TRPV1 and occludin are expressed in SMG-C6 cells

Expression of TRPV1 mRNA was detected at the expected size of 258 bp in SMG-C6 cells (Fig. 1A), and further confirmed by sequencing. Rat dorsal root ganglion (DRG), reported to express TRPV1, was used as positive control. TRPV1 protein was observed with a molecular mass of ∼95 kDa (Fig. 1A). Immunofluorescence imaging showed that TRPV1 proteins were widely diffused in the cytoplasm with a stronger intensity at the cell boundary (Fig. 1B). To further confirm the intracellular location of TRPV1, sequential images of the monolayer of cells at six different x–y planes from the apical surface to the basal region along the z-axis were taken using confocal microscopy. Consistently, TRPV1 protein was seen mainly in the cytoplasm and lateral membranes of SMG-C6 cells (Fig. 1C). We also co-stained cells with two lateral membrane markers, E-cadherin and β-catenin, which are components of adherens junctions. Images from both horizontal and vertical planes showed that TRPV1 was colocalized with E-cadherin and β-catenin (Fig. 1D). Moreover, 10 µmol/l capsaicin treatment for 10 min did not induce any change in the distribution of TRPV1, E-cadherin or β-catenin (Fig. 1D). In accordance with the co-immunofluorescence results, immunoprecipitation assays identified that TRPV1 was co-precipitated with lateral membrane markers E-cadherin and β-catenin, but not with the apical tight junction component occludin (Fig. 1E). Additionally, the interaction between TRPV1 with either E-cadherin or β-catenin was not influenced by capsaicin (Fig. 1E), which indicated that neither TRPV1 nor adherens junction distribution was altered after capsaicin treatment.

• Download figure
• Open in new tab
• Download powerpoint

Fig. 1.

TRPV1 and occludin are expressed in rat SMG-C6 cells. (A) Upper panels: RT-PCR analysis of TRPV1 mRNA in SMG-C6 cells. Rat dorsal root ganglion (DRG) was used as the positive control, and actin as the loading control. Lower panels: western blot analysis of TRPV1 expression in rat DRG and SMG-C6 cells. Equal loading of each lane was verified by actin. (B) Immunofluorescence staining of TRPV1 in SMG-C6 cells. TRPV1 protein was expressed in the cytoplasm of SMG-C6 cells with a stronger staining in the cell borders (white arrows). (C) Sequential images of SMG-C6 cells at six x–y planes along the z-axis showing that the TRPV1 was mainly in the lateral membranes (white arrows). Each image is a representative of three separate experiments in duplicate. Scale bars: 25 µm. (D) Co-immunofluorescence staining of TRPV1 with E-cadherin (upper and middle panels) or β-catenin (lower panel) with or without 10 µmol/l capsaicin treatment for 10 min. White lines in the x–y panels indicate the position of the z-line scans; white arrowheads point to the co-localization of TRPV1 and E-cadherin in the x–z images. Each image is a representative of three separate experiments in duplicate. Scale bars for the x–y and x–z images: 25 µm and 10 µm, respectively. (E) Co-immunoprecipitation of TRPV1 with E-cadherin, β-catenin or occludin (Ocln). TRPV1 co-precipitated with either E-cadherin or β-catenin, and their interactions did not change after capsaicin treatment. In contrast, TRPV1 did not co-precipitate with occludin. (F) Upper panels: RT-PCR analysis of occludin mRNA in SMG-C6 cells. Rat submandibular gland (SMG) tissue was used as a positive control. Lower panels: western blot analysis of occludin expression in rat SMG tissue and SMG-C6 cells. (G) Immunofluorescence staining of occludin. X–y images show that occludin protein is located in the cell membrane of SMG-C6 cells. Scale bars: 10 µm and 40 µm. X–z images show that occludin is located in the most apical portion of cell membrane (white arrowheads), while TRPV1 is expressed in the cytoplasm as well as the lateral membrane beneath occludin. Scale bars: 10 µm. Each image is a representative of three separate experiments in duplicate.

