Korean J Physiol Pharmacol 2025; 29(1): 93-108
Published online January 1, 2025 https://doi.org/10.4196/kjpp.24.265
Copyright © Korean J Physiol Pharmacol.
Misun Kwak1,#, Hana Kang1,#, Jinhyeong Kim1,#, Yejun Hong1, Byeongseok Jeong1, Jongyun Myeong2, and Insuk So1,*
1Department of Physiology and Biomedical Sciences, Seoul National University College of Medicine, Seoul 03080, Korea, 2Department of Cell Biology and Physiology, Washington University School of Medicine in St. Louis, MO 63110, United States
Correspondence to:Insuk So
E-mail: insuk@snu.ac.kr
#These authors contributed equally to this work.
Author contributions: M.K, H.K., and J.K. designed the study, performed experiments, generated figures, analyzed data, and wrote the manuscript. M.K., H.K., and B.J. generated figures and wrote the manuscript. J.K., M.K., and Y.H. performed patch clamp experiments. M.K. performed Co-IP and western experiment. J.M. performed FRET experiment. I.S. provided the overall experimental advice and coordinated the study. All authors reviewed the manuscript.
PKD1 regulates a number of cellular processes through the formation of complexes with the PKD2 ion channel or transient receptor potential classical (TRPC) 4 in the endothelial cells. Although Ca2+ modulation by polycystins has been reported between PKD1 and TRPC4 channel or TRPC1 and PKD2, the function with TRPC subfamily regulated by PKD2 has remained elusive. We confirmed TRPC4 or TRPC5 channel activation via PKD1 by modulating G-protein signaling without change in TRPC4/C5 translocation. The activation of TRPC4/C5 channels by intracellular 0.2 mM GTPγS was not significantly different regardless of the presence or absence of PKD1. Furthermore, the C-terminal fragment (CTF) of PKD1 did not affect TRPC4/C5 activity, likely due to the loss of the N-terminus that contains the G-protein coupled receptor proteolytic site (GPS). We also investigated whether TRPC1/C4/C5 can form a heterodimeric channel with PKD2, despite PKD2 being primarily retained in the endoplasmic reticulum (ER). Our findings show that PKD2 is targeted to the plasma membrane, particularly by TRPC5, but not by TRPC1. However, PKD2 did not coimmunoprecipitate with TRPC5 as well as with TRPC1. PKD2 decreased both basal and La3+-induced TRPC5 currents but increased M3R-mediated TRPC5 currents. Interestingly, PKD2 increased STAT3 phosphorylation with TRPC5 and decreased STAT1 phosphorylation with TRPC1. To be specific, PKD2 and TRPC1 compete to bind with TRPC5 to modulate intracellular Ca2+ signaling and reach the plasma membrane. This interaction suggests a new therapeutic target in TRPC5 channels for improving vascular endothelial function in polycystic kidney disease.
Keywords: Polycystic kidney disease 1 protein, Polycystic kidney disease 2 protein, Polycystic kidney diseases, Signal transducer and activator of transcription, Transient receptor potential canonical channel 5
Autosomal dominant polycystic kidney disease (ADPKD) is one of the most common inherited diseases. ADPKD is characterized by the progressive expansion, in both kidneys, of multiple fluid-filled cysts, which gradually replace normal renal tissue and ultimately result in end-stage renal failure [1]. In ADPKD-causative genes, the polycystic kidney disease 1 (PKD1) and PKD2 genes are involved in the activation of cation-permeable currents by regulation of G-protein signaling, as well as the control of epithelial cell population growth, migration, differentiation and apoptosis [1,2]. PKD1 (also known as polycystin-1 [PC-1]) is a glycoprotein that consists of approximately 4,302 amino acids, PKD1 functions as an atypical G protein coupled receptor (GPCR), binds heterotrimeric Gαi/o proteins and regulates calcium flux through PKD2 (also known as PC-2 or transient receptor potential polycystin 2 [TRPP2]) by releasing Gβγ subunits [1]. Thus, PKD1 and PKD2 are related to disturbed intracellular Ca2+ homeostasis and cyclic adenosine monophosphate (cAMP) accumulation, leading to abnormal cell proliferation and the growth of multiple cysts [3,4].
