Serine Protease Activity in M-1 Cortical Collecting Duct Cells

doi:10.1161/01.HYP.0000013055.48885.8D

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Hypertension. 2002;39:860-864
doi: 10.1161/01.HYP.0000013055.48885.8D

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(Hypertension. 2002;39:860.)
© 2002 American Heart Association, Inc.

Scientific Contributions

Serine Protease Activity in M-1 Cortical Collecting Duct Cells

Lian Liu; Kathleen S. Hering-Smith; Faith R. Schiro; L. Lee Hamm

From the Department of Medicine and Physiology, Tulane University Health Science Center and VA Medical Center, New Orleans, La.

Correspondence to L. Lee Hamm, MD, Tulane University Health Science Center, Nephrology, SL 45, 1430 Tulane Ave, New Orleans, LA 70112. E-mail lhamm{at}tulane.edu

An apical serine protease, channel-activating protease 1 (CAP1),augments sodium transport in A6 cells. Prostasin, a novel serineprotease originally purified from seminal fluid, has been proposedto be the mammalian ortholog of CAP1. We have recently foundfunctional evidence for a similar protease activity in the M-1cortical collecting duct cell line. The purposes of the presentstudies were to determine whether prostasin (or CAP1) is presentin collecting duct cells by use of mouse M-1 cells, to sequencemouse prostasin, and to further characterize the identity ofthe serine protease activity and additional functional featuresin M-1 cells. Using mouse expressed sequence tag sequences thatare highly homologous to the published human prostasin sequenceas templates, reverse transcription–polymerase chain reactionand RACE (rapid amplification of cDNA ends) were used to sequencemouse prostasin mRNA, which shows 99% identical to publishedmouse CAP1 sequence. A single 1800-bp transcript was found byNorthern analysis, and this was not altered by aldosterone.Equivalent short-circuit current (I_eq), which represents sodiumtransport in these cells, dropped to 59±3% of controlvalue within 1 hour of incubation with aprotinin, a serine proteaseinhibitor. Trypsin increased the I_eq in aprotinin-treated cellsto the value of the control group within 5 minutes. Applicationof aprotinin not only inhibited amiloride sensitive I_eq butalso reduced transepithelial resistance (R_te) to 43±2%,an effect not expected with simple inhibition of sodium channels.Trypsin partially reversed the effect of aprotinin on R_te. Anotherserine protease inhibitor, soybean trypsin inhibitor (STI),decreased I_eq in M-1 cells. STI inhibited I_eq gradually over6 hours, and the inhibition of I_eq by 2 inhibitors was additive.STI decreased transepithelial resistance much less than didaprotinin. Neither aldosterone nor dexamethasone significantlyaugmented protease activity or prostasin mRNA levels, and infact, dexamethasone decreased prostasin mRNA expression. Inconclusion, although prostasin is present in M-1 cells and probablyaugments sodium transport in these cells, serine proteases probablyhave other effects (eg, resistance) in the collecting duct inaddition to effects on sodium channels. Steroids do not alterthese effects in M-1 cells. Additional proteases are likelyalso present in mouse collecting duct cells.

Key Words: epithelium • sodium channels • cortical collecting duct • serine protease • M-1 cells

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