Previous data showed that a series of tight junction proteins including zonula occludens-1 (ZO-1), occludin, claudin-1, −3, −4 and −5 exist in rat SMG tissue (Peppi and Ghabriel, 2004). Thus, we examined these components in SMG-C6 cells and found that ZO-1, occludin, claudin-1, −3 and −4 mRNA were expressed, whereas claudin-2 and −5 mRNA were not detected (supplementary material Fig. S1A). Occludin mRNA at the expected size of 482 bp, and the protein (65 kDa) were detected in SMG-C6 cells (Fig. 1F). Occludin protein was continuously expressed in the cell membrane encircling the cells and delineating the cellular borders. Vertical x–z plane images further revealed that occludin was located in the most apical portion of cell membrane, whereas TRPV1 was expressed in the cytoplasm around the nucleus as well as the lateral membrane beneath occludin (Fig. 1G).

Activation of TRPV1 induces redistribution of occludin

Previous studies showed that proper distribution of occludin in the cell membrane is required for its normal performance, and occludin internalization is closely associated with barrier disruption (Musch et al., 2006; Marchiando et al., 2010; Van Itallie et al., 2010). After stimulation for 5 min with 10 µmol/l capsaicin, occludin staining appeared to be reduced and more fragmented in the cell–cell contacts, while more positive staining increased in cytoplasm, which indicated that occludin was redistributed from the membrane into the cytoplasm. The redistributed occludin was partly returned to the membrane after capsaicin treatment for 60 min (Fig. 2A, upper panels). By contrast, the distribution of claudin-3, another transmembrane tight junction component expressed in SMG-C6 cells, was not affected by capsaicin (Fig. 2A, lower panels). Moreover, we extracted the cytoplasm and membrane protein fractions as previously described (Kawedia et al., 2008). Capsaicin induced a significant increase in occludin protein in the cytoplasm fraction within 60 min, together with a decrease in the membrane fraction. However, the claudin-3 content of both the cytoplasm or membrane fractions did not show any changes (Fig. 2B). These results were consistent with the immunofluorescence images, which demonstrated that capsaicin selectively induced redistribution of occludin, but not claudin-3.

• Download figure
• Open in new tab
• Download powerpoint

Fig. 2.

Capsaicin induces redistribution of occludin. (A) Immunofluorescence imaging of occludin (Ocln) and claudin-3 (Cln-3) distribution induced by capsaicin. A reduction and discontinuity of occludin was observed in the cell membrane, along with more intracellular staining after 10 µmol/l capsaicin treatment for 5, 10 and 30 min, but by 60 min the membrane localization of occludin was partly recovered. However, the distribution of claudin-3 was not influenced by capsaicin treatment. Images of both occludin and claudin-3 are shown at two magnifications (scale bars: 40 µm and 25 µm). Each image is representative of three separate experiments in duplicate. (B) Capsaicin-induced expression of occludin and claudin-3 in the cytoplasmic and membrane fractions. Left: capsaicin (10 µmol/l) significantly increased occludin protein expression in the cytoplasmic fraction within 60 min, but reduced its expression in the membrane fraction. In contrast, the expression of claudin-3 in these two fractions was unaffected by capsaicin. Right: quantitative analysis of occludin and claudin-3 in cytoplasmic and membrane fractions. *P<0.05 and **P<0.01 compared with unstimulated cells.

The double immunofluorescence staining of occludin and claudin-3 from both horizontal (x–y) and vertical (x–z) planes revealed that occludin and claudin-3 were co-localized in SMG-C6 cells (Fig. 3A, upper panel). After exposure to 10 µmol/l capsaicin for 10 min, occludin was disrupted and redistributed whereas claudin-3 was unaffected. In x–z images occludin appeared to become more dispersed and was no longer co-localized with claudin-3 (Fig. 3A, middle panel). The distribution of claudin-4, which forms a chloride-selective channel in other types of epithelia (Hou et al., 2010), was also observed by double-staining with occludin. Similar to claudin-3, there was no change in claudin-4 distribution after capsaicin treatment (10 µmol/l for 10 min; Fig. 3A, lower panel), suggesting that both claudin-3 and claudin-4 might serve as invariant components in the tight junction complex, whereas occludin could be redistributed by capsaicin.

• Download figure
• Open in new tab
• Download powerpoint

Fig. 3.

