tools not only for investigating caveolar endocytosis/transcytosis but also elucidating new potential applications for site-directed treatment of many diseases. Vascular targeting of the caveolar trafficking pathway may be a useful strategy for achieving tissue-specific pharmacodelivery that also overcomes key, normally restrictive cell barriers which greatly reduce the efficacy of many therapies in vivo.

Analysis of steric partition behavior of molecules in membranes using statistical physics. Application to gel chromatography and electrophoresis.

The principles of statistical physics are used to formulate general expressions for the steric partition behavior of molecules in both random and ordered membrane structures that may be applied to any shape of the solute and/or the volume-excluding element of the membrane. These expressions fully define partitioning in terms of the volume excluded to point molecules and to finite-sized molecules. The mean effective exclusion volume for a molecule is calculated as a function of a global interaction energy, which varies with position, conformation, and orientation of the molecule. It allows consideration of electrostatic and other nonsteric factors. To test the model, specific partition functions are derived for several simple geometries describing the membrane and solute. Frequently, the derived expressions agree with past analyses; however, a new expression describing partitioning within an random network of fibers is derived. It agrees with past results only in the limit of low exclusion volumes. With greater volume exclusions, past results greatly overestimate the partition function. It is applied to gel electrophoresis and chromatography and survives testing with available experimental data. Unlike past analyses, it predicts nonlinear Ferguson plots for agarose gel electrophoresis. In addition, an analytical expression predicting the minimum radius of a sphere excluded from a random fiber matrix is derived, tested, and found to agree with experimental data.

gp60 is an albumin-binding glycoprotein expressed by continuous endothelium involved in albumin transcytosis.

Albumin reduces capillary permeability and acts as a carrier for various small molecules. Recently, we identified a 60-kDa sialoglycoprotein (gp60) on the surface of cultured rat microvascular endothelial cells (MEC) that binds albumin and antiglycophorin serum (alpha-gp). We verified that alpha-gp recognizes the albumin-binding gp60 by affinity, purifying proteins from MEC extracts using immobilized albumin. gp60 was immunoblotted with alpha-gp only when the MEC extract was reacted with albumin and not in controls. We immunoprecipitated gp60 from biosynthetically radiolabeled MEC lysates and from extracts containing endothelial surface proteins of isolated rat hearts that were radioiodinated in situ. gp60 was immunoblotted selectively in rat tissue microvascular beds lined with continuous endothelium (heart, lung, diaphragm, fat, skeletal muscle, mesentery, and duodenal muscularis but not cortical brain) and not those exclusively lined with fenestrated or sinusoidal endothelium (adrenal, pancreas, liver, and small intestinal mucosa). MEC isolated from rat heart, lung, and epididymal fat pad expressed gp60 and bound albumin, whereas various nonendothelial cells and brain-derived MEC did not. gp60 is an albumin-binding glycoprotein expressed specifically on the surface of continuous endothelium that binds albumin apparently not only to initiate its transcytosis via plasmalemmal vesicles but also to increase capillary permselectivity.

Glycocalyx electrostatic potential profile analysis: ion, pH, steric, and charge effects.

The Poisson-Boltzmann equation is modified to consider charge ionogenicity, steric exclusion, and charge distribution in order to describe the perimembranous electrostatic potential profile in a manner consistent with the known morphology and biochemical composition of the cell's glycocalyx. Exact numerical and approximate analytical solutions are given for various charge distributions and for an extended form of the Donnan potential model. The interrelated effects of ionic conditions, bulk pH, ion binding, local dielectric, steric volume exclusion, and charge distribution on the local potential, pH, and charge density within the glycocalyx are examined. Local charge-induced, potential-mediated pH reductions cause glycocalyx charge neutralization. Under certain conditions, local potentials may be insensitive to ionic strength or may decrease in spite of increasing charge density. The volume exclusion of the glycocalyx reduces the local ion concentration, thereby increasing the local potential. With neutral lipid membranes, the Donnan and surface potential agree if the glycocalyx charge distribution is both uniform and several times thicker than the Debye length (approximately 20 A in thickness under physiological conditions). Model limitations in terms of application to microdomains or protein endo- and ectodomains are discussed.

Antibodies to SPARC inhibit albumin binding to SPARC, gp60, and microvascular endothelium.

