Thomas Jöns

Production of polyclonal antibodies against proteins and peptides.

Publisher Summary This chapter focuses on the most commonly used procedures for production, purification, and characterization of polyclonal antibodies against proteins and peptides raised in rabbits and mice. The main purpose of the immune system is to bind and eliminate foreign molecules (antigens), such as bacterial toxins that have invaded an individual. This task is mainly accomplished by immunoglobulins, which are water-soluble glycoproteins that carry the specific antibody activity. The main reason for the preferential use of polyclonal antibodies is that their generation is rather simple, quick, and inexpensive, whereas the production of monoclonal antibodies requires equipment and skills in cell culture techniques and is relatively time consuming and expensive. In addition, a suitable test system must be established to screen hundreds of cell culture supernatants to identify and select the clones—producing the monoclonal antibodies of interest. Polyclonal antibodies raised against a protein are usually directed against more than one epitope. An advantage of polyepitopic specificity is that denaturation of proteins by SDS or by fixation with aldehydes usually will not destroy all epitopes so that polyclonal antibodies can be used in most instances for both immunoblotting and for immunostaining of chemically fixed cells and tissues.

The maintenance of the permeability barrier of bladder facet cells requires a continuous fusion of discoid vesicles with the apical plasma membrane

The luminal surface of the bladder epithelium is continuously exposed to urine that differs from blood in its ionic composition and osmolality. The apical plasma membrane of facet or umbrella cells, facing the urine, is covered with rigid-looking plaques consisting of hexagonal uroplakin particles. Together with tight junctions these plaques form a specialized membrane compartment that represents one of the tightest and most impermeable barriers in the body. Plaques also occur in the membrane of cytoplasmic discoid vesicles. Here it is shown shown that synaptobrevin, SNAP23 and syntaxin are perfectly colocalized with uroplakin III at the apical plasma membrane as well as with membranes of discoid vesicles. Such a distribution suggests that discoid vesicles in facet cells may gain access to the apical plasma membrane probably by combination of homotypic and heterotypic fusion events. Furthermore, we detected uroplakin III-containing membranes of different sizes in the urine of healthy humans and rats. Probably facet cells maintain their permeability barrier by a process of continuous membrane regeneration that includes the cutting off of areas of the apical membrane and its replacement by newly fused discoid vesicles.

Anion exchanger 2. (AE2) binds to erythrocyte ankyrin and is colocalized with ankyrin along the basolateral plasma membrane of human gastric parietal cells

The hydrochloric acid secreting parietal cells of the human stomach mucosa have been shown to express anion exchanger 2 (AE2). AE2 is restricted to the basolateral membrane domain and is responsible for the basolateral uptake of Cl- and release of HCO3-. It is unknown which mechanism is responsible for the basolateral positioning of AE2 in parietal cells. We raised the question whether AE2 might be immobilized at the cell surface by linkage via ankyrin to the spectrin/actin-based membrane cytoskeleton. In the present study we communicate two observations that support this hypothesis, namely that in parietal cells ankyrin is localized with AE2 along the basolateral cell surface and, secondly, that purified erythrocyte ankyrin binds to the in vitro-translated cytoplasmic domain of AE2. We conclude from these observations that AE2 in parietal cells might be linked via ankyrin to the basolateral membrane cytoskeleton and that this type of linkage might play a role in immobilizing AE2 in a non-random fashion along the basolateral membrane domain.

Expression of rat kidney anion exchanger 1 in type A intercalated cells in metabolic acidosis and alkalosis

