Kristian Prydz

Selective Effects of Sodium Chlorate Treatment on the Sulfation of Heparan Sulfate

We have analyzed the effect of sodium chlorate treatment of Madin-Darby canine kidney cells on the structure of heparan sulfate (HS), to assess how the various sulfation reactions during HS biosynthesis are affected by decreased availability of the sulfate donor 3′-phosphoadenosine 5′-phosphosulfate. Metabolically [3H]glucosamine-labeled HS was isolated from chlorate-treated and untreated Madin-Darby canine kidney cells and subjected to low pH nitrous acid cleavage. Saccharides representing (i) the N-sulfated domains, (ii) the domains of alternatingN-acetylated and N-sulfated disaccharide units, and (iii) the N-acetylated domains were recovered and subjected to compositional disaccharide analysis. Upon treatment with 50 mm chlorate, overall O-sulfation of HS was inhibited by ∼70%, whereas N-sulfation remained essentially unchanged. Low chlorate concentrations (5 or 20 mm) selectively reduced the 6-O-sulfation of HS, whereas treatment with 50 mm chlorate reduced both 2-O- and 6-O-sulfation. Analysis of saccharides representing the different domain types indicated that 6-O-sulfation was preferentially inhibited in the alternating domains. These data suggest that reduced 3′-phosphoadenosine 5′-phosphosulfate availability has distinct effects on the N- and O-sulfation of HS and thatO-sulfation is affected in a domain-specific fashion.

A proteoglycan undergoes different modifications en route to the apical and basolateral surfaces of Madin-Darby canine kidney cells

We have grown polarized epithelial Madin-Darby canine kidney II (MDCK II) cells on filters in the presence of [35S]sulfate, [3H]glucosamine, or [35S]cysteine/[35S]methionine to study proteoglycan (PG) synthesis, sorting, and secretion to the apical and basolateral media. Whereas most of the [35S]sulfate label was recovered in basolateral PGs, the [3H]glucosamine label was predominantly incorporated into the glycosaminoglycan chains of apical PGs, indicating that basolateral PGs are more intensely sulfated than their apical counterparts. Expression of the PG serglycin with a green fluorescent protein tag (SG-GFP) in MDCK II cells produced a protein core secreted 85% apically, which was largely modified by chondroitin sulfate chains. Surprisingly, the 15% of secreted SG-GFP molecules recovered basolaterally were more heavily sulfated and displayed a different sulfation pattern than the apical counterpart. More detailed studies of the differential modification of apically and basolaterally secreted SG-GFP indicate that the protein cores have been designated to apical and basolateral transport platforms before pathway-specific, post-translational modifications have been completed.

In vitro formation of bile acids from di- and trihydroxy-5β-cholestanoic acid in human liver peroxisomes

The conversion of 3 alpha,7 alpha,12 alpha-trihydroxy-5 beta-[3H]cholestanoic acid into cholic acid and 3 alpha,7 alpha-dihydroxy-5 beta-[3H]cholestanoic acid into chenodeoxycholic acid has been studied in subcellular fractions of human liver. The products were separated from the substrates by high-pressure liquid chromatography and identified by combined gas chromatography-mass spectrometry. The highest rates of conversion were found in the light mitochondrial fraction. This fraction also contained the highest amount of the marker enzymes for peroxisomes. The maximal rates of cholic acid and chenodeoxycholic acid formation were 1.3 and 1.8 nmol/mg protein per h, respectively. The presence of KCN in the incubation medium stimulated the formation of bile acids. Peroxisomes were prepared from the light mitochondrial fraction by sucrose-gradient centrifugation. By use of different marker enzymes, it was confirmed that the major part of the activity for cholic acid formation in the light mitochondrial fraction was located in the peroxisomes. It is concluded that liver peroxisomes are important for the oxidative cleavage of the C27 steroid side chain in bile acid formation in man.

Epigenetics: methylation-associated repression of heparan sulfate 3-O-sulfotransferase gene expression contributes to the invasive phenotype of H-EMC-SS chondrosarcoma cells