Transient receptor potential (TRP) channels make up a family of seven cationic channels, which are divided into 7 subfamilies based on amino acid similarity. TRP channels can form functional homo- or hetero-tetrameric channels with intra-subgroups or even with inter-subfamilies [5]. The classical TRP (TRPC) is a receptor-operated channel (
In the absence of PKD1, PKD2 primarily localizes to the endoplasmic reticulum (ER) membrane, where it mediates calcium (Ca2+) leak, with its function modulated by other ER membrane proteins. Endogenously, PKD2 is found on the plasma membrane and the membrane of primary cilia, while heterologously expressed PKD2 predominantly targets the ER membrane [10,11]. TRPC1 also functions as a homotetramer calcium release channel in the ER, while at the plasma membrane, it forms agonist-activated heterotetramers with TRPC4 or TRPC5 [12]. Originally, PKD1 and PKD2 were proposed to function as sensors of fluid flow, triggering calcium flux through PKD2 due to their localization on the plasma membrane of primary cilia [13,14]. A key limitation of the ciliary hypothesis is that it overlooks the role of polycystin-dependent calcium signaling originating from the ER or the plasma membrane. Furthermore, recent evidence suggests that cilia are largely impermeable to calcium, which challenges the validity of the ciliary hypothesis [15].
Although the modulation of Ca2+ by polycystins and TRPC, particularly between PKD1 and the TRPC4 channel, has been documented [9], the interaction between the TRPC subfamily and PKD2 has remained unclear. TRPC1 protein has been shown to interact with proteins beyond the classical TRP channel monomers, particularly with PKD2 [16-18], forming heteromeric channels, despite PKD and TRPC belonging to different groups based on amino acid homology and CryoEM structures. Both proteins are suggested to function as Ca2+ release channels in the ER. Moreover, TRPC1 and PKD2 require their respective subfamily members to transport from the ER to the plasma membrane. However, with the structural elucidation of each ion channel [7,19], the existence of these heteromers has become questionable. In this study, we explored how TRPC interacts with and modulates the PKD2 channel. First, we aimed to confirm whether TRPC1 physically interacts with PKD2. Following this, we expanded our experiments to investigate the effects of PKD2 on TRPC4 and TRPC5. Our results demonstrate that TRPC5 modulates PKD2 activity, while TRPC1 does not. Additionally, PKD2 regulates TRPC5 by influencing channel activity at the plasma membrane and ER calcium levels, but it does not affect TRPC1 in the same manner.
Human embryonic kidney (HEK)-293 cells (American Type Culture Collection) were maintained in Dulbecco’s modified Eagle’s medium (HyClone) supplemented with 10% fetal bovine serum (FBS), 100 U/ml penicillin, and 100 μg/ml streptomycin according to the supplier’s recommendations. Prior to transient transfection, cells were seeded in 6- or 12-well plates. The following day, 0.5–2 μg/well TRPC and PKD1 (PC-1, polycystin-1) or PKD2 (PC-2, polycystin-2) cDNA was transfected into cells using the transfection reagent FuGENE 6 (Roche Molecular Biochemicals) for electrophysiological experiments, according to the manufacturer’s protocol. For molecular biology experiments, Lipofectamine 2000 (Invitrogen) was used as the transfection reagent. All experiments were performed 20–30 h after transfection. Englerin A was purchased from Sigma Aldrich.
Human PKD1(FL(full-length)) in pGFP-N1 and human PKD1(FL)-Flag in pCI-neo plasmids were kindly provided by Eric Honoré and Gregory Germino, respectively. HA-human PKD1(CTF)-Flag in pCI and EGFP-human PKD1(FL) in pCI were kindly provided by Feng Qian (Johns Hopkins University). Human PKD1(FL) was subcloned into the pECFP-N1 and pEYFP-N1 vectors. Mouse PKD2 in pGFP-N1 were kindly provided by Yao Xiaoqiang (Hong Kong University). Human PKD2-myc and Pet-15b mouse PKD2 were kindly provided by Yiqiang Cai (Yale University). Human PKD2 and mPKD2 were subcloned into the pECFP-N1 and pEYFP-N1 vectors. Mouse PKD2 was subcloned into the pEGFP-N1 vector. PKD2 R740X, mutagenesis was conducted using QuickChange site-directed mutagenesis kit (Stratagene).