By enzyme-linked in situ hybridization (ISH), direct evidence is provided that acid-secreting intercalated cells (type A IC) of both the cortical and medullary collecting ducts of the rat kidney selectively express the mRNA of the kidney splice variant of anion exchanger 1 (kAE1) and no detectable levels of the erythrocyte AE1 (eAE1) mRNA. Using single-cell quantification by microphotometry of ISH enzyme reaction, medullary type A IC were found to contain twofold higher kAE1 mRNA levels compared with cortical type A IC. These differences correspond to the higher intensity of immunostaining in medullary versus cortical type A IC. Chronic changes of acid-base status induced by addition of NH4Cl (acidosis) or NaHCO3 (alkalosis) to the drinking water resulted in up to 35% changes of kAE1 mRNA levels in both cortical and medullary type A IC. These experiments provide direct evidence at the cellular level of kAE1 expression in type A IC and show moderate capacity of type A IC to respond to changes of acid-base status by modulation of kAE1 mRNA levels.By enzyme-linked in situ hybridization (ISH), direct evidence is provided that acid-secreting intercalated cells (type A IC) of both the cortical and medullary collecting ducts of the rat kidney selectively express the mRNA of the kidney splice variant of anion exchanger 1 (kAE1) and no detectable levels of the erythrocyte AE1 (eAE1) mRNA. Using single-cell quantification by microphotometry of ISH enzyme reaction, medullary type A IC were found to contain twofold higher kAE1 mRNA levels compared with cortical type A IC. These differences correspond to the higher intensity of immunostaining in medullary versus cortical type A IC. Chronic changes of acid-base status induced by addition of NH(4)Cl (acidosis) or NaHCO3 (alkalosis) to the drinking water resulted in up to 35% changes of kAE1 mRNA levels in both cortical and medullary type A IC. These experiments provide direct evidence at the cellular level of kAE1 expression in type A IC and show moderate capacity of type A IC to respond to changes of acid-base status by modulation of kAE1 mRNA levels.

K+-ATP-channel-related protein complexes: potential transducers in the regulation of epithelial tight junction permeability

K+-ATP channels are composed of an inwardly rectifying Kir6 subunit and an auxiliary sulfonylurea receptor (SUR) protein. The SUR subunits of Kir6 channels have been recognized as an ATPase, which appears to work as a mechanochemical device like other members of the ABC protein family. Thus, in spite of just gating ions, Kir6/Sur might, in addition, regulate completely different cellular systems. However, so far no model system was available to directly investigate this possibility. Using highly specific antibodies against Kir6.1-SUR2A and an in vitro model system of the rat small intestine, we describe a new function of the Kir6.1-SUR2A complex, namely the regulation of paracellular permeability. The Kir6.1-SUR2A complex localizes to regulated tight junctions in a variety of gastrointestinal, renal and liver tissues of rat, pig and human, whereas it is absent in the urothelium. Changes in paracellular permeability following food intake was investigated by incubating the lumen of morphological well-defined segments of rat small intestine with various amounts of glucose. Variations in the lumenal glucose concentrations and regulators of Kir6.1/SUR2A activity, such as tolbutamide or diazoxide, specifically modulate paracellular permeability. The data presented here shed new light on the physiological and pathophysiological role K+-ATP channels might have for the regulation of tight junctions.

CYTOSKELETON-MEMBRANE CONNECTIONS IN THE HUMAN ERYTHROCYTE MEMBRANE: BAND 4.1 BINDS TO TETRAMERIC BAND 3 PROTEIN

Band 4.1 provides, besides ankyrin, the main linkage between the erythrocyte membrane and its cytoskeleton. Its predominant binding sites in the membrane are located on the glycophorins. However, the cytoplasmic domain of band 3 can also bind band 4.1. We have studied which of the different band 3 oligomers observed (monomers, dimers, tetramers) can act as band 4.1 binding sites, by equilibrium sedimentation experiments on mixtures of purified band 3 and dye-labelled band 4.1 in solutions of a nonionic detergent. At low molar ratios of band 4.1 and band 3, the sedimentation equilibrium distributions obtained could all be perfectly fitted assuming that only two dye-labelled particles were present: uncomplexed band 4.1 and a complex formed between one band 4.1 molecule and one band 3 tetramer. The presence of small amounts of complexes containing band 3 monomers or dimers could not be completely ruled out but is unlikely. On the other hand, stabilized band 3 dimers effectively bound band 4.1. At higher molar band 4.1/band 3 ratio, the band 3 tetramer apparently could bind up to at least four band 4.1 molecules. The band 4.1/band 3 tetramer complex was found to be unstable. The results described, together with those reported previously, point at a prominent role of tetrameric band 3 in ligand binding.

SAP 97 is a potential candidate for basolateral fixation of ezrin in parietal cells.

Abstractu2002Acid secretion in gastric parietal cells is preceded by a dramatic increase in surface area of the apical membrane compartment, due to fusion of the H+/K+-ATPase-containing tubulovesicles. The resulting canaliculi must be fixed for a period of minutes by cytoskeletal elements to sustain acid secretion. Using immunofluorescence microscopy, the cytoskeletal linker molecule, ezrin, localizes to the apical canalicular membrane of parietal cells. Antibodies against ezrin precipitate H+/K+-ATPase and β-actin. In addition to its apical localization, ezrin is found to be colocalized at the basolateral compartment with synapse-associated protein (SAP) 97. Immunoprecipitation confirms a direct binding of SAP 97 and ezrin. We conclude that ezrin is fixed to the basolateral compartment by SAP 97. Upon stimulation of acid secretion, ezrin moves to the apical surface where it might stabilize the canalicular microvilli by connecting to β-actin and H+/K+-ATPase, thereby sustaining acid secretion.

