Tomas Bratt

Lipocalins and cancer.

Lipocalins are mainly extracellular carriers of lipophilic molecules, though exceptions with properties like prostaglandin synthesis and protease inhibition are observed for specific lipocalins. The interest concerning lipocalins in cancer has so far been focussed to the variations in concentration and the modification of lipocalin expression in distinct cancer forms. In addition, lipocalins have been assigned a role in cell regulation. The influence of the extracellular lipocalins on intracellular cell regulation events is not fully understood, but several of the lipocalin ligands are also well-known agents in cell differentiation and proliferation. Lipophilic ligands can, after lipocalin-mediated transport to the cell surface, penetrate the cell membrane and interact with proteins in the cytosol and/or the nucleus. The signaling routes of the lipocalin ligands, retinoids and fatty acids are presented and discussed. Tumor growth in tissue is restricted by extracellular protease/protease inhibitor interactions. Several lipocalins also have protease inhibitory properties and possess the ability to interact with tumor specific proteases, revealing another pathway for lipocalins to interact with cancer cells.

The Human Antibacterial Cathelicidin, hCAP-18, Is Bound to Lipoproteins in Plasma

Cathelicidins are a family of antibacterial and lipopolysaccharide-binding proteins. hCAP-18, the only human cathelicidin, is a major protein of the specific granules of human neutrophils. The plasma level of hCAP-18 is >20-fold higher than that of other specific granule proteins relative to their levels within circulating neutrophils. The aim of this study was to elucidate the background for this high plasma level of hCAP-18. Plasma was subjected to molecular sieve chromatography, and hCAP-18 was found in distinct high molecular mass fractions that coeluted with apolipoproteins A-I and B, respectively. The association of hCAP-18 with lipoproteins was validated by the cofractionation of hCAP-18 with lipoproteins using two different methods for isolation of lipoproteins from plasma. Furthermore, the level of hCAP-18 in delipidated plasma was <1% of that in normal plasma. Immunoprecipitation of very low, low, and high density lipoprotein particles with anti-apolipoprotein antibodies resulted in coprecipitation of hCAP-18. The binding of hCAP-18 to lipoproteins was mediated by the antibacterial C-terminal part of the protein. The binding of hCAP-18 to lipoproteins suggests that lipoproteins may play an important role as a reservoir of this antimicrobial protein.

Rat α1-microglobulin: co-expression in liver with the light chain of inter-α-trypsin inhibitor

A 1162 bp rat liver cDNA clone encoding the immunoregulatory plasma protein alpha 1-microglobulin was isolated and sequenced. The open reading frame encoded a 349 amino acid polyprotein, including alpha 1-microglobulin, 182 amino acids, and bikunin, the light chain of the plasma protein inter-alpha-trypsin inhibitor, 145 amino acids. The alpha 1-microglobulin/bikunin mRNA was found only in the liver when different tissues were examined. Free alpha 1-microglobulin and a polyprotein, containing both alpha 1-microglobulin and inter-alpha-trypsin inhibitor epitopes, were found in the microsomal fraction from rat liver homogenates.

Cleavage of the α1-microglobulin-bikunin precursor is localized to the Golgi apparatus of rat liver cells

alpha 1-Microglobulin, a plasma protein with immunoregulatory properties, and bikunin, the light chain of the proteinase inhibitors inter-alpha-inhibitor and pre-alpha-inhibitor, are translated as a precursor protein from the same mRNA. The cosynthesis of alpha 1-microglobulin and bikunin is unique compared to other proproteins such as procomplement components and prohormones, since alpha 1-microglobulin and bikunin have no known functional connection. Different forms of intracellular rat liver alpha 1-microglobulin were isolated and characterized by amino acid sequence analysis, lectin binding and glycosidase treatment. Their subcellular distribution was studied by Nycodenz and sucrose gradient centrifugation, pulse-chase experiments, and electrophoresis with subsequent immunoblotting, using pro-C3 and prohaptoglobin as reference proteins. Two alpha 1-microglobulin-bikunin precursors (40 and 42 kDa), containing one and two N-linked oligosaccharides, respectively, were detected in the endoplasmic reticulum. After transport to the Golgi apparatus, the precursors were cleaved, probably C-terminal to the sequence Arg-Ala-Arg-Arg immediately preceding the bikunin part, yielding free sialylated 28 kDa alpha 1-microglobulin, representing the mature protein. The cleavage was almost complete in phosphatidylinositol 4-kinase-enriched membranes, previously identified as a post-Golgi compartment. A fourth intracellular form of alpha 1-microglobulin, 26 kDa, lacked sialic acid. None of the intracellular forms carried the yellow-brown chromophore associated with alpha 1-microglobulin when purified from serum and urine, suggesting that this chromophore becomes linked to the protein after its secretion from the liver cells.

