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norpA and itpr mutants reveal roles for phospholipase C and inositol (1,4,5)- trisphosphate receptor in Drosophila melanogaster renal function

Valerie P. Pollock¹, Jonathan C. Radford¹, Susan Pyne², Gaiti Hasan³, Julian A. T. Dow¹ and Shireen-A. Davies^1,*

¹ Institute of Biomedical and Life Sciences, Division of Molecular Genetics, University of Glasgow, Glasgow G11 6NU, UK
² Department of Physiology and Pharmacology, Strathclyde Institute for Biomedical Sciences, University of Strathclyde, Glasgow G4 ONR, UK
³ National Centre for Biological Sciences, UAS-GKVK Campus, Bangalore 560065, India

View larger version (15K): [in a new window]   Fig. 1. An epithelial phenotype for norpA: phospholipase Cß (PLCß) is required for neuropeptide stimulation of principal and stellate cells. Fluid transport assays were performed on intact tubules from wild-type (Oregon R), norpAH52 and norpAP24 flies as described in the Materials and methods. Either (A) 10-7 moll-1 CAP2b or (B) 10-7 moll-1 Drosokinin were added at 30 min (arrow), and transport rates were measured for a further 30 min. Data are expressed as mean secretion rates ± S.E.M. (N=8).

View larger version (20K): [in a new window]   Fig. 2. Resting and CAP2b-stimulated inositol (1,4,5)-trisphosphate (IP3) levels in itpr mutants. (A) Resting IP3 levels are shown for tubules from the following lines: Oregon R (control), itprXR12/+, itpr90B.0/+, itpr1664/+, itpr1664/itprXR12, itpr1664/itpr90B.0, itpr1664/itpr1664 and itprWC361/itprUG3. In order to aid comparison between experiments, data are shown as the % difference between IP3 levels in itpr mutants compared with wild type (100%) ± S.E.M. (N=4). Typical IP3 content of wild-type tubules was as described in Table 1. (B) CAP2b stimulates IP3 production in itpr lines. Stimulated IP3 levels were measured in CAP2b-stimulated tubules (10-7 moll-1, 5s). Data are expressed as the % increase of unstimulated IP3 levels (calculated as [stimulated IP3]/[resting IP3]x100%; [IP3] measured in pmol µg protein-1) ± S.E.M. (N=3-4). Significant differences between IP3 content in wild-type and itpr lines are denoted by * (P<0.05, Student's t-test, unpaired samples).

View larger version (21K): [in a new window]   Fig. 3. CAP2b- and Drosokinin-stimulated fluid transport are inhibited in itpr mutants. Fluid transport assays were performed on intact tubules as described in Fig. 1 for the following lines: Oregon R (control), itprXR12/+, itpr90B.0/+, itpr1664/+, itpr1664/itprXR12, itpr1664/itpr90B.0, itpr1664/itpr1664 and itprWC361/itprUG3. Either (A) 10-7 moll-1 CAP2b or (B) 10-7 moll-1 Drosokinin were added at 30 min, and transport rates were measured for a further 30 min. No change in basal secretion rate was observed in itpr mutants. Furthermore, kinetics of the fluid secretion response in all lines were similar (data not shown). To aid comparison between stimulated transport rates, data are expressed as the % stimulation of secretion [(maximal stimulated rates minus the mean of three basal secretion rate readings)/(mean basal rate)x100% ± S.E.M.; N=15-20] upon stimulation with CAP2b or Drosokinin. Stimulated fluid transport rates that are significantly different from wild type are denoted by * (P<0.05, Student's t-test, unpaired samples).

View larger version (20K): [in a new window]   Fig. 4. itpr rescues the transport phenotype of the itpr90B.0 allele. Fluid transport assays were performed on the hsGAL4;itpr90B.0 line. The data show that CAP2b-stimulated fluid transport is decreased in this line. Rescue of hsGAL4;itpr90B.0 with UAS-itpr results in wild-type levels of stimulated fluid transport. Fluid secretion rates were measured for 30 min prior to addition of neuropeptide (arrow), after which measurements were taken for a further 30 min. Data are expressed as mean fluid secretion rates (nl min-1) ± S.E.M. (N=6-10). UAS-itpr tubules display similar secretion rates to those of wild-type tubules (data not shown).

View larger version (21K): [in a new window]   Fig. 5. CAP2b-induced cytosolic calcium signals in itpr mutants. (A) Typical traces of changes in intracellular Ca2+ concentration ([Ca2+]i) in tubule principal cells stimulated by 10-7 moll-1 CAP2b (arrows) in the following lines: (i) aeq;hsGAL4;+ (control), (ii) aeq;hsGAL4;itprXR12/+, (iii) aeq;hsGAL4;itpr90B.0/+, (iv) aeq;hsGAL4;itpr1664/+, (v) aeq;hsGAL4;itpr1664/itpr1664 and (vi) aeq;hsGAL4;itprWC361/itprUG3. Each sample contains 20 intact tubules. While no changes in the resting [Ca2+]i is seen in any of the mutants, changes in amplitude of the primary and/or secondary response can be observed in all lines (also in B). (B) Pooled results of changes in tubule [Ca2+]i in itpr mutants in response to 10-7 moll-1 CAP2b are shown. Results are expressed as means ± S.E.M. (N=8) for background (open bars), CAP2b-stimulated primary peaks (filled bars) and CAP2b-stimulated secondary peaks (hatched bars) for the lines described in A. The measure of secondary peak is taken as the average [Ca2+]i over 4 min post-stimulation with CAP2b. CAP2b-stimulated primary peaks that are significantly different from aeq;hsGAL4 tubules are denoted by *, and statistically significant differences in secondary peaks compared to wild type are denoted by (P<0.05, Student's t-test, unpaired samples).

View larger version (19K): [in a new window]   Fig. 6. Drosokinin-induced cytosolic calcium signals in itpr mutants. (A) Typical traces of changes in intracellular Ca2+ concentration ([Ca2+]i) in tubule stellate cells stimulated by 10-7 mol l-1 Drosokinin (arrows) in the following lines: (i) aeq;hsGAL4;+ (control), (ii) aeq;hsGAL4; itprXR12/+, (iii) aeq;hsGAL4;itpr90B.0/+, (iv) aeq;hsGAL4;itpr1664/+, (v) aeq;hsGAL4;itpr1664/itpr1664 and (vi) aeq;hsGAL4;itprWC361/itprUG3. Each sample contains 20 intact tubules. While no changes in the resting [Ca2+]i is seen in any of the mutants, changes in amplitude of the calcium peak can be observed in aeq;hsGAL4;itpr1664/itpr1664 and aeq;hsGAL4;itprWC361/itprUG3 (also in B). (B) Pooled results of changes in tubule [Ca2+]i in itpr mutants in response to 10-7 moll-1 Drosokinin. Results are expressed as means ± S.E.M. (N=8) for background (open bars) and Drosokinin-stimulated peaks (filled bars) for the lines described in A. Drosokinin-stimulated primary peaks that are significantly different from aeq;hsGAL4;+ tubules are denoted by * (P<0.05, Student's t-test, unpaired samples).