Albumin, through its binding to the endothelial glycocalyx, functions as a major determinant of capillary permeability and as a carrier for various small molecules in its transcytosis across continuous endothelium via plasma-lemmal vesicles. Several albumin-binding proteins (ABP) have been identified: three membrane-associated ABP, which we call gp60, gp30, and gp18, and one secreted protein, acidic and rich in cysteine (SPARC). In this study, we used antiserum raised against bovine SPARC (BON) to investigate the possible interrelationships among ABP to better understand their role in binding and transcytosis. BON not only interacted with SPARC secreted by cultured endothelium but also recognized gp60 in lysates of cultured rat, human, and bovine endothelial cells. Purified SPARC inhibited BON interaction with gp60. BON immunoglobulin (Ig)G specifically inhibited albumin binding to both SPARC and gp60 extracts. This effect was eliminated by preabsorption of BON to immobilized SPARC. BON also significantly inhibited albumin binding to cultured microvascular endothelial cells via its interaction with gp60. Anti-SPARC peptide sera were also tested, and one serum raised against a peptide encompassing an NH2-terminal region of SPARC recognized both SPARC and gp60 but did not inhibit albumin binding; gp30 and gp18 were not recognized by any of these anti-SPARC antibodies. These results suggest that SPARC and gp60 are functionally and immunologically related ABP that may share a common albumin-binding domain. gp60 appears to be the major mediator of albumin binding to microvascular endothelium.

Quantitation of specific binding of orosomucoid to cultured microvascular endothelium: role in capillary permeability.

Orosomucoid (also known as alpha 1-acid glycoprotein) is a highly sialylated, polyanionic serum glycoprotein. Its presence in vascular perfusates alters microvascular permeability, presumably by binding to the endothelial glycocalyx, but the rest of its functions remains unknown. In this study, we assess the binding of bovine serum orosomucoid (BSO) to the surface of bovine pulmonary microvascular endothelial cells (BLMVEC) in culture at 4 degrees C. The binding of radioiodinated BSO (125I-BSO) reached equilibrium after 10 min of incubation, was not calcium dependent, and was reversible by greater than 80% in 30 min. The binding of 125I-BSO was competed with unlabeled BSO but not by transferrin, immunoglobulin, gelatin, ovalbumin, mannan, fucoidan, mucin, or asialomucin. In addition, binding was not affected by the presence of galactose, glucose, fucose, mannose, N-acetyl-D-galactosamine, or N-acetyl-D-glucosamine. This binding behavior is not consistent with carbohydrate recognition by lectin-like molecules such as the asialoglycoprotein receptor. Scatchard analysis of the BSO binding to BLMVEC produced a concave-upward shaped curve, which revealed a higher affinity binding component with an apparent equilibrium affinity constant (Kd) of 8.6 nM and a maximum receptor number of 40,000/cell and revealed a moderate affinity component with a Kd of 9.1 microM with a maximum binding of 10(7) binding sites per cell. Other blood vessel-associated cells clearly bound less BSO with a lower binding affinity than the BLMVEC monolayers. From the binding data, we estimated the total increase in the negative charge of the glycocalyx with orosomucoid binding to be approximately 17 meq/l.(ABSTRACT TRUNCATED AT 250 WORDS)

Aquaporin-1 in plasma membrane and caveolae provides mercury-sensitive water channels across lung endothelium.

Classically, water transport across endothelium of the continuous type found in the microvessels of many organs such as lung was thought to occur almost completely via the paracellular pathway through intercellular junctions. Direct transmembrane and transcellular transport was considered to be minimal. In this study, we focused on the critical transport interface in direct contact with the circulating blood by purifying luminal endothelial cell plasma membranes directly from rat lungs and then isolating the noncoated plasmalemmal vesicles or caveolae from these membranes. Immunoblotting of these fractions showed that the transmembrane water channel protein aquaporin-1 was amply expressed on the endothelial cell surface at levels comparable to rat erythrocyte plasma membranes. It was found concentrated, but not exclusively, in caveolae. The functional role of these water channels in transport was examined in rat lungs perfused in situ with tritiated water by testing known inhibitors of aquaporin-1-mediated transmembrane water transport. Mercurial sulfhydryl reagents such as HgCl2 reversibly reduced tritiated water uptake without affecting small solute transport. Just like certain epithelia, endothelia might express physiologically relevant amounts of aquaporin-1 on their cell surface to permit direct, mercurial-sensitive, transcellular transport of water.