Capsaicin induces occludin redistribution via activation of TRPV1. (A) Upper and middle panels: co-immunofluorescence imaging of occludin (Ocln) and claudin-3 (Cln-3). Lower panel: co-immunofluorescence imaging of occludin and claudin-4 (Cln-4). Occludin was co-localized with either claudin-3 or claudin-4 in unstimulated cells. Capsaicin (10 µmol/l for 10 min) disrupted the occludin expression in the cell membrane (white arrows), whereas neither claudin-3 nor claudin-4 distribution was altered. X–z images show that occludin appeared more dispersed and was not co-localized with claudin-3 (white arrowheads). Each image is a representative of three separate experiments in duplicate. Scale bars for x–y and x–z images: 25 µm and 10 µm, respectively. (B) Co-immunofluorescence imaging of occludin (Ocln) and E-cadherin after capsaicin treatment with or without capsazepine (CPZ) pretreatment. Both occludin and E-cadherin localized at the cell–cell contacts in x–y images, and E-cadherin was positioned below occludin in x–z images. 10 µmol/l capsaicin caused an obvious internalization of occludin, but not E-cadherin. CPZ (10 µmol/l for 30 min) abolished the capsaicin-induced occludin redistribution. Each image is representative of three separate experiments in duplicate. X–y images are shown at two magnifications (scale bars: (100 µm and 40 µm); x–z images (scale bars: 20 µm).

Previous studies reported that other cell–cell interaction components such as the adherens junction protein E-cadherin may also affect tight junction formation and regulate barrier function (Tunggal et al., 2005). We thus investigated the effect of capsaicin on the distribution of occludin and E-cadherin simultaneously. Under unstimulated conditions, both occludin and E-cadherin were localized at the cell–cell contacts; however, x–z images clearly showed that E-cadherin was positioned directly below occludin (Fig. 3B). As capsaicin (10 µmol/l for 10 min) induced a redistribution of occludin as described above, the location of E-cadherin was unaffected in either x–y or x–z images (Fig. 3B). These results indicated that capsaicin selectively induced occludin redistribution, but not E-cadherin. Furthermore, pre-incubation for 30 min with 10 µmol/l capsazepine (CPZ), a TRPV1 antagonist, abolished the capsaicin-induced redistribution of occludin, whereas CPZ alone did not alter the membrane distribution of occludin (Fig. 3B). DMSO was used as the vehicle control (data not shown). We further quantified the proportion of cells in which occludin had been redistributed in lower magnification images of at least 100 cells. Capsaicin (10 µmol/l for 10 min) induced breaks in staining greater than 4 µm in 42.3±6.81% of cells, a significant increase compared with 4.8±2.08% in unstimulated cells, 5.4±1.73% in CPZ+CAP- treated cells, and 4.7±2.31% in CPZ-treated cells. Together these data suggested that capsaicin selectively induced the redistribution of occludin, but not claudin-3 or E-cadherin, in SMG-C6 cells through activation of TRPV1.

Activation of TRPV1 decreases TER and increases paracellular transport

To further evaluate the effect of TRPV1 activation on tight junction function, TER and paracellular permeability assays were performed as described previously (Turner et al., 1997; Sáenz-Morales et al., 2009). In SMG-C6 cells, the initial TER value was 516.2±98.62 Ω ˙cm², which was consistent with previous reports in the same cell line (Kawedia et al., 2008) and represented a relatively ‘tight’ epithelium according to the description of electrical characteristics (Anderson and Van Itallie, 2009). 1 µmol/l capsaicin did not induce any change to TER values within 60 min (Fig. 4A), whereas at 5 µmol/l, only a small but significant decline in TER value appeared at 60 min (Fig. 4B). At 10 and 20 µmol/l, capsaicin evoked a rapid and prominent drop in TER values from 5 to 60 min (Fig. 4C,D). Pretreatment with 10 µmol/l CPZ for 30 min abolished the 10 µmol/l capsaicin-induced TER decrease, while DMSO alone did not affect TER values (Fig. 4E). Serving as a positive control, incubation of SMG-C6 cells in a Ca²⁺-free medium for 60 min caused a dramatic twofold decrease in TER values (Fig. 4E) due to its effects on tight junction disassembly and paracellular opening as previously reported.

• Download figure
• Open in new tab
• Download powerpoint

Fig. 4.