Mouse TRPC4 and TRPC5 were kindly provided by Dr. M. Schaefer and cDNA human TRPC4 and TRPC5-GFP was kindly provided by Dr. Shuji Kaneko. Human TRPC4 and TRPC5 were subcloned into the pECFP and pEYFP vectors. Mouse TRPC4 and TRPC5 were subcloned into the pECFP and pEYFP vectors. Mouse TRPC4-Flag and TRPC5-Flag were also subcloned into pcDNA3. cDNA of human TRPC1 isoform long tagged with CFP at N-terminus was kindly donated by Dr. Luis Vaca.
Human Gαi1 Q204L, Gαi2 Q205L, Gαi3 Q204L, Gαs WT, Gαs Q277L, Gαo Q205L, human Gαq Q209L, and human M3 receptor, were kindly provided by Dr. Yong-Sung Juhn. Src Y527F and GSK3β were kindly provided by Juhong Jeon.
Cells were plated in 6-well dishes. Lysates were prepared in lysis buffer (0.5% Triton X-100, 150 mmol/L NaCl, 50 mmol/L HEPES, 2 mmol/L MgCl2, 2 mmol/L EDTA, pH 7.4)
The transfected cells were trypsinized and transferred to a recording chamber, which was equipped for the application of a number of solutions. Whole-cell currents were recorded using an Axopatch 200B amplifier (Axon Instruments) and Digidata 1440 A Interface (Axon Instruments), and analyzed using a personal computer equipped with pClamp 10.2 software (Axon Instruments) and Origin software (Microcal origin v.8.0). Patch pipettes were made from borosilicate glass and had resistances of 2–4 MΩ when filled with standard intracellular solutions. For whole cell experiments, we used an external bath medium (normal Tyrode solution) of the following composition (in mmol/L): 135 NaCl, 5 KCl, 2 CaCl2, 1 MgCl2, 10 glucose, and 10 N-[2-hydroxyethyl]piperazine-N′-[2-ethanesulfonic acid] (HEPES) with the pH adjusted to 7.4 using NaOH. Cs+-rich external solution was made by replacing NaCl and KCl with equimolar CsCl. The standard pipette solution contained the following (in mmol/L): 140 CsCl, 10 HEPES, 0.2 Tris-GTP, 0.5 EGTA, and 3 Mg-ATP with the pH adjusted to 7.3 using CsOH. Voltage ramp pulses were applied at −60 mV with a holding potential from +100 to −100 mV for 500 ms. A salt-agar bridge was used to connect the ground Ag-AgCl wire to the bath solution for the experiments that used reducing agents. All current traces are recorded at −60 or +80 mV during the ramp pulses. The bar graphs summarize the inward current amplitudes at −60 mV. The current recordings were performed according to previously established protocols.
Three FRET images (cube set tings for CFP, YFP, and Raw FRET) were obtained from a pE-1 Main Unit to 3 FRET cubes (excitation, dichroic mirror, filter)
The following commercial antibodies were used: anti-PC1 (PKD1, sc-130554 or sc-10371; Santa Cruz Biotechnology); anti-GFP (A11122; Life Technologies); anti-Flag (F3165; Sigma Aldrich); anti-STAT1 (#9172; Cell Signaling); anti-p-STAT1 (#9167; Cell Signaling); STAT3 (Cell Signaling, #9132); pSTAT3(Y705) (Cell Signaling, #4133); PKD2(H-280); Anti-STAT6 (Cell Signaling, #9362); Anti-p-STAT6(Tyr641) (Cell Signaling, #9361); anti-TRPC (73-119; Neuromab); anti-β-tubulin (T-4026; Sigma Aldrich); Anti-JNK (Santa Cruz Biotechnology, sc-571); Anti-p-JNK(Thr183/Tyr185) (Cell Signaling, #9251s); Anti-c-Jun (Cell Signaling, #9165); Anti-p-c-Jun(Ser63) (Cell Signaling, #9261); Anti-p38 MAPK (Cell Signaling, #9212); Anti-p-p38 MAPK(Thr180/Tyr182) (Cell Signaling, #9216); Anti-c-Src (Santa Cruz Biotechnology, sc-8056); Anti-p-Src(Tyr416) (Cell Signaling, #2101); Anti-NFATc1 (Santa Cruz Biotechnology, sc-7294); Anti-NFATc2 (Santa Cruz Biotechnology, sc-7296); Anti-NFATc3 (Santa Cruz Biotechnology, sc-8321); Anti-NFATc4 (Santa Cruz Biotechnology, sc-13036); Anti-Akt (Cell Signaling, #9272); Anti-Akt(Ser473) (Cell Signaling, #4058); Anti-GSK3α/β (Santa Cruz Biotechnology, sc-7291); Anti-p-GSK3β(Ser9) (Cell Signaling, #9336); Anti-ERK1/2 (Cell Signaling, #9102); Anti-p-ERK(Thr202/Tyr204) (Santa Cruz Biotechnology, sc-7383); Anti-PDK1 (Cell Signaling, #3062); Anti-p-PDK1(Ser241) (Cell Signaling, #3061).