Acid secretion of parietal cells is paralleled by a redistribution of NSF and α, β-SNAPs and inhibited by tetanus toxin

Abstract. Stimulation of parietal cells causes fusion of intracellular tubulovesicles with the canalicular plasma membrane thereby increasing the apical membrane area up to tenfold. The presence of the SNARE proteins synaptobrevin, syntaxin1, and SNAP25 in parietal cells and their intracellular redistribution after stimulation suggest a SNARE-mediated mechanism. Here we show that NSF and α,xa0β-SNAPs which are involved in the dissociation of the SNARE complex in neurons also occur in parietal cells exhibiting subcellular distributions similar to the ones obtained for SNARE proteins and for the H+,xa0K+-ATPase. More importantly proteolytic cleavage of synaptobrevin by tetanus neurotoxin completely inhibits the cAMP-dependent increase of acid secretion further supporting the crucial role SNARE proteins play in parietal cells.

Cytoskeleton and Epithelial Polarity

The membrane surface of polarized epithelial cells can be divided in apical and basolateral domains that differ in molecular composition and function. Components of the cytoskeleton are involved in critical steps of both generation and maintenance of cell polarity. Generation of polarity is controlled by microtubules that serve as uniformly aligned and polarized cytoplasmic guiding structures for the vectorial and selective transport of Golgi-derived carrier vesicles to the apical cell surface. Targeting of membrane proteins to the basolateral cell surface does not depend on microtubules but follows the constitutive bulk flow of membranes. Once inserted into the lipid bilayer several membrane proteins such as the kidney anion exchanger 1 (AE1) and the sodium pump become immobilized at specialized microdomains of the lateral cell surface. Evidence is provided that both membrane proteins are linked via ankyrin to the spectrin-based membrane cytoskeleton that underlies the basolateral membrane domain. Linkage of these and other integral membrane proteins to the cytoskeleton may not only place them to specialized sites of the plasma membrane but may also prevent these transporters from clustering and endocytosis, thus helping them to stay at the cell surface. In search of sequence motifs involved in binding of integral membrane proteins to components of the cytoskeleton we found that the binding interface of AE1 to protein 4.1 (an actin and spectrin cross-linking protein) consists of a cluster of five amino acid residues, namely IRRRY in AE1 and LEEDY on protein 4.1. This motif may play a more general role in cytoskeleton membrane linkages.

SNARE proteins and rab3A contribute to canalicular formation in parietal cells.

SNARE proteins - rab3A - parietal cells - H+/K+-ATPase When stimulated by histamine, acetylcholine, or gastrin the luminal compartments of oxyntic parietal cells display conspicuous morphological changes. The luminal plasma membrane surface becomes greatly expanded, while the cytoplasmic tubulovesicles are decreased in parallel. Due to these membrane rearrangements the H+/K(+)-ATPase obtains access to the luminal surface, where proton secretion occurs. The stimulation-induced translocation of H+/K(+)-ATPase involves a fusion process. Exocytotic membrane fusion in neurons is achieved by the highly regulated interaction of mainly three proteins, the vesicle protein synaptobrevin and the plasma membrane proteins syntaxin and SNAP25 (synaptosomal-associated protein of 25 kDa), also referred to as SNARE proteins. Using immunofluorescence microscopy we analysed the subcellular distribution of neuronal synaptic proteins and rab3A in resting and stimulated parietal cells from pig and rat. In resting cells all synaptic proteins colocalized with the H+/ K(+)-ATPase trapped in the tubulovesicular compartment. After stimulation, translocated H+/K(+)-ATPase showed a typical canalicular distribution. Syntaxin, synaptobrevin, SNAP25 and rab3A underwent a similar redistribution in stimulated cells and consequently localized to the canalicular compartment. Using immunoprecipitation we found that the SNARE complex consisting of synaptobrevin, syntaxin and SNAP25, which is a prerequisite for membrane fusion in neurons, is also assembled in parietal cells. In addition the parietal cell-derived synaptobrevin could be proteolytically cleaved by tetanus toxin light chain. These data may provide evidence that SNARE proteins and rab3A are functionally involved in the stimulation-induced translocation of the H+/K(+)-ATPase.