Christopher M. Gillen

Functional interaction of the K-Cl cotransporter (KCC1) with the Na-K-Cl cotransporter in HEK-293 cells

We have studied the regulation of the K-Cl cotransporter KCC1 and its functional interaction with the Na-K-Cl cotransporter. K-Cl cotransporter activity was substantially activated in HEK-293 cells overexpressing KCC1 (KCC1-HEK) by hypotonic cell swelling, 50 mM external K, and pretreatment with N-ethylmaleimide (NEM). Bumetanide inhibited 86Rb efflux in KCC1-HEK cells after cell swelling [inhibition constant ( K i) ∼190 μM] and pretreatment with NEM ( K i ∼60 μM). Thus regulation of KCC1 is consistent with properties of the red cell K-Cl cotransporter. To investigate functional interactions between K-Cl and Na-K-Cl cotransporters, we studied the relationship between Na-K-Cl cotransporter activation and intracellular Cl concentration ([Cl]i). Without stimulation, KCC1-HEK cells had greater Na-K-Cl cotransporter activity than controls. Endogenous Na-K-Cl cotransporter of KCC1-HEK cells was activated <2-fold by low-Cl hypotonic prestimulation, compared with 10-fold activation in HEK-293 cells and >20-fold activation in cells overexpressing the Na-K-Cl cotransporter (NKCC1-HEK). KCC1-HEK cells had lower resting [Cl]i than HEK-293 cells; cell volume was not different among cell lines. We found a steep relationship between [Cl]i and Na-K-Cl cotransport activity within the physiological range, supporting a primary role for [Cl]iin activation of Na-K-Cl cotransport and in apical-basolateral cross talk in ion-transporting epithelia.

Characterization of sarcoplasmic calcium binding protein (SCP) variants from freshwater crayfish Procambarus clarkii

Sarcoplasmic calcium binding protein (SCP) is an invertebrate EF-hand calcium buffering protein that has been proposed to fulfill a similar function in muscle relaxation as vertebrate parvalbumin. We have identified three SCP variants in the freshwater crayfish Procambarus clarkii. The variants (pcSCP1a, pcSCP1b, and pcSCP1c) differ across a 37 amino acid region that lies mainly between the second and third EF-hand calcium binding domains. We evaluated tissue distribution and response of the variants to cold exposure, a stress known to affect expression of parvalbumin. Expression patterns of the variants were not different and therefore do not provide a functional rationale for the polymorphism of pcSCP1. Compared to hepatopancreas, expression of pcSCP1 variants was 100,000-fold greater in axial abdominal muscle and 10-fold greater in cardiac muscle. Expression was 10-100 greater in fast-twitch deep flexor and extensor muscles compared to slow-twitch superficial flexor and extensors. In axial muscle, no significant changes of pcSCP1, calmodulin (CaM), or sarcoplasmic/endoplasmic reticulum Ca-ATPase (SERCA) expression were measured after one week of 4°C exposure. In contrast, large decreases of pcSCP1 were measured in cardiac muscle, with no changes in CaM or SERCA. Knockdown of pcSCP1 by dsRNA led to reduced muscle activity and decreased expression of SERCA. In summary, the pattern of pcSCP1 tissue expression is similar to parvalbumin, supporting a role in muscle contraction. However, the response of pcSCP1 to cold exposure differs from parvalbumin, suggesting possible functional divergence between the two proteins.

Cloning and characterization of a calmodulin gene (CaM) in crayfish Procambarus clarkii and expression during molting.

Calmodulin (CaM) is a highly conserved calcium (Ca(2+)) binding protein that transduces Ca(2+) signals into downstream effects influencing a range of cellular processes, including Ca(2+) homeostasis. The present study explores CaM expression when Ca(2+) homeostasis is challenged during the mineralization cycle of the freshwater crayfish (Procambarus clarkii). In this paper we report the cloning of a CaM gene from axial abdominal crayfish muscle (referred to as pcCaM). The pcCaM mRNA is ubiquitously expressed but is far more abundant in excitable tissue (muscle, nerve) than in any epithelia (gill, antennal gland, digestive) suggesting that it plays a greater role in the biology of excitation than in epithelial ion transport. In muscle cells the pcCaM was colocalized on the plasma membrane with the Ca(2+) ATPase (PMCA) known to regulate intracellular Ca(2+) through basolateral efflux. While PMCA exhibits a greater upregulation in epithelia (than in non-epithelial tissues) during molting stages requiring transcellular Ca(2+) flux (pre- and postmolt compared with intermolt), expression of pcCaM exhibited a uniform increase in epithelial and non-epithelial tissues alike. The common increase in expression of CaM in all tissues during pre- and postmolt stages (compared with intermolt) suggests that the upregulation is systemically (hormonally) mediated. Colocalization of CaM with PMCA confirms physiological findings that their regulation is linked.