The results are presented as the means ± S.E.M. They were compared using Student’s t-tests between two groups. p < 0.05 was considered statistically significant.
PKD2 primarily resides in the ER and reaches the plasma membrane with special conditions. Specifically, it has been shown that the amount of PKD2 in the plasma membrane is dynamically regulated by interacting proteins (PKD1 [20,21], Polycystin-2 interactor, Golgi- and ER-associated protein-14 (PIGEA-14) [22]), posttranslational modifications (serine phosphorylation by casein kinase 2 (CK2: S812) [23] and glycogen synthase kinase 3 (GSK3: S76) [24]), interaction with other channel subunits in the plasma membrane (PKD1 [20,21], TRPC1 [16-18]) (Fig. 1A). We investigated whether specific factors, such as PKD1 or GSK3, promote the translocation of PKD2 to the plasma membrane. As shown in Fig. 1, both PKD1 (Fig. 1B) and GSK3β (Fig. 1C) significantly increased PKD2 surface expression. Furthermore, we generated a PKD2 mutant by deleting its ER retention signal. The C-terminal region of PKD2 contains several important functional domains, including the ER retention signal, Ca2+ binding domains, EF-hand, and a coiled-coil domain. This region also mediates interaction with the C-terminus of PKD1. The hPKD2 R742X mutation, which affects the C-terminal region, is known to cause ADPKD [14]. The resulting PKD2 R740X mutant efficiently localized to the plasma membrane (Fig. 1D). Our result confirmed more surface expression R740X mutant without ER retention deletion. From these results, we reconfirmed certain factors regulating the surface expression of PKD2.
PKD1 is a large plasma membrane glycoprotein that undergoes several proteolytic cleavages, including autocatalytic cleavage at the G-protein coupled receptor proteolytic site (GPS). The cleaved PKD1 consists of an N-terminal fragment (NTF) associated with a C-terminal fragment (CTF). As previously reported, PKD1 cleaved to NTF and CTF in our hands (Fig. 2. See also [9,25]). PKD2, together with PKD1, forms a PKD1/PKD2 complex. This complex moves to the plasma membrane, where it creates a functional channel that responds to mechanical stimuli. In this study, we investigated whether PKD1 directly interacts with PKD2 (Fig. 2). Using an antibody against the PC1 N-terminus (7E12) or an antibody against the PC1 C-terminus (A-20), PKD1 was immunoprecipitated. With anti-PKD2 antibody (H-280), Western blot was performed for PKD2. When PKD2 was immunoprecipitated, anti-PKD1 antibody, 7E12 or A-20, was used for Western blot of PKD1. CTF of PKD1 and FL PKD co-immunoprecipitated with PKD2 (Fig. 2). From these results, we reconfirmed FL and CTF of PKD1 interact with PKD2 to make PKD1/PKD2 complex. The regulators for PKD1 cleavage are Ca2+, FBS, mechanical stimulus, γ-secretase as well as PKD2 [2,4,26]. When ER Ca2+ pump was blocked with thapsigargin (TG) to induce ER stress, there was no cleavage of PKD1 into NTF and CTF (Supplementary Fig. 1). Such cleavage disruption might lead to the mislocation of PKD1 and PKD2. If PKD2 fails to reach the plasma membrane, its accumulation in the ER increases, consequently regulating Ca2+ release from the ER. Cyclopiazonic acid (CPA) also inhibited the cleavage of PKD1 into NTF and CTF (Supplementary Fig. 1). In addition, external Ca2+ itself increased the surface expression of PKD2 only in the presence of FBS (Supplementary Fig. 2). These results suggest that ER calcium and extracellular calcium play roles of PKD2 trafficking.
