Characterization and purification of a guanidinobenzoatase: a possible marker of human renal carcinoma.

Guanidinobenzoatases are cell surface-associated proteinases supposed to be involved in cancer metastasis, cell migration, and tissue remodeling. The main features of the guanidinobenzoatase associated with human renal carcinoma plasma membrane are weak membrane association, continuous cleavage of p-nitrophenyl-p'-guanidinobenzoate conversely to the site titration effect of this compound when used with trypsin, and a peculiar sensitivity to serine protease inhibitors, compatible with a poorly active form. Plasma membrane preparation followed by agmatine-trisacryl affinity chromatography allows the purification of guanidinobenzoatase to homogeneity with an apparent enrichment factor of 450. Purified guanidinobenzoatase appears as a single polypeptide chain of M(r) 80,000, likely stabilized by intrachain disulfides bonds. The properties of purified guanidinobenzoatase indicate that it is an original enzyme in spite of some similarities with plasminogen activators. Indeed, in addition to differences in substrate and inhibitor specificity, guanidinobenzoatase is not recognized by specific monoclonal antibodies directed against plasminogen activators or their single-chain precursors. Thus, human renal carcinoma guanidinobenzoatase appears to be an original enzyme whose activity is undetectable in the nontumoral tissue of origin. In this respect, use of purified guanidinobenzoatase would allow us to obtain specific tools to give new insights in cancer cell metastasis.

[CAL 54, a new cell line derived from a human renal carcinoma: characterization and radiosensitivity]. / CAL 54, une nouvelle lignée cellulaire dérivée d'un carcinome rénal humain: caractérisation et radiosensibilité.

A new cell line (CAL 54) was isolated from a malignant pleural effusion of a patient with renal carcinoma. CAL 54 is a continuous and stable cell line. Immunochemical staining showed simultaneous expression of cytokeratin, epithelial membrane antigen and vimentin. Cytometric flow analysis of DNA content reveals one major hyperdiploid population. Histological aspect of the tumor induced in the nude mouse showed well differentiated adenocarcinoma with papillary structure. Radiation response of these cells was evaluated by the colony-forming method and the data were fitted with the linear-quadratic model. Survival at 2 Gy (SF2) was 0.28 and the mean inactivation dose (D) = 1.50 Gy, ranking this cell line among the radiation sensitive cells. CAL 54 may be an informative cell line to investigate radiation effects in the management of renal tumours.

LLC-PK1 cells express Na+-lactate cotransport in apical membranes after confluency.

L-[3H]lactate uptake was characterized in LLC-PK1 cell apical membrane vesicles obtained by intensive culture on microcarrier beads. The apical membrane preparation technique involved MgCl2 precipitation. Na+-dependent L-[3H]lactate uptake was present only after confluency; its appearance paralleled the subcellular localization of aminopeptidase in apical membranes. L-[3H]lactate uptake was Na+-dependent and electrogenic. Only the Na+-dependent component of L-[3H]lactate uptake was saturable with one family of independent carriers. The apparent affinity constant was 1.1 +/- 0.25 mM and the apparent maximal velocity was 29 +/- 3 nmol.mg-1.min-1. The Na+-lactate cotransport stoichiometry was 2 Na+ for 1 lactate. The specificity of the L-lactate transport system was compatible with that of the monocarboxylic acid pathway described previously in brush-border membranes of kidney cortex and discrete from the tricarboxylic acid carrier, the D-glucose transporter, and the general pathway for anions. The LLC-PK1 cell line appears to be a useful tool for study of the regulation of L-lactate uptake and biosynthesis of the renal monocarboxylic acid transporter.

SP220K is a novel matrix serine proteinase.

Matrix proteinases play a critical role in extracellular matrix remodeling, which is particularly involved in cancer invasion and metastasis. We have previously characterized and purified a new tetrameric serine proteinase (SP220K) from human kidney clear cell carcinoma plasma membranes. Here, we report that SP220K exhibits gelatinase activity as assessed both in solution and by zymography. Optimum gelatinase activity ranges between pH 7.5 to pH 9.0. Fibronectin and type I collagen were hydrolyzed by SP220K, at variance with laminin and type IV collagen. Like other trypsin-like fibronectin degrading proteinases, SP220K released the 29-kDa N-terminal heparin-binding domain of fibronectin. By using a panel of proteinase inhibitors, we found that the inhibition profile of SP220K was different from that of other known serine proteinases such as thrombin, trypsin, plasmin, plasminogen activators and tryptase. Altogether, our results indicate that SP220K corresponds to a novel matrix proteinase that exhibits a marked specificity for fibronectin and type I collagen.