Activation of TRPV1 increases paracellular permeability of SMG-C6 cells. Time course of TER was measured using an EVOM. (A) 1 µmol/l capsaicin (CAP) had no effect on TER values within 60 min. (B) 5 µmol/l capsaicin caused a small but significant decrease at 60 min. (C) 10 µmol/l or (D) 20 µmol/l capsaicin evoked a rapid decrease in TER from 5 to 60 min. (E) Capsazepine (CPZ, 10 µmol/l for 30 min) suppressed capsaicin-induced TER decrease. Incubation of cells in a Ca²⁺-free medium caused a decrease in TER values from 5 to 60 min. (F) Time course of Trypan Blue transport into the lower chamber medium. The flux of Trypan Blue was transiently increased after capsaicin treatment for 5–10 min. (G) The apparent permeability coefficients (P_app) for 4 kDa FITC–dextran was also increased by capsaicin (10 µmol/l for 10 min). Values are means ± s.d. from three independent experiments performed in duplicate. *P<0.05 and **P<0.01 compared with unstimulated cells.

It is well known that TRPV1 influences diverse activities through Ca²⁺ signaling. Here, we showed that 10 µmol/l capsaicin increased the mean and median Fluo-3 fluorescence in the 30,000 harvested cells at 60 s by flow cytometry (Burchiel et al., 2000), which indicated that capsaicin evoked an initial small peak of intracellular Ca²⁺ ([Ca²⁺]_i). The [Ca²⁺]_i returned to basal level after capsaicin treatment for 300 s. Pretreatment with 10 µmol/l CPZ for 30 min abolished the capsaicin-induced increased [Ca²⁺]_i, whereas CPZ alone did not affect [Ca²⁺]_i (supplementary material Fig. S1B).

In addition to TER measurements, the paracellular permeability is also routinely evaluated by non-charged tracers, which can pass through the monolayer only by the paracellular route. We used Trypan Blue and FITC–dextran as indicators, and calculated their flow rate as described previously (Sáenz-Morales et al., 2009; Rosenthal et al., 2010). Capsaicin significantly elicited a brief and transient approximately twofold increase in Trypan Blue flux during a 5–10 min period (Fig. 4F). The apparent permeability coefficients (P_app) for 4 kDa FITC–dextran were also greatly enhanced by capsaicin (Fig. 4G). These flux studies provided more evidence that capsaicin increased paracellular permeability of SMG-C6 cells.

Depletion or re-expression of occludin alters the response of capsaicin-induced TER

To reveal the potential role of occludin in paracellular permeability of SMG-C6 cells, we designed specific shRNAs to knock down the expression of occludin and claudin-3 (Fig. 5A). Depletion of occludin significantly reduced the baseline TER value by 45.5% compared with scrambled control (P<0.01), whereas depletion of claudin-3 slightly decreased the basal TER value by 20.3% but was not statistically significant (Fig. 5B). We then evaluated the involvement of those occludin or claudin-3 knockdown cells, in the TRPV1-modulated paracellular permeability. Compared with the scrambled control cells, knockdown of occludin significantly reduced TER responses to treatment with 10 µmol/l capsaicin from 5–60 min (Fig. 5C). By contrast, in claudin-3 knockdown cells, capsaicin still caused a prompt decline in TER values (Fig. 5D).

• Download figure
• Open in new tab
• Download powerpoint

Fig. 5.

Occludin is required to mediate capsaicin-induced increased paracellular permeability. (A) Western blot of occludin (Ocln) and claudin-3 (Cln-3) in SMG-C6 cells that were transfected with occludin and claudin-3 shRNAs, respectively. Occludin shRNA induced a decrease in occludin protein levels, but no change in claudin-3 expression. Claudin-3 shRNA induced a decrease in claudin-3 protein levels, but no change in occludin expression. (B) Knockdown of occludin significantly reduced TER value compared with control, whereas knockdown of claudin-3 only slightly decreased TER value. (C) The capsaicin-induced decreases in TER were inhibited in occludin knockdown cells. (D) Claudin-3 knockdown did not affect the capsaicin-reduced TER values. (E) Western blot of occludin in the ‘rescue’ cells by transfection of occludin cDNA into the occludin knockdown cells. The expression of occludin in the rescue cells was upregulated compared with that in occludin knockdown cells. (F) TER value in the rescue cells was also restored. (G) The capsaicin-induced decline in TER was much less in occludin rescue cells. Values are means ± s.d. from three independent experiments performed in duplicate. *P<0.05 and **P<0.01 compared with unstimulated control. ^#P<0.05 compared with occludin knockdown cells.