In our previous study, we showed that PKD1 activated TRPC4 by Gα protein signaling pathway [9]. Since PKD1 is an adhesion type GPCR, we tested whether various Gα proteins affect the expression of PKD2 at the plasma membrane. Constitutively active Gαs proteins increased the surface expression of PKD2 (Supplementary Fig. 3). As PKD1-Gα protein pathway activated TRPC4, PKD1-Gαs protein pathway increased the surface expression of PKD2. On the other hand, constitutively active Src (Src Y527F) did not increase the surface expression of PKD2 (Supplementary Fig. 3).
TRPC1 is well known for its expression on the ER membrane and its direct interaction with PKD2 [16-18]. TRPC1 and PKD2 assembles together with ratio of 2:2 [17,18]. Numerous studies have suggested that TRPC1 directly binds to PKD2 and enhances its expression at the plasma membrane [16-18]. We investigated the effects of TRPC1, TRPC4, and TRPC5 on PKD2 expression. Contrary to expectations, neither TRPC1 nor TRPC4 had any impact on the surface expression of PKD2. Interestingly, TRPC5 significantly increased the surface expression of PKD2 at the plasma membrane (Fig. 3). TRPC5, but not TRPC1 or TRPC4, promoted PKD2 localization predominantly to the plasma membrane. However, when TRPC1 was coexpressed with TRPC5 to form a TRPC1/5 heteromer, TRPC1 reversed the increase in PKD2 surface expression induced by TRPC5 (Supplementary Fig. 4). These results suggest that the increased surface expression of PKD2 by TRPC5 might be due to 1) direct interaction of TRPC5 with PKD2, 2) some factor related to TRPC5 with TRPC1 reversing the effects or 3) competition of TRPC1 and TRPC5 against PKD2.
Thus, we investigated how TRPC5 increases the surface expression of PKD2 at the plasma membrane. To investigate the direct interaction of TRPC with PKD2, we performed Co-IP and FRET experiments. First, we performed Co-IP experiments of PKD2 with TRPC channels. Different from the previous reports [16-18], TRPC1 did not directly bind and co-immunoprecipitate with PKD2 (Fig. 4A). TRPC5 and TRPC4 did not Co-IP with PKD2, either. Thus, TRPC5 did not directly bind and Co-IP with PKD2 (Fig. 4). Next, we performed FRET experiments. The FRET efficiency was also much lower compared with that between PKD2 itself or TRPC5 itself (Fig. 4). These results suggest that the increased surface expression of PKD2 by TRPC5 is not due to a direct interaction between TRPC5 and PKD2. TRPC5 forms a TRPC1/5 heteromer with TRPC1 and regulates Ca2+ permeability, even though both TRPC1 and PKD2 homotetramers are typically localized in the ER (see also [5,8,10,12]). Based on the results regarding the regulation of PKD2 surface expression—such as ER Ca2+, extracellular Ca2+, cAMP, and TRPC1—it is possible that Ca2+ influx through TRPC5 channels contributes to the increased surface expression of PKD2.