Non-traditional Models: The Molecular Physiology of Sodium and Water Transport in Mosquito Malpighian Tubules

The Malpighian (renal) tubules of adult female mosquitoes are a valuable comparative model system for elucidating the mechanisms of transepithelial fluid secretion. Here we summarize the current state of knowledge on the cellular and molecular mechanisms of sodium and water transport in the tubule epithelium, and highlight key areas in which further research is needed. In brief, the epithelium contains several mechanisms for the transport of sodium, including cation proton antiporters, cation chloride cotransporters, sodium channels, sodium-coupled bicarbonate cotransporters, and a Na,K-ATPase. Moreover, the epithelium contains mechanisms for the paracellular and transcellular transport of water via septate junctions and aquaporin water channels, respectively. Collectively, these transport systems contribute to the renal maintenance of extracellular fluid homeostasis in mosquitoes, provide an accessible comparative model system for understanding the evolution of Na+ and water transport in animal epithelia, and present potential physiological targets to exploit in the control of disease vectors.

Effect of Body Size on Expression of Manduca sexta Midgut Genes

Isometric growth of larval insect midgut predicts that the ratio of midgut surface area to body mass decreases as larvae grow. Gut tissue and gut content masses were measured in first through fifth instar Manduca sexta larvae. Wet mass of gut tissue increased in relationship to body mass with a scaling exponent of 0.85 compared to an exponent of 1.33 for gut content mass, suggesting that surface area becomes increasingly limiting in larger larvae. To test the hypothesis that compensation for the decrease in relative surface area of the midgut occurs by increased expression of membrane proteins, we compared midgut mRNA expression in fourth and fifth instar. Surveyed genes encoded apical membrane proteins with diverse functions, including the potassium amino acid transporter KAAT1, ion channel CAATCH1, aminopeptidase msAPN3, V-type H-ATPase E subunit, and cation chloride cotransporter masBSC. KAAT1 was expressed 300- to 1500-fold higher in middle and posterior midgut compared to anterior midgut. Expression of msAPN3 was approximately 200-fold higher in posterior midgut than middle midgut. Expression of KAAT1 was 2.3- to 3.1-fold higher in fifth compared to fourth-instar larvae, and masBSC expression was 1.3- to 1.9-fold higher in fifth-instar larvae. Expression of msAPN3 and V-ATPase, but not KAAT1, decreased as body mass increased within the fifth instar. Although the increased expression of KAAT1 and masBSC in fifth-instar larvae supports the hypothesis of increased membrane protein expression in larger larvae, results from the other genes do not support this hypothesis.

Elongation factor 1Bγ (eEF1Bγ) expression during the molting cycle and cold acclimation in the crayfish Procambarus clarkii

Eukaryotic elongation factor 1Bgamma (eEF1Bgamma) is a subunit of elongation factor 1 (EF1), which regulates the recruitment of amino acyl-tRNAs to the ribosome during protein synthesis in eukaryotes. In addition to structural roles within eEF1, eEF1Bgamma has properties which suggest sensory or regulatory activities. We have cloned eEF1Bgamma from axial abdominal muscle of freshwater crayfish, Procambarus clarkii. The predicted amino acid sequence has 66% identity to Locusta migratoria eEF1Bgamma and 65% identity to Artemia salina eEF1Bgamma. We measured eEF1Bgamma expression by real-time PCR, using the relative quantification method with 18s ribosomal RNA as an internal calibrator. eEF1Bgamma expression was lowest in gill, axial abdominal muscle, and hepatopancreas, and was highest in the antennal gland (5.7-fold above hepatopancreas) and cardiac muscle (7.8-fold above hepatopancreas). In axial abdominal muscle, eEF1Bgamma expression was 4.4-fold higher in premolt and 11.9 higher in postmolt compared to intermolt. In contrast, eEF1Bgamma was decreased or unchanged in epithelial tissues during pre- and postmolt. eEF1Bgamma expression in the hepatopancreas was 3.5-fold higher during intermolt compared to premolt and was unchanged in gill and antennal gland. No significant differences in eEF1Bgamma were found after 1 week of acclimation to 4 degrees C. These results show that eEF1Bgamma is regulated at the mRNA level with tissue-specific differences in expression patterns.

Calcium Binding to Procambarus clarkii Sarcoplasmic Calcium Binding Protein Splice Variants

Sarcoplasmic calcium binding protein (SCP) is a high-affinity calcium buffering protein expressed in muscle of crayfish and other invertebrates. In previous work, we identified three splice variants of Procambarus clarkii SCP (pcSCP1a, pcSCP1b, and pcSCP1c) that differ in a 37 amino acid region that lies mainly between the 2nd and 3ed EF-hand calcium binding domain. To evaluate the function of the proteins encoded by the pcSCP1 transcripts, we produced recombinant pcSCP1 and used tryptophan fluorescence to characterize calcium binding. Tryptophan fluorescence of pcSCP1a decreased in response to increased calcium, while tryptophan fluorescence of the pcSCP1b and pcSCP1c variants increased. We estimated calcium binding constants and Hill coefficients with two different equations: the standard Hill equation and a modified Hill equation that accounts for contributions from two different tryptophans. The approaches gave similar results. Steady-state calcium binding constants (Kd) ranged from 2.7±0.7×10(-8)M to 5.6±0.1×10(-7)M, consistent with previous work. Variants displayed significantly different apparent calcium affinities, which were decreased in the presence of magnesium. Calcium Kd was lowest for pcSCP1a and highest for pcSCP1c. Site-directed mutagenesis of pcSCP1c residues to the amino acids of pcSCP1b decreased the calcium Kd, identifying residues outside the EF-hand domains that contribute to calcium binding in crayfish SCP.