To further confirm that the disappearance of the TER response to capsaicin was due to occludin depletion but not other influencing factors, we re-expressed occludin (‘rescue’) by transfecting occludin cDNA into occludin knockdown cells. Compared with control scrambled siRNA-treated cells, the protein expression of occludin was recovered to 68.2% and TER value was restored to 80.9% in occludin rescue cells (Fig. 5E,F). Furthermore, the capsaicin-induced TER decrease re-appeared in occludin rescue cells (Fig. 5G). Together these results suggested that occludin, rather than claudin-3, plays a crucial role in barrier function of SMG-C6 cells, and capsaicin-induced increases in paracellular permeability are predominantly mediated through occludin.

Activation of TRPV1 increases ERK1/2 phosphorylation

We next explored the possible intracellular signaling pathway involved in the capsaicin-induced alteration of TER and occludin distribution. Extracellular signal-regulated kinase 1/2 (ERK1/2), p38 mitogen-activated protein kinase (p38MAPK), and c-Jun N-terminal kinase (JNK) are major members of the MAPK family and have been suggested to play important roles in mediating tight-junction protein expression and function in different tissues and cells (González-Mariscal et al., 2008). We found that the p-ERK1/2 level was significantly increased at 5 and 10 min, and returned to the basal level at 30 min after 10 µmol/l capsaicin treatment (Fig. 6A). However, the levels of p-p38MAPK and p-JNK were not changed at these times (supplementary material Fig. S1C). The total amounts of ERK1/2, p38MAPK and JNK did not change by capsaicin treatment. The results suggested that ERK1/2, but not p38MAPK or JNK, was the downstream signaling molecule selectively regulated by capsaicin. Pretreatment with CPZ (10 µmol/l for 30 min) abolished capsaicin-induced ERK1/2 phosphorylation (Fig. 6B), further indicating that capsaicin induced ERK1/2 activation through TRPV1.

• Download figure
• Open in new tab
• Download powerpoint

Fig. 6.

Activation of TRPV1 increases ERK1/2 and MLC2 phosphorylation, and alters F-actin distribution. (A) The levels of p-ERK1/2 were significantly increased after 10 µmol/l capsaicin treatment, while the total ERK1/2 level showed no change. (B) The capsaicin (CAP)-induced increase in p-ERK1/2 expression was suppressed by pretreatment with 10 µmol/l capsapine (CPZ) for 30 min. (C) Phosphorylation of MLC2 at Ser19 was elevated by capsaicin treatment. Expression of total MLC2 did not change. Values are means ± s.d. from three independent experiments performed in duplicate. *P<0.05 and **P<0.01 compared with control. ^##P<0.01 compared with capsaicin-treated cells. (D) Pre-incubation with ML-7 (20 µmol/l) for 30 min had no effect on the capsaicin-induced ERK1/2 phosphorylation, whereas pretreatment with PD98059 (20 µmol/l) for 30 min abolished the MLC2 phosphorylation induced by capsaicin. (E) Immunofluorescence imaging of F-actin after capsaicin treatment for 5–60 min. Under unstimulated conditions, F-actin was mainly present at the peri-junctional regions with abundant stress fibers in the cytoplasm. However, the architecture of F-actin was disorganized, and a significant decrease in the stress fibers was observed after 10 µmol/l capsaicin treatment. Moreover, the capsaicin-induced F-actin disorganization was inhibited by pretreatment with CPZ. (F) Co-immunofluorescence imaging of F-actin with either E-cadherin or occludin. Upper panel: capsaicin (10 µmol/l for 10 min) reorganized F-actin, but the distribution of E-cadherin was not affected. Lower panel: capsaicin treatment resulted in the redistribution of both F-actin and occludin. (G) Both F-actin staining (upper panel) and F-actin/E-cadherin co-staining (lower panel) showed that pretreatment with either PD98059 or ML-7 abolished the capsaicin-induced F-actin redistribution, while PD98059 and ML-7 alone had no effect on F-actin organization. Incubation with cytochalasin B (CytoB, 20 µmol/l for 30 min) or Ca²⁺-free medium were used as positive controls. Each image is a representative of three separate experiments in duplicate.