Although Ca2+ modulation by polycystins has been reported between PKD1 and TRPC4 channel or TRPC1 and PKD2, whether the function of TRPC subfamily is regulated by PKD2 has remained elusive. Here, we recorded the activity of TRPC4/C5 heterologously co-expressed with PKD1 or PKD2 in HEK293 cells. First, PKD1 activated TRPC4 (40 ± 14 pA/pF) channel by modulating G-protein signaling without change in TRPC4 translocation as previously reported [9]. PKD1 acts as a GPCR and activates Gαi increased both basal Gαi proteins induced TRPC4 currents [9]. PKD1 also activated TRPC5 channel from 54 ± 8 pA/pF to 114 ± 16 (n = 7) by modulating G-protein signaling without change in TRPC4/C5 translocation (Fig. 5A, B). Intracellular 0.2 mM GTPγS-induced TRPCC5 activation, however, was not significantly different in the presence or absence of PKD1 (Fig. 5C, D). Whereas FL PKD1 increased TRPC5 current, CTF of PKD1 did not affect TRPC5 activity (80 ± 12 pA/pF, n = 7) due to loss of N-terminus containing GPS (Fig. 5C, D). FL PKD1 also increased the La3+-induced TRPC5 currents from 27 ± 8 to 58 ± 12 pA/pF (n = 7), whereas CTF did not (Fig. 5E, F). PKD1 increased both the inward and outward TRPC5 currents. These results suggested that PKD1 increased TRPC5 current
Second, we investigated the effects of PKD2 on TRPC4 and TRPC5 channels. PKD2 affected muscarinic stimulation of TRPC channels by carbachol (Fig. 6). When M3R was co-expressed with PKD2, carbachol increased currents in both TRPC5 (from 33 ± 9 to 112 ± 33 pA/pF, n = 7) and TRPC4 channels (from 34 ± 4 to 77 ± 14 pA/pF, n = 7) (Fig. 6). These results suggest that muscarinic stimulation activates IP3R and the activated IP3R induces more calcium release
Finally we investigated whether other stimulators like external cesium or La3+ have any effect on TRPC5 when PKD2 was co-expressed with TRPC5. TRPC5 has unique electrophysiological properties. As shown above, TRPC5 has a larger basal current than TRPC4 and responds well to external La3+ [5-9]. Without intracellular GTPγS, PKD2 decreased the basal Cs current of TRPC5 channels from 115.8 ± 29.8 (n = 7) to 13 ± 5 pA/pF (n = 7) (Fig. 7). However, with GTPγS, the basal Cs currents was not changed by PKD2 coexpression (99.3 ± 23.5 [n = 8]
To see the combined effects of TRPC and PKD2 on cell signaling, we investigated which downstream effects occur when PKD2 and TRPC were co-expressed. In ADPKD pathogenesis, many signaling pathways are suggested, that is, 1) protein kinase C (PKC)- c-Jun N-terminal kinases (JNK)-p38-activating protein-1 (AP-1), 2) mechanistic target of rapamycin (mTOR)-AMP-activated protein kinase (AMPK)-extracellular signal–regulated kinase (ERK), 3) 3-phosphoinositide-dependent protein kinase-1 (PDK1)-Akt-GSK3, and 4) Src-STAT-p21 (Supplementary Fig. 5, see also [1,2,14,26,27]). Western blot analysis was performed to detect the phosphorylation of the proteins involved in the signaling pathways. There were no change of the phosphorylation of JNK, Jun, and p38 mitogen-activated protein kinase (MAPK) (Supplementary Fig. 6A). The phosphorylation of mTOR (Supplementary Fig. 6B) and ERK (Supplementary Fig. 6C) was not changed, either. There were no change of the phosphorylation of PDK1, Akt and GSK3, either (Supplementary Fig. 7).
The JAK-STAT signaling pathway is also upregulated in ADPKD, with cyst-lining cells showing increased levels of nuclear STAT-1, STAT-3, and STAT-6. This leads to enhanced STAT-dependent gene expression [27]. PKD1 has been implicated in a variety of intracellular signaling events, including JAK-STAT signaling. Overexpression of FL PKD1 can activate STAT1, STAT3 and STAT6 [28], which mediate signaling involved in proliferation, differentiation and death. We suggested that the C-terminal tail (CTT) of PKD1 activates TRPC4β
Our findings indicate that 1) TRPC5 regulates the surface expression of PKD2 as well-known factors like PKD1, GSK3, Ca2+, ER retention signals of PKD2, 2) PKD2 regulates TRPC5 and TRPC4 channels by interacting with PKD1-Gα protein or ER calcium content, 3) PKD2 activates STAT3 signaling pathway with TRPC5 as PKD1-TRPC1/4-STAT1 signaling pathways, and 4) PKD1/2 and TRPC1/C4/C5 play the important roles in the regulation of calcium homeostasis independently, but interact each other