Monomeric 55-kDa guanidinobenzoatase switches to a serine proteinase activity upon tetramerization. Tetrameric proteinase SP 220 K appears as the native form.

Guanidinobenzoatases are cell surface enzymes present in cells capable of migration or remodeling. The guanidinobenzoatase purified to homogeneity from human renal carcinoma did not display gelatinase activity under the 55-kDa form (Poustis-Delpont, C., Descomps, R., Auberger, P., Delque-Bayer, P., Sudaka, P., and Rossi, B. (1992) Cancer Res. 52, 3622-3628). We bring new insights into the structure-activity relationships of this enzyme using sodium dodecyl sulfate-polyacrylamide gel electrophoresis, [3H]diisopropyl fluorophosphate labeling, gelatin zymography, and immunodetection using a polyclonal antibody raised against the 55-kDa entity. Upon aggregation into a 220-kDa form, the enzyme exhibited [3H]diisopropyl fluorophosphate labeling and diisopropyl fluorophosphate-inhibitable gelatinase activity whereas its capability to cleave p-nitrophenyl p'-guanidinobenzoate as a substrate was abolished. Thus, the guanidinobenzoatase property appears as a feature of a 55-kDa inactive form of a serine proteinase subunit. After boiling in the presence of sodium dodecyl sulfate (3% w/v), the 220-kDa entity subjected to SDS-polyacrylamide gel electrophoresis could be dissociated into a 55-kDa protein as shown by silver staining. The resulting 55-kDa band remained [3H]diisopropyl fluorophosphate-labeled and reacted with anti-55-kDa guanidinobenzoatase antibodies, strongly suggesting that the 220-kDa proteinase was a noncovalently associated tetramer. Interestingly, Triton X-100 extracts of renal carcinoma plasma membranes exhibited a 220-kDa serine proteinase activity, as expressed in gelatin zymography, which was barely detectable in the non-tumoral counterpart. It is noteworthy that an anti-55-kDa guanidinobenzoatase reactive 220-kDa species was also observed in renal carcinoma plasma membranes extracts as assessed by Western blot, whereas it was hardly visible in the non-tumoral counterpart. No signal was immunodetected at M(r) 55,000 in renal carcinoma and kidney cortex membranes in Western blot experiments. Taken together, our data support the idea that the enzyme is expressed under its tetrameric form in the membrane. The purified enzyme is able to exhibit a serine proteinase activity when it recovers its native tetrameric form. This high molecular weight tetrameric proteinase SP 220 K appears as a new member of the cell surface serine protease family.

Differential SP220K expression in renal carcinoma and oncocytoma cells.

SP220K is a newly described serine proteinase which displays guanidinobenzoatase activity in its inactive form and gelatinolytic activity in its active form. SP220K expression was studied in 20 renal clear-cell carcinomas and in a series of renal oncocytomas, a rare benign tumor derived from the kidney tubule epithelium. We provide evidence that SP220K expression, as assessed by guanidinobenzoatase activity, gelatin zymography and Western blot immunodetection, was increased markedly in cancer basolateral membranes compared to kidney cortex controls, whereas no signal was detectable in basolateral membranes from the 5 renal oncocytomas studied. Cytoplasms of carcinoma cells were immunodetected consistently, whereas no expression was seen in oncocytic cells from any of the oncocytomas studied (12/12). Endothelial cells were immunodetected in all 3 tissue types. Our data favor a potential mechanistic relationship between expression of the matrix proteinase SP220K and invasive phenotype in kidney epithelium proliferative processes.

Two-dimensional polyacrylamide gel electrophoresis of the protease SP220K, a renal cell carcinoma marker.

The present study analyses, by two-dimensional polyacrylamide gel electrophoresis, the protease SP220K isolated from renal cell carcinoma. The pure molecule is separated using either immobilized pH gradient or isoelectric focusing in conventional carrier ampholyte in the first dimension. Some interactions with the acrylamide matrix in isoelectric focusing are discussed. The results demonstrate that two-dimensional gel electrophoresis performed with enriched media such as basolateral membranes, allows the detection of the protease. In addition, the non detection of the molecule up to now by this methodology can be explained by the high tendency of oligomerization of SP220K. Effectively the high molecular weight form of the molecule of 220 kDa is favoured in two-dimensional gel electrophoresis over monomeric forms which are better detected in SDS PAGE. This was confirmed by immunostaining performed with an antiserum to SP220K produced by nitrocellulose-bound antigen.