Capsaicin increases MLC2 phosphorylation in an ERK1/2-dependent manner

Myosin light chain 2 (MLC2) is a member of the regulatory light chain of myosin II, and plays a crucial role in regulating the distribution of tight junctions as well as the paracellular permeability in epithelial cells (Hecht et al., 1996; Shen et al., 2006). We explored the effect of capsaicin on MLC2 phosphorylation and the relationship between ERK1/2 and MLC2 in SMG-C6 cells. Phosphorylation of MLC2 at Ser19 was significantly elevated at 5 min, peaked at 10 min, and returned to basal level at 30 min after capsaicin treatment (Fig. 6C). Pre-incubation with ML-7 (20 µmol/l), an inhibitor of MLC2 upstream kinase, for 30 min did not affect the capsaicin-induced ERK1/2 phosphorylation. However, pretreatment with PD98059 (20 µmol/l), an inhibitor of ERK1/2 upstream kinase, for 30 min abolished the capsaicin-induced MLC2 phosphorylation (Fig. 6D). As shown in supplementary material Fig. S1D, the concentrations of PD98059 or ML-7 used in this study effectively inhibited their target kinases in SMG-C6 cells. These results indicated that MLC2 was downstream of ERK1/2 in SMG-C6 cells, and capsaicin activated MLC2 in an ERK1/2-dependent manner.

Activation of TRPV1 alters F-actin organization in an ERK1/2- and MLC2-dependent manner

Since F-actin has a direct structural link with the tight-junction complex, any influence on F-actin organization could alter tight junction distribution as well as paracellular permeability (Bruewer et al., 2004; Peixoto and Collares-Buzato, 2005). Therefore, we examined the effect of capsaicin on F-actin organization. Under unstimulated condition, a high density of F-actin was present at the peri-junctional regions with abundant stress fibers in the cytoplasm of SMG-C6 cells. However, F-actin architecture was disorganized after capsaicin (10 µmol/l) treatment for 5, 10 and 30 min. A significant decrease in the stress fibers and more F-actin at the cell periphery, together with an obvious increased space between adjacent F-actin filaments was seen at those time points, whereas it was partly recovered after capsaicin treatment for 60 min (Fig. 6E). CPZ pretreatment (10 µmol/l for 30 min) abolished capsaicin-induced F-actin reorganization (Fig. 6E). Co-staining of F-actin and E-cadherin further showed that capsaicin reorganized F-actin in particular while the distribution of E-cadherin was unaffected (Fig. 6F, upper panel). To further clarify whether this increased peripheral F-actin was at cell–cell junctions, co-staining of F-actin with occludin was performed. Results showed that the displacement of occludin occurred with an increased F-actin staining close to the occludin position, indicating that F-actin was assembled near the cell–junction region by capsaicin treatment (Fig. 6F, lower panel).

We also identified the effects of ERK1/2 and MLC2 on F-actin organization. Pretreatment with either PD98059 or ML-7 for 30 min abolished the capsaicin-induced F-actin reorganization, whereas PD98059 and ML-7 alone, as well as DMSO, had no effect on F-actin morphology (Fig. 6G, upper panel). Co-immunofluorescence images of F-actin and E-cadherin showed that the disrupted stress fiber organization, as well as the junctional reorganization of F-actin was restored by PD98059 and ML-7 pretreatment (Fig. 6G, lower panel). These results suggested that both ERK1/2 and MLC2 were required in TRPV1-modulated F-actin organization. Cytochalasin B (CytoB) or Ca²⁺-free medium were used as the positive control (Bengtsson et al., 1993; Nybom and Magnusson, 1996; Schaphorst et al., 2003). CytoB (20 µmol/l for 30 min) induced a disruption of actin filaments, and incubation of SMG-C6 cells in a Ca²⁺-free medium for 60 min caused an obvious shrinkage of the filaments (Fig. 6G).