Interactions between neutrophil gelatinase-associated lipocalin and natural lipophilic ligands.

Neutrophils are activated by both paracrine molecules, e.g. platelet activating factor (PAF) and leukotriene B4 (LTB4), and the bacterial hydrophobic peptide N-formyl-Met-Leu-Phe (fMLP). Several mechanisms are involved in regulation of the activation, including receptor endocytosis and ligand breakdown. The interactions between the specific granule protein neutrophil gelatinase-associated lipocalin (NGAL), expressed in human neutrophils, and fMLP, PAF and LTB4, were investigated by weak affinity chromatography. NGAL was immobilised to a silica matrix and packed in a micro-column and the retention times of retarded ligands were measured and used to calculate the strength of the interactions. The association constants for fMLP were K(ass) = 0.85 x 10(3) M(-1) at 20 degrees C and 0.77 x 10(3) M(-1) at 37 degrees C, for LTB4 were K(ass) = 4.37 x 10(3) M(-1) at 20 degrees C and 3.27 x 10(3) M(-1) at 37 degrees C and for PAF were K(ass) = 25.4 x 10(3) M(-1) at 20 degrees C and 10.5 x 10(3) M(-1) at 37 degrees C. Other methods of detecting the interactions such as gel filtration, immunoprecipitation, photoactivated ligands and fluorescence quenching proved to be insufficient. The results demonstrate the superiority of weak affinity chromatography as a method of studying the interactions of the specific granule protein NGAL.

Formation of the α1-microglobulin chromophore in mammalian and insect cells: a novel post-translational mechanism?

α1‐Microglobulin is an immunosuppressive plasma protein synthesized by the liver. The isolated protein is yellow‐brown, but the hypothetical chromophore has not yet been identified. In this work, it is shown that a human liver cell line, HepG2, grown in a completely synthetic and serum‐free medium, secretes α1‐microglobulin which is also yellow‐brown, suggesting a de novo synthesis of the chromophore by the cells. α1‐Microglobulin isolated from the culture medium of insect cells transfected with the gene for rat α1‐microglobulin is also yellow‐brown, suggesting that the gene carries information about the chromophore. Reduction and alkylation or removal of N‐ or O‐linked carbohydrates by glycosidase treatment did not reduce the colour intensity of the protein. An internal dodecapeptide (amino acid positions 70–81 in human α1‐microglobulin) was also yellow‐brown. The latter results indicate that the chromophore is linked to the polypeptide. In conclusion, the results suggest that the α1‐microglobulin gene carries information activating a post‐translational protein modification mechanism which is present in mammalian and insect cells.

Processing and secretion of rat α1-microglobulin-bikunin expressed in eukaryotic cell lines

The precursor protein α1‐microglobulin‐bikunin was cleaved to the same degree whether expressed in CHO cells or in mutated CHO cells, RPE.40 cells, suggested to lack a functional form of the intracellular protease furin. Thus, α1‐microglobulin‐bikunin probably is not cleaved in vivo by furin. However, simultaneous overexpression of the precursor and furin in COS, CHO and RPE.40 cells increased the cleavage, suggesting that compartmentalisation and concentrations of protease and precursor are important for the cleavage, besides the in vitro specificity. Expression of α1‐microglobulin and bikunin alone gave different protein patterns on SDS‐PAGE as compared to expression of the precursor and subsequent cleavage, suggesting that the precursor protein is important for the post‐translational handling of α1‐microglobulin and bikunin.