Heparan sulfate proteoglycans (HSPGs), strategically located at the cell‐tissue‐organ interface, regulate major biological processes, including cell proliferation, migration, and adhesion. These vital functions are compromised in tumors, due, in part, to alterations in heparan sulfate (HS) expression and structure. How these modifications occur is largely unknown. Here, we investigated whether epigenetic abnormalities involving aberrant DNA methylation affect HS biosynthetic enzymes in cancer cells. Analysis of the methylation status of glycosyltransferase and sulfotransferase genes in H‐HEMC‐SS chondrosarcoma cells showed a typical hypermethylation profile of 3‐OST sulfotransferase genes. Exposure of chondrosarcoma cells to 5‐aza‐2′‐deoxycytidine (5‐Aza‐dc), a DNA‐methyltransferase inhibitor, up‐regulated expression of 3‐OST1, 3‐OST2, and 3‐OST3A mRNAs, indicating that aberrant methylation affects transcription of these genes. Furthermore, HS expression was restored on 5‐Aza‐dc treatment or reintroduction of 3‐OST expression, as shown by indirect immunofluorescence microscopy and/or analysis of HS chains by anion‐exchange and gel‐filtration chromatography. Notably, 5‐Aza‐dc treatment of HEMC cells or expression of 3‐OST3A cDNA reduced their proliferative and invading properties and augmented adhesion of chondrosarcoma cells. These results provide the first evidence for specific epigenetic regulation of 3‐OST genes resulting in altered HSPG sulfation and point to a defect of HS‐3‐O‐sulfation as a factor in cancer progression.—Bui, C., Ouzzine, M., Talhaoui, I., Sharp, S., Prydz, K., Coughtrie, M. W. H., Fournel‐Gigleux, S. Epigenetics: methylation‐associated repression of heparan sulfate 3‐O‐sulfo‐transferase gene expression contributes to the invasive phenotype of H‐EMC‐SS chondrosarcoma cells. FASEB J. 24, 436–450 (2010). www.fasebj.org

Serglycin is implicated in the promotion of aggressive phenotype of breast cancer cells.

Serglycin is a proteoglycan expressed by some malignant cells. It promotes metastasis and protects some tumor cells from complement system attack. In the present study, we show for the first time the in situ expression of serglycin by breast cancer cells by immunohistochemistry in patients’ material. Moreover, we demonstrate high expression and constitutive secretion of serglycin in the aggressive MDA-MB-231 breast cancer cell line. Serglycin exhibited a strong cytoplasmic staining in these cells, observable at the cell periphery in a thread of filaments near the cell membrane, but also in filopodia-like structures. Serglycin was purified from conditioned medium of MDA-MB-231 cells, and represented the major proteoglycan secreted by these cells, having a molecular size of ∼250 kDa and carrying chondroitin sulfate side chains, mainly composed of 4-sulfated (∼87%), 6-sulfated (∼10%) and non-sulfated (∼3%) disaccharides. Purified serglycin inhibited early steps of both the classical and the lectin pathways of complement by binding to C1q and mannose-binding lectin. Stable expression of serglycin in less aggressive MCF-7 breast cancer cells induced their proliferation, anchorage-independent growth, migration and invasion. Interestingly, over-expression of serglycin lacking the glycosaminoglycan attachment sites failed to promote these cellular functions, suggesting that glycanation of serglycin is a pre-requisite for its oncogenic properties. Our findings suggest that serglycin promotes a more aggressive cancer cell phenotype and may protect breast cancer cells from complement attack supporting their survival and expansion.

How many ways through the Golgi maze

The secretory route in eukaryotic cells has been regarded as one common pathway from the endoplasmic reticulum (ER) through the Golgi cisternae to the trans Golgi network where recognition, sorting and exit of cargo molecules are thought to occur. Morphologically, the ribosome‐coated ER is observed throughout the cytoplasm, while the Golgi apparatus usually is confined to a perinuclear position in mammalian cells. However, Golgi outposts have been observed in neuronal dendrites and dispersed Golgi elements in skeletal muscle myofibers. In insects, like in Drosophila melanogaster imaginal disc cells and epidermal cells of Tobacco and Arabidopsis leafs, individual Golgi stacks are distributed throughout the cytoplasm. Golgi stacks do not only differ in their intracellular localization but also in the number of stacks from one to several hundreds. Each stack consists of closely aligned, flattened, membrane‐limited cisternae. The number of cisternae in a Golgi stack is also variable, 2–3 in some ciliates, 10 in many plant cell types and up to 30 in certain euglenoids. The yeast Saccharomyces cerevisiae has a Golgi structure of minimal complexity with scattered solitary cisternae. It is assumed that the number of Golgi cisternae reflects the overall complexity of the enzymatic reactions that occur in their lumen, while the number of stacks reflects the load of macromolecules arriving at the cis side. In this review, we will focus on how the available morphological and biochemical data fit with the current view of protein sorting in the secretory pathway, particularly in polarized cells like neuronal and epithelial cells.