ERK1/2/MLC2 signaling pathway is involved in TRPV1-mediated paracellular permeability and occludin redistribution

The involvement of the ERK1/2 and MLC2 pathway in capsaicin-induced paracellular permeability and occludin distribution was further investigated. Pretreatment with either PD98059 or ML-7 for 30 min abolished the capsaicin-induced decreases in TER (Fig. 7A,B), and meanwhile, suppressed capsaicin-induced redistribution of occludin (Fig. 7C), whereas PD98059 and ML-7 alone did not affect TER or occludin location. In addition, to demonstrate the crucial involvement of the cytoskeleton in capsaicin-induced occludin redistribution, we pretreated cells with either CytoB for 30 min or Ca²⁺-free medium for 60 min and found that occludin expression in the cell membrane was dramatically disrupted and simultaneously the staining in the cytoplasm was increased (Fig. 7C). This suggested a crucial requirement of cytoskeleton organization for TRPV1-mediated occludin distribution. Quantification of the intensity of the occludin fluorescence in the cytosol showed that increased occludin in cytosol induced by capsaicin was significantly inhibited by either PD98059 or ML-7 pretreatment (Fig. 7D). Moreover, the increased expression of occludin in the cytoplasm and the decreased expression of occludin in membrane, was blocked by pretreatment with PD98059 and ML-7 for 30 min, respectively (Fig. 7E). These results again indicated that ERK1/2 and MLC2 signaling molecules are responsible for capsaicin-induced increased paracellular permeability and occludin redistribution.

• Download figure
• Open in new tab
• Download powerpoint

Fig. 7.

ERK1/2 and MLC2 are involved in capsaicin-induced paracellular permeability and occludin redistribution. Pretreatment with either 20 µmol/l PD98059 (A) or 20 µmol/l ML-7 (B) for 30 min abolished the capsaicin (CAP)-induced decreases in TER values. Values are means ± s.d. from three independent experiments performed in duplicate. *P<0.05 and **P<0.01 compared with unstimulated cells. (C) Pretreatment with either PD98059 or ML-7 suppressed capsaicin-induced redistribution of occludin. Incubation with cytochalasin B (CytoB, 20 µmol/l for 30 min) or Ca²⁺-free medium for 60 min dramatically disrupted occludin distribution in the membrane. Each image is a representative of three separate experiments in duplicate. Scale bars for the lower and higher magnification images: 40 µm and 25 µm, respectively. (D) The quantitative analysis of the fluorescence intensity of occludin in the cytosol. The capsaicin-induced increase in cytosolic occludin was significantly inhibited by either PD98059 or ML-7 pretreatment. **P<0.01 compared with unstimulated cells. ^#P<0.05 compared with capsaicin-treated cells. (E) Pretreatment with either PD98059 or ML-7 abolished the capsaicin-induced increase in occludin expression in the cytoplasm fraction, as well as the decreased occludin expression in the membrane fraction.

We also treated SMG-C6 cells with scrambled control or ERK1/2-specific siRNA. The expression of total ERK1/2 was markedly reduced and capsaicin-induced increased p-ERK1/2 and p-MLC2 disappeared (Fig. 8A). More importantly, the decreases in both TER (Fig. 8B) and occludin redistribution induced by capsaicin were significantly attenuated by ERK1/2 knockdown (Fig. 8C), in parallel with the above results using ERK1/2 inhibitor, which again confirmed the importance of ERK1/2 in TRPV1-modulated paracellular permeability and occludin distribution.

• Download figure
• Open in new tab
• Download powerpoint

Fig. 8.

The capsaicin-induced decrease in TER values and occludin redistribution does not occur in ERK1/2 knockdown cells. (A) Expression of ERK1/2 and MLC2 in SMG-C6 cells that were transfected with ERK1/2 siRNA. The expression of total ERK1/2 was markedly decreased and capsaicin-induced increases in p-ERK1/2 and p-MLC2 did not occur. (B) The capsaicin-induced decreases in TER were attenuated in ERK1/2 knockdown cells. Values are means ± s.d. from three independent experiments performed in duplicate. *P<0.05 and **P<0.01 compared with unstimulated cells. (C) The capsaicin-induced occludin redistribution did not occur in ERK1/2 knockdown cells. Each image is a representative of three separate experiments in duplicate. Scale bars: 25 µm.