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First published online September 23, 2003

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Transport mechanisms of diuresis in Malpighian tubules of insects

Klaus W. Beyenbach

Department of Biomedical Sciences, VRT 8004, Cornell University, Ithaca, NY 14853, USA

View larger version (53K): [in a new window]   Fig. 1. The study of isolated Malpighian tubules. (A) The method of Ramsay (1953) for measurements of fluid secretion and for the compositional analysis of secreted fluid under well-defined experimental conditions in vitro. (B) The methods of Burg and Helman (Helman, 1972) for measurement of the transepithelial voltage (Vt) and resistance (Rt) in isolated perfused Malpighian tubules. Vbl is the voltage measured across the basolateral membrane of a principal cell impaled with a microelectrode. I is the current injected for the measurement of Rt. Voltage measurements yield electrochemical potentials of the major electrolytes, Na+, K+ and Cl-, secreted into the tubule lumen. Resistance measurements give insights into conductive and non-conductive transport mechanisms. (C) The isolated Malpighian tubule of Aedes aegypti under control conditions. To move K+ from 3.4 mmol l-1 in the peritubular bath to 91 mmol l-1 in the tubule lumen requires a driving force (chemical potential) of 87.1 mV, calculated as EK=61 mV log(91/3.4). Add to this the lumen-positive voltage of 52.6 mV (electrical potential), against which K+ is moved, to yield the total electrochemical potential (139.7 mV) needed to transport K+ into the tubule lumen. Similar calculations for Na+ yield an electrochemical potential of 40.2 mV against which this cation is secreted. To move Cl- from 158 mmol l-1 in the peritubular bath to 161 mmol l-1 in the tubule lumen requires the small driving force of -0.5 mV [ECl=-61 mV log(161/158)]. However, the transepithelial voltage is lumen-positive (52.6 mV), `pulling' Cl- into the tubule lumen. Thus, Cl- moves into the tubule lumen down (passive) an electrochemical potential of 52.1 mV.

View larger version (121K): [in a new window]   Fig. 2. Malpighian tubules of the yellow fever mosquito Aedes aegypti. The tubule presents two types of cells, principal cells and stellate cells, in a ratio of 5:1. (A) Principal cells are characterized by large intracellular concretions (spherites) of organo-metallo complexes of Ca2+, Mg2+ and K+ and by long slender microvilli containing mitochondria. (B) Stellate cell bracketed by principal cells. Stellate cells do not contain intracellular concretions and their brush borders are short and devoid of mitochondria. The basolateral membrane facing the hemolymph shows extensive infoldings. Septate junctions define the lateral border with principal cells.

View larger version (63K): [in a new window]   Fig. 3. Mechanism of transepithelial NaCl and KCl secretion in Malpighian tubules of the yellow fever mosquito Aedes aegypti under control conditions. (A) Phenotypic model. K+ enters principal cells from the peritubular Ringer bath (or hemolymph) via K+ channels located in the basolateral membrane. Na+ enters via cotransport with K+ and Cl-. Na+ and K+ are extruded from the cell across the apical membrane via K+/H+ transport and Na+/H+. The proton gradient driving the antiport is generated by an electrogenic V-type H+-ATPase located in the apical membrane. The Cl- conductance of the basolateral membrane (channel) is at present hypothetical to allow an exit mechanism for steady-state intracellular Cl- concentrations. (B) Electrical model. Outward positive current generated by the ATP-driven V-type H+-ATPase returns to the cytoplasmic face of the pump via the paracellular shunt pathway (Rsh) and the basolateral membrane (Rbl). (C) Mitochondrion that produces ATP for the V-type H+-ATPase is densely packed in the microvillus of the brush border. E, electromotive force; V, voltage; R, resistance; a, apical membrane; bl, basolateral membrane; t, transepithelial. For further details, see Beyenbach (1995, 2001) and Beyenbach et al. (2000).

View larger version (47K): [in a new window]   Fig. 4. Mechanisms of action of mosquito natriuretic peptide (MNP). MNP probably belongs to the CRF family of insect diuretic peptides. In Malpighian tubules of the yellow fever mosquito Aedes aegypti, MNP selectively increases the rates of transepithelial Na+ secretion by increasing (+) the Na+ conductance of the basolateral membrane and by activating Na+/K+/2Cl- cotransport. The second messenger of MNP and CRF-like diuretic peptides is cAMP. Whether cAMP also stimulates proton extrusion across the apical membrane is unknown. Table 2 documents the cAMP stimulation of NaCl secretion and not KCl secretion.

View larger version (40K): [in a new window]   Fig. 5. Mechanisms of action of leucokinin. Leucokinin belongs to the kinin family of insect diuretic peptides. Leucokinin increases the rates of both transepithelial NaCl and KCl secretion by increasing the paracellular Cl- conductance via intra- and extracellular Ca2+. Septate junctional proteins (claudins, neurexins) are hypothesized to form channel-like extracellular structures with permselectivity and variable conductance (Beyenbach, 2003). Table 3 documents the non-selective stimulation of transepithelial NaCl and KCl secretion. G, heterotrimeric G-protein; PLC, phospholipase C; IP3, inositol (1,4,5)-trisphosphate. Data from Yu and Beyenbach, 2002.

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