ABSTRACT
BACKGROUND: The vasopressin V2 receptor is expressed in the polarized principal cell of the renal collecting duct. Inactivating mutations of the vasopressin V2 receptor gene cause X-linked nephrogenic diabetes insipidus (NDI). Most of the mutant V2 receptors show transport defects, as analyzed in non-polarized cells, but data pertaining to polarized cells have not previously been presented. METHODS: Madin-Darby canine kidney cell (MDCK) II clones stably expressing c-myc-tagged human V2 receptors were characterized for [3H]-arginine vasopressin (AVP)-binding and AVP-sensitive adenylyl cyclase activity. The V2 receptors were immunocytochemically localized using the tyramide signal amplification technique in conjunction with an anti-c-myc antibody. RESULTS: The introduction of the c-myc epitope at the N- or C-terminus did not affect the functional properties of the V2 receptor expressed in MDCK II clones. However, the use of standard immunofluorescence methodology for these MDCK II clones yielded only weak signals. With the tyramide signal amplification technique, strong signals were obtained, showing the V2 receptor to be mainly localized within the lateral and, to a minor extent, apical membrane. In MDCK II clones stably expressing the c-myc-tagged V2 receptor NDI mutant L44P, fluorescent signals were found exclusively within the cell. CONCLUSION: The wild-type V2 receptor is expressed mainly in the lateral membrane, whereas the L44P mutant is completely retained within the cell. In conjunction with tyramide signal amplification, MDCK II cells constitute a suitable model for the analysis of transport-defective mutants of the V2 receptor.
Subject(s)
Kidney Tubules, Distal/chemistry , Kidney Tubules, Distal/cytology , Receptors, Vasopressin/genetics , Adenylyl Cyclases/metabolism , Animals , Biological Transport/physiology , Cell Line , Cell Membrane/chemistry , Cell Membrane/metabolism , DNA Probes , Diabetic Nephropathies/genetics , Diabetic Nephropathies/physiopathology , Dogs , Gene Expression/physiology , Humans , Kidney Tubules, Distal/enzymology , Membrane Proteins/genetics , Membrane Proteins/metabolism , Mutagenesis, Site-Directed/physiology , Proto-Oncogene Proteins c-myc/genetics , RNA, Messenger/analysis , Receptors, Vasopressin/metabolism , Recombinant Proteins/analysis , Recombinant Proteins/genetics , Transfection , Tritium , X ChromosomeSubject(s)
Clostridium tetani/metabolism , Peptide Biosynthesis , Protein Biosynthesis , Transcription, Genetic , Amino Acids/metabolism , Autoradiography/methods , Cell-Free System , DNA/metabolism , DNA, Bacterial/isolation & purification , DNA, Bacterial/metabolism , Electrophoresis, Polyacrylamide Gel/methods , Indicators and Reagents , Kinetics , Methionine/metabolism , Peptides/isolation & purification , Potassium/pharmacology , Protein Biosynthesis/drug effects , Restriction Mapping , Ribonucleotides/metabolism , Sulfur Radioisotopes , Transcription, Genetic/drug effectsABSTRACT
The pore-forming activity of tetanus toxin, its chains and fragments was studied on membrane patches from spinal cord neurons of fetal mice using the outside-out patch-clamp configuration. 1. The dichain tetanus toxin forms pores at pH 5, but not at pH 7.4. The elementary pore conductance is 38.4 +/- 1.1 pS and nonselective for small cations. The open probability of the pores is voltage-dependent and increases with membrane depolarisation. The pores activate at +80 mV with a time constant of about 20 ms and deactivate at -80 mV with two time constants of about 2 ms and 10 ms. Besides the elementary pore conductance, larger pore conductances which are multiples of the elementary conductance were observed. With increasing conductances, their frequency of occurrence decreases exponentially. 2. The light chain of tetanus toxin alone does not form pores in neuronal membranes at pH 5 or at pH 7.4. 3. The heavy chain of tetanus toxin forms pores at pH 5 as well as at pH 7.4. The single pore conductance increases from 35.0 +/- 1.2 pS at pH 5 to 43.2 +/- 1.8 pS at pH 7.4. The pores allow mono- and divalent cations and chloride ions to pass. Only at pH 5 do they have a voltage dependence with time constants identical to those obtained with tetanus toxin. 4. Secondary structure predictions show a high density of presumably helically organized elements in fragment beta 2 (45 kDa) of the heavy chain between residues 700-850.(ABSTRACT TRUNCATED AT 250 WORDS)
Subject(s)
Neurons/drug effects , Peptide Fragments/pharmacology , Protein Structure, Secondary , Tetanus Toxin/pharmacology , Animals , Cell Membrane/drug effects , Cell Membrane/ultrastructure , Cells, Cultured , Chemical Phenomena , Chemistry, Physical , Evaluation Studies as Topic , Hydrogen-Ion Concentration , Mice , Molecular Weight , Neurons/ultrastructure , Peptide Fragments/chemistry , Spinal Cord/cytology , Spinal Cord/drug effects , Structure-Activity Relationship , Tetanus Toxin/chemistryABSTRACT
To define epitopes of tetanus toxin, we compared four different in vitro systems in terms of their ability to produce tetanus toxin-specific subfragments from cloned DNA. A transcription-translation system developed from a nontoxigenic strain of Clostridium tetani was found to yield predominantly full-sized peptides. Such peptides were used to map six different epitopes for eight monoclonal antibodies. The toxin-neutralizing properties of the antibodies were determined in an in vitro assay, based on the toxin-mediated inhibition of norepinephrine release from rat brain particles. Two monoclonal antibodies recognizing epitopes within the regions Ser-744 to Ser-864 and Ile-1224 to Asp-1315 could neutralize the toxin. A third nonneutralizing antibody was shown to recognize the synthetic peptide Phe-947 to Glu-967 derived from the tetanus toxin sequence. This peptide contains a human T-cell epitope.