PKD and TRPC channel play each role for regulation of calcium homeostasis. TRPC1 acts as a negative regulator for TRPC4 and TRPC5 after forming a heteromer channels. TRPC1 reduced calcium permeability and cellular excitability by modifying IV curve [29-33] (Fig. 9 blue dotted line). On the other hand, PKD2 needs PKD1 for trafficking and its function for ion channels. PKD1 acts a carrier for PKD2 from ER to the primary cilia as TRPC5 for TRPC1 from the ER to the plasma membrane. PKD1/PKD2 forms a complex and together play a very important role for anticystogenic activity at renal tubular epithelial cells. PKD1 also changes calcium permeability of PKD2 when they make PKD1/PKD2 complex [19]. Contrary to their independent roles in calcium regulation, TRPC and PKD have similar properties. First, both TRPC1 and PKD2 express at the ER and play a Ca2+ release channel at the ER maybe as a homotetramer (Fig. 9, see also [12,34]). Second, there is an intimate connection with ER calcium. TRPC channels are initially suggested as a store operated channels (SOCs). Regardless of TRPC as a SOC or not, TRPC seems very important for filling ER Ca2+, especially when GPCR induces Ca2+ release from the ER (Fig. 9 blue dotted line). PKD1 also acts as a GPCR and contributes to fill ER Ca2+ by activating TRPC4 or TRPC5. The depletion of ER calcium prevents the cleavage of PKD1 (Supplementary Fig. 1) and increase Ca2+ influx through TRPC at the plasma membrane. Thus, there is intimate interaction between ER calcium and PKD1 cleavage. In addition, the cleavage of PKD1 is needed for the trafficking of PKD2 to the primary cilia, thus the retention of PKD2 at the ER due to non-cleavage of PKD1 might exacerbate the ER Ca2+ depletion. When ER Ca2+ was modified with TG, the cleavage of PKD1 might not occur and bring PKD2 to the primary cilia (Supplementary Fig. 1). ER calcium content appears to modulate the response of PKD2 on the co-expression with TRPC channels. Thus, PKD2 increased carbachol-induced TRPC5 currents on the co-expression of PKD2 with TRPC channels (Figs. 6 and 9 (green line)). The sustained activation of the Gαq/11-PLCβ pathway results in ER stress and unfolded protein response (UPR) as demonstrated by the effect of the Gαq-blocker FR900359 on the transcriptome from patients [35]. Therefore intimate relationship between ER calcium and TRPC or PKD proteins are essential for cell calcium homeostasis as well as protein translation.
Early studies have suggested that PKD2 plays an important role in intracellular Ca2+ homeostasis [10]. The loss of PC2 in cells results in defective ER Ca2+ release, which is believed to contribute to cAMP overproduction and cystogenesis, the foundation for treatment of ADPKD by tolvaptan [10,36]. Recently, Padhy
PKD2 increased M3R-Gαq/11-PLCβ-induced TRPC5 currents because there is a calcium induced calcium release through PKD2 and IP3R. PKD1 inhibits IP3R whereas PKD2 activates IP3R. When PKD1 and PKD2 were co-expressed, they enhanced IP3R activity (Fig. 9, see also [40,41]). The sustained activation of the Gαq/11-PLCβ pathway results in ER calcium stress and UPR [35]. IP3 from M3R-Gαq/11-PLCβ pathway usually binds with IP3R and releases Ca2+ from the ER. IP3 also activates PKD2 and release Ca2+ from the ER
For a role for polycystin dependent calcium signaling originating in the ER or at the plasma membrane, we suggested that the PKD1/TRPC4 signaling pathway controls the migration of endothelial cell monolayers, leading to endothelial permeability [9]. To determine whether PKD1 or TRPC4β affects vascular permeability, we investigated the distribution of an endothelial-specific cadherin, vascular endothelial (VE)-cadherin, and leakage of Evans blue dye in endothelial cells. We suggested that PKD1-mediated TRPC4β activation plays an important role in the stability of endothelial junctions and permeability [9]. TRPC4 was initially suggested to be involved in the regulation of vasorelaxation by acetylcholine in the endothelium-dependent manner [48] and lung microvascular permeability [49]. Following the publication of papers indicating that TRPC4 is involved in endothelial cell function, reports have subsequently emerged that TRPC5 and TRPC1/C5 heteromers are involved in NO-dependent endothelial cell function [50,51]. Recently, reports have been published that PKD2 and the PKD1/2 complex are also involved in mechanosensation by endothelial cells [52-55]. These results suggest that PKD1/2 and TRPC1/4/5 play important roles in the regulation of vascular tone and endothelial permeability by controlling ER calcium and Ca2+ influx across the plasma membrane as well as the primary cilia.