Characterization of Rb Uptake into Sf9 Cells Using Cation Chromatography: Evidence for a K-Cl Cotransporter

To assess cation-chloride cotransporter activity in Sf9 cells, cation chromatography was used to measure initial uptake rates of Rb. Rb exchanged with cellular K, with 30% of cellular K replaced after a 40 min exposure to Rb. Rb uptake into Sf9 cells was not inhibited by 50 µmol l(-1) ouabain. Rb uptake was approximately 65% inhibited by 250 µmol l(-1) bumetanide added to the assay solution, and was more than 95% inhibited when cells were pre-incubated for 20 min with bumetanide (100 and 1000 µmol l(-1)). Uptake of Rb and Cl followed simple Michaelis-Menten kinetics, with a K(m) for Rb of 17.1+/-2.2 mmol l(-1) and a K(m) for Cl of 93.7+/-5.6 mmol l(-1). Rb uptake was not dependent upon extracellular Na. Two min exposures to solutions with reduced [Na] or [Cl] produced small but significant changes in cellular Na content. We conclude that the primary Rb uptake pathway in Sf9 cells is a K-Cl cotransporter and that cation chromatography can be used to effectively study kinetic parameters of cotransporter function in tissue culture cells. Characterization of baseline cation-chloride cotransporter activity in Sf9 cells strengthens their utility as a tool for expression and characterization of exogenous proteins.

Epithelial Calcium Transport in Crustaceans: Adaptation to Intrinsic and Extrinsic Stressors

Since the classical studies of Ussing employing a nonmammalian isolated epithelium (frog skin) to explore the basic principles of ion transport, physiologists have adopted increasingly reductionist approaches to dissect the biophysical mechanisms undergirding biological transport. In vitro characterization has employed isolated perfused organs, isolated epithelia, and reconstituted vesicle studies. Depth of resolution has been further enhanced by the emerging molecular revolution. Following years of deconstruction, physiologists are now engaging in reconstruction, namely putting the genes back into the organism. This contribution attempts such an integrative approach for a single electrolyte, calcium (Ca2+), in a nonmammalian epithelium, the crayfish antennal gland (kidney). Two collaborating laboratories have archived an inventory of Ca2+ associated proteins believed to play a role in transcellular Ca2+ movement. Using the basic building blocks (expression profiles of key Ca2+ associated proteins and their regulators), the authors attempt to reconstruct a whole cell model for Ca2+ regulation in transporting epithelium (compared with a nonepithelial tissue) under stressors that perturb Ca2+ homeostasis which originate either intrinsically (the postmolt stage of the molting cycle) or extrinsically (unanticipated cold acclimation). Through horizontal integration of expression profiles of seven target Ca2+ associated proteins in epithelial and nonepithelial tissue under two contrasting experimental conditions, emergent themes inform the physiological complexity of Ca2+ homeostasis. Integration at the next level will require placing the epithelium in the context of organismic Ca2+ balance. The unique Ca2+ handling capabilities of the freshwater crayfish make it an excellent nonmammalian model for those studies.

Differential expression of putative sodium-dependent cation-chloride cotransporters in Aedes aegypti

The yellow fever mosquito, Aedes aegypti, has three genes that code for proteins with sequence similarity to vertebrate Na+-K+-Cl- cotransporters (NKCCs) of the solute-linked carrier 12 superfamily of cation-chloride cotransporters (CCCs). We hypothesized that these mosquito NKCC orthologues have diverged to perform distinct roles in salt secretion and absorption. In phylogenetic analyses, one protein (aeNKCC1) groups with a Drosophila melanogaster NKCC that mediates salt secretion whereas two others (aeCCC2 and aeCCC3) group with a Drosophila transporter that is not functionally characterized. The aeCCC2 and aeCCC3 genes probably result from a tandem gene duplication in the mosquito lineage; they have similar exon structures and are consecutive in genomic DNA. Predicted aeCCC2 and aeCCC3 proteins differ from aeNKCC1 and vertebrate NKCCs in residues from the third transmembrane domain known to influence ion and inhibitor binding. Quantitative PCR revealed that aeNKCC1 and aeCCC2 were approximately equally expressed in larvae and adults, whereas aeCCC3 was approximately 100-fold more abundant in larvae than in adults. In larval tissues, aeCCC2 was approximately 2-fold more abundant in Malpighian tubules compared to anal papillae. In contrast, aeCCC3 was nearly 100-fold more abundant in larval anal papillae compared to Malpighian tubules, suggesting a role in absorption. Western blots with polyclonal antibodies against isoform-specific peptides revealed stronger aeCCC2 immunoreactivity in adults versus larvae, whereas aeCCC3 immunoreactivity was stronger in larvae versus adults. The differential expression pattern of aeCCC2 and aeCCC3, and their sequence divergence in transmembrane domains, suggests that they may have different roles in transepithelial salt transport.