Determinants of Glycosaminoglycan (GAG) Structure

Proteoglycans (PGs) are glycosylated proteins of biological importance at cell surfaces, in the extracellular matrix, and in the circulation. PGs are produced and modified by glycosaminoglycan (GAG) chains in the secretory pathway of animal cells. The most common GAG attachment site is a serine residue followed by a glycine (-ser-gly-), from which a linker tetrasaccharide extends and may continue as a heparan sulfate, a heparin, a chondroitin sulfate, or a dermatan sulfate GAG chain. Which type of GAG chain becomes attached to the linker tetrasaccharide is influenced by the structure of the protein core, modifications occurring to the linker tetrasaccharide itself, and the biochemical environment of the Golgi apparatus, where GAG polymerization and modification by sulfation and epimerization take place. The same cell type may produce different GAG chains that vary, depending on the extent of epimerization and sulfation. However, it is not known to what extent these differences are caused by compartmental segregation of protein cores en route through the secretory pathway or by differential recruitment of modifying enzymes during synthesis of different PGs. The topic of this review is how different aspects of protein structure, cellular biochemistry, and compartmentalization may influence GAG synthesis.

Lithocholic acid and sulphated lithocholic acid differ in the ability to promote matrix metalloproteinase secretion in the human colon cancer cell line CaCo-2.

The human colon carcinoma cell line CaCo-2 has the ability to sulphate the secondary bile acid lithocholic acid (LA), whereas other primary or secondary bile acids were not sulphated [Halvorsen, Kase, Prydz, Gharagozlian, Andresen and Kolset (1999) Biochem. J. 343, 533--539]. To study the biological implications of this modification, CaCo-2 cells were incubated with either LA or sulphated lithocholic acid (3-sulpholithocholic acid, SLA), and in some experiments with taurine-conjugated lithocholic acid. Increased secretion of matrix metalloproteinases (MMPs) correlates with transformation of colon epithelial cells. When CaCo-2 cells were incubated with LA, the secretion of MMP-2 was found to increase approx. 60% when analysed by gelatin zymography, and 80% when analysed by Western blotting. SLA, in contrast, did not affect the level of MMP-2 secretion, and after zymography the level of enzyme activity was 78% of control values after 18 h incubation. The secretion of MMPs is linked to increased cellular invasion and, in tumours, to increased capacity for metastasis. The ability of CaCo-2 cells to invade in a chamber assay was stimulated after exposure to LA, whereas SLA-treated cells did not differ from control cells. LA therefore seems to induce a more invasive CaCo-2 cell phenotype, as judged by the two parameters tested, whereas the sulphated counterpart, SLA, did not have these effects. Sulphation of LA in the colon may be an important mechanism to decrease the potential LA has to promote a malignant epithelial phenotype.

Studies on the interrelated stimuiation of microsomal ω-oxidation and peroxisomal β-oxidation in rat liver with a partially hydrogenated fish oil diet

Abstract To investigate the mechanism for initiation of peroxisomal β-oxidation by high-fat diets the time-courses of peroxisomal β-oxidation and microsomal ω-oxidation stimulated by 20% (w/w) partially hydrogenated fish oil were studied. The relative stimulation of these two activities developed in a very similar, way. We observed an elevated level of long-chain acyl-CoA with partially hydrogenated fish oil, but not of free acids. There was, however, a significant shift in the composition of free fatty acids to a higher amount of monoenes and lower amounts of 18:2 and 20:4 fatty acids. In peroxisomes purified by Nycodenz centrifugation there was no lauric acid hydroxylation. This study indicates that with partially hydrogenated fish oil we obtain a parallel stimulation of reactions in two different cellular compartments. Dicarboxylic fatty acids, which are products of the ω-oxidation, had only a slight stimulatory effect on peroxisomal β-oxidation. Therefore, the primary stimulatory agent of peroxisomal β-oxidation and microsomal ω-oxidation is still unknown. It was speculated that this agent may activate a gene-locus responsible for both reactions.

A Secretory Golgi Bypass Route to the Apical Surface Domain of Epithelial MDCK Cells

Proteins leave the endoplasmic reticulum (ER) for the plasma membrane via the classical secretory pathway, but routes bypassing the Golgi apparatus have also been observed. Apical and basolateral protein secretion in epithelial Madin‐Darby canine kidney (MDCK) cells display differential sensitivity to Brefeldin A (BFA), where low concentrations retard apical transport, while basolateral transport still proceeds through intact Golgi cisternae. We now describe that BFA‐mediated retardation of glycoprotein and proteoglycan transport through the Golgi apparatus induces surface transport of molecules lacking Golgi modifications, possessing those acquired in the ER. Low concentrations of BFA induces apical Golgi bypass, while higher concentrations were required to induce basolateral Golgi bypass. Addition of the KDEL ER‐retrieval sequence to model protein cores allowed observation of apical Golgi bypass in untreated MDCK cells. Basolateral Golgi bypass was only observed after the addition of BFA or upon cholesterol depletion. Thus, in MDCK cells, an apical Golgi bypass route can transport cargo from pre‐Golgi organelles in untreated cells, while the basolateral bypass route is inducible.