One function of the PKD1/PKD2 complex is to regulate the JAK/STAT pathway, providing insight into how mutations in either gene can lead to dysregulated cell growth. The unique channel properties that arise from the coassembly of polycystin-1 and polycystin-2 at the plasma membrane are believed to be responsible for the activation of JAK2 [28,56,57]. Initially, given the channel’s high permeability to calcium, an intriguing possibility was that calcium influx through the channel could trigger a signaling cascade, leading to the phosphorylation and activation of JAK2. PKD2 is essential for the proper function of PKD1, as neither protein alone can activate the JAK-STAT pathway. The involvement of PKD2 in PKD1-mediated JAK2 activation further supports that both proteins are key components of a shared signaling pathway, and disruptions in this pathway result in the indistinguishable phenotypes observed in PKD1 and PKD2 mutations [28]. IP3R needs TRPC channels for STAT activation, especially for persistent STAT activation [58]. In hypoxic pulmonary vasoconstriction, JAK/STAT pathway needs TRPC1 and TRPC6 as SOC [59]. In our hands, TRPC4 channels are required for PKD1-STAT activation while TRPC5 and TRPC1 for PKD2-STAT signaling pathways.
PKD1/PKD2 are sensitive to ER calcium and PKD2 contributes to TRPC5 response
In conclusion, we showed 1) a special role of TRPC5 for the expression of PKD2, 2) two PKD2-TRPC5-STAT3 and PKD2-TRPC1/C4 heteromer-STAT1 signaling pathways, and 3) PKD1-G protein TRPC4/C5 activation, PKD2-Ca2+-muscarinic activation of TRPC4/5 and PKD2-PKD1-G protein-inhibition of basal or La3+ activation of TRPC4/C5. Our findings thus provided a new potential therapeutic approach targeting TRPC1/C4/C5 channel in cerebral arterial aneurysm from polycystic kidney disease. Interestingly, while the PKD1/PKD2-STAT1 pathway exhibits an anticystogenic effect on tubular epithelial cells, the analogous PKD1/TRPC4/STAT1 pathway promotes proliferation and strengthens the tight junctions of endothelial cells.
This study was supported by National Research Foundation of Korea grant 2020R1A2C1012670 and 2021R1A4A2001857 (I.S.), Education and Research Encouragement Fund of Seoul National University Hospital (I.S.), Mid-Career Bridging Program through Seoul National University (800-20240545) (I.S.), Seoul National University Hospital Research Fund (03-2024-0440) (I.S.), BK21 FOUR education program scholarship (H.K., J.K., B.J.).
Human PKD1(FL) in pGFP-N1 and human PKD1(FL)-Flag in pCI-neo plasmids were kindly provided by Eric Honoré and Gregory Germino, respectively. HA-human PKD1(CTF)-Flag in pCI and EGFP-human PKD1(FL) in pCI were kindly provided by Feng Qian (Johns Hopkins University). Mouse PKD2 in pGFP-N1 were kindly provided by Yao Xiaoqiang (Hong Kong University). Human PKD2-myc AND Pet-15b mouse PKD2 were kindly provided by Yiqiang Cai (Yale University). Mouse TRPC4 and TRPC5 were kindly provided by Dr. M. Schaefer and cDNA human TRPC4 and TRPC5-GFP was kindly provided by Dr. Shuji Kaneko. cDNA of human TRPC1 isoform long tagged with CFP at N-terminus was kindly donated by Dr. Luis Vaca. Human Gαi1 Q204L, Gαi2 Q205L, Gαi3 Q204L, Gαs WT, Gαs Q277L, Gαo Q205L, human Gαq Q209L, and human M3 receptor, were kindly provided by Dr. Yong-Sung Juhnn. Src Y527F and GSK3β were kindly provided by Juhong Jeon. Christine Haewon Park went through english proofreading.
The authors declare no conflicts of interest.
Supplementary data including eight figures can be found with this article online at https://doi.org/10.4196/kjpp.24.265
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