Morrill GA, Kostellow AB, Moore RD, Gupta RK.

GM-071324 NIGMS NIH HHS , HD-10463 NICHD NIH HHS

	Figure 1. Comparison of mammalian and Xenopus laevis: insulin and insulin receptor structures. The upper panel compares the amino acid sequences of Porcine (Accession #P01315) and X. laevis (Accession #P12706) insulin-1. The lower panel compares the alignment of the α-subunits of the X. laevis insulin receptor (Accession #Q9PVZ4; sequence 38–754) and human insulin receptor (Accession #P06213; sequence 28–758). Data are from the unprocessed sequences as listed in the Swiss Protein Knowledgebase (http://www.uniprot.org).
	Figure 2. Scatchard type plot of [125I]insulin binding to the plasma-vitelline membrane complex of denuded R. pipiens oocytes. Intact, denuded prophase oocytes were incubated in Ringer’s solution containing [125I]insulin for 15 min at 20–22°C, the oocytes removed, rinsed with Ringer’s solution and the membranes removed and counted as described in Methods. The [125I]insulin binding data were corrected by subtracting the constant binding fraction.
	Figure 3. A comparison of the time course of insulin effects on 45Ca2+/Na+ exchange and fluid phase uptake ([14C]insulin) by isolated denuded R. pipiens oocytes at 20–22°C, plotted as rate of change per unit time (dy/dt). The values are in pmols/oocyte for 45Ca2+ and [14C]inulin, respectively. Each point presents a pooled sample of 5–10 sibling oocytes and the values shown are typical for 4 experiments in late winter-early spring. For details see Methods.
	Figure 4. A comparison of the time course of insulin effects on membrane hyperpolarization (EmV), intracellular pH (pHi) and [14C]2-deoxy-D-glucose uptake by isolated denuded R. pipiens oocytes at 20–22°C. The graphs represent changes in various parameters relative to untreated oocytes. Each point presents a pooled sample of 5–10 sibling oocytes and is typical for 4 experiments in late winter-early spring Rana. For details see Table 2 and Methods.
	Figure 5. Effect of 5 μM insulin on serine protease activity in isolated, intact plasma-vitelline membranes from prophase-arrested Rana pipiens oocytes (● - ●). p-Tosyl-l-arginine methyl ester (TAME) was used as a serine protease-specific substrate and the serine protease inhibitor phenylmethyl-sulfonyl-flouride (PMSF) was added 15 min prior to insulin (▲ - ▲). The control is represented by (○ - ○). Values shown are from a typical experiment using sibling oocytes. The mean ± SD values for serine protease activity for oocytes from four R. pipiens females at 30 min was 26.4 ± 2.57 absorbancy units for 5 μM insulin, 8.23 ± 1.27 absorbancy units for 0 insulin (controls) and 0 absorbancy units for oocytes treated with both 5 μM insulin and PMSF. For details see methods.
	Figure 6. A comparison of the topology of four plasma membrane proteins associated with the initial insulin response. TMHMM projections were generated using the server at the Center for Bological Sequence Analysis, Technical University of Denmark DTU. From top to bottom the proteins are: the β-subunit of the insulin receptor (Accession #Q9PVZ4), the membrane serine protease 8 (Prostasin, Accession #Q16651), the protease-activated receptor (PAR2, Accession #Q5U791) and the amiloride-sensitive Na+ channel subunit β (Accession #P51169). The amino acid sequences are those published in the Swiss Protein Knowledgebase (http://www.uniprot.org).
	Figure 7. A comparison of the topology of four putative plasma membrane enzymes that respond to exogenous insulin. TMHMM projections were generated as described in Figure 6. From top to bottom the enzymes are: the catalytic α-subunit of Na+/K+-ATPase (Accession #Q92123), Na+/H+-exchanger (Accession #P70009), the Na+/Ca2+-exchanger (Accession #Q91849) and Na+ -glucose cotransporter ((SGLT2, Accession #P31639). The amino acid sequences are those published in the Swiss Protein Knowledgebase (http://www.uniprot.org).

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