Abstract
Head and neck cancer (HNC) is the sixth most common cancer worldwide with a 5-year survival rate of less than 50%. The PI3K/AKT/mTOR signaling pathway is frequently implicated in HNC. Recently, IQ motif–containing GTPase-activating protein 1 (IQGAP1) was discovered to scaffold the PI3K/AKT signaling pathway. IQGAP1 gene expression is increased in HNC, raising the hypothesis that IQGAP1 contributes to HNC.
We performed a combination of in vitro studies using human cancer cell lines treated with a cell-permeable peptide that interferes with IQGAP1′s ability to bind to PI3K, and in vivo studies utilizing mice genetically knocked out for the Iqgap1 (Iqgap1−/−). In vivo EGF stimulation assays were used to evaluate PI3K signaling. To study the role of IQGAP1 in HNC, we used a well-validated mouse model that drives HNC via a synthetic oral carcinogen, 4-nitroquinoline 1-oxide (4NQO).
IQGAP1 is necessary for efficient PI3K signaling in vitro and in vivo. Disruption of IQGAP1-scaffolded PI3K/AKT signaling reduced HNC cell survival. Iqgap1−/− mice had significantly lower cancer incidences, lesser disease severity, and fewer cancer foci. IQGAP1 protein levels were increased in HNC arising in Iqgap1+/+ mice. The level of PI3K signaling in 4NQO-induced HNC arising in Iqgap1−/− mice was significantly reduced, consistent with the hypothesis that IQGAP1 contributes to HNC at least partly through PI3K signaling. High IQGAP1 expression correlated with reduced survival, and high pS6 levels correlated with high IQGAP1 levels in patients with HNC.
These data demonstrate that IQGAP1 contributes to head and neck carcinogenesis.
Head and neck cancer (HNC) is the sixth most common cancer with a 5-year survival rate less than 50%. A frequently altered pathway in HNC is EGFR and its downstream PI3K signaling, which can be scaffolded by IQGAP1. Herein, we investigated the role of IQGAP1 in HNC using a combination of in vitro and in vivo approaches in human and mouse tissues/cell lines. We demonstrate that IQGAP1 is necessary for efficient PI3K signaling in vitro and in vivo, and the loss of IQGAP1 significantly reduced cancer phenotypes in mice. PI3K signaling was reduced in HNC arising in Igqap1-knockout mice, supporting that IQGAP1 contributes to HNC, at least partly through scaffolding PI3K. High IQGAP1 levels correlated with high pS6 levels in patients with HNC. Importantly, high IQGAP1 levels correlated with poor survival in patients with HNC, implicating its importance. Drugs that target IQGAP1 may provide new approaches to treat patients with HNC.
Introduction
Head and neck cancers (HNCs), most often, squamous cell carcinoma, arise in the mouth/throat region and are the sixth most frequent cancer worldwide, with a 5-year survival rate less than 50% (1, 2). Risk factors for HNC include smoking, alcohol abuse, and infection with high-risk human papillomaviruses (HPV; ref. 1). EGFR and downstream PI3K signaling are among the most frequently altered factors in HNCs (3–7).
PI3K is implicated in diverse physiologic processes including cell survival, migration, and proliferation. In response to agonists, PI3K converts phosphatidylinositol-4,5- biphosphate (PIP2) to phosphatidylinositol-3,4,5-trisphosphate (PIP3). PIP3 then functions as a messenger to activate AKT, which activates multiple downstream effectors including the mTOR1 pathway to promote cell growth and protein synthesis (8, 9). PI3K/AKT/mTOR signaling plays an important role in HNC. Mutations in the PI3K pathway arise in 30% of HNCs (3). Activating mutations in the 110 kDa catalytic subunit of PI3K are found in 20% of HNCs (5). These PIK3CA mutations increase PI3K activity and thereby promote HNC cell growth (3). Pan-PI3K inhibitors suppress HNC cell growth both in tissue culture and in xenografts (8, 10, 11). However, clinical treatments with small-molecule inhibitors targeting the PI3K/AKT/mTOR pathway have had limited success due to toxicity and possible drug resistance (8). Therefore, drugs targeting other components of the PI3K/AKT/mTOR pathway in HNC may provide more effective treatments.
IQ motif–containing GTPase-activating protein 1 (IQGAP1), a scaffolding protein, mediates many cellular pathways, contains multiple protein interaction domains, and interacts with more than 100 proteins to regulate diverse cellular processes including cytoskeletal dynamics, adhesion, cell motility/invasion, and cell proliferation (12–16). It can also bind directly to EGFR and mediate receptor activation (17) as well as scaffold and facilitate the Ras–MAPK pathway (16). IQGAP1 is overexpressed in several cancers, including breast, lung, colorectal carcinomas, and squamous cell carcinoma of head and neck (12, 18–21). High levels of IQGAP1 are linked to poor prognosis in HNC (21). Diminished tumorigenesis was observed in Iqgap1-knockout mice in a Ras-driven skin cancer model (16).
IQGAP1-mediated PI3K/AKT/mTOR signaling is important for cancer cell survival. Recently, IQGAP1 was reported to assemble each of the kinases, including PI3K and AKT that are necessary for rapid, channeled conversion of PI to PIP3 upon receptor activation, resulting in increased AKT activation in vitro and in vivo (22). Cell-permeable peptides that interfered with the ability of IQGAP1 to bind to PI3K disrupted the intracellular formation of the scaffolded PI3K complex and inhibited AKT activation (22). These peptides diminished breast cancer cell survival, including cell lines harboring PIK3CA mutations, while not affecting normal cells (22). These data indicated IQGAP1-mediated PI3K signaling in cancer cell survival. Blocking IQGAP1-mediated PI3K signaling using the same peptide in UM-SCC47, a HNC cell line, inhibited cell proliferation, migration, and invasion (23). Upon IQGAP1 overexpression, IQGAP1-dependent phosphorylation of ERK1/2 is impeded via AKT-mediated phosphorylation of Forkhead box protein O1, a downstream effector of AKT, suggesting that there is cross-talk among IQGAP1-mediated pathways (24).
Here, we focus on the role of IQGAP1 in HNC using a well-established mouse model for keratinizing squamous cell carcinoma of head and neck, in which a synthetic oral carcinogen, 4-nitroquinoline 1-oxide (4NQO), is used to drive tumorigenesis (25). This carcinogen causes a spectrum of DNA damage similar to that caused by tobacco-associated carcinogens (25). 4NQO is known to cause HNC in mice, at least in part, by activating EGFR signaling, upstream of the PI3K/AKT/mTOR pathway, and therefore was chosen as a preclinical model that closely reflects activation of EGFR in human HNCs (9, 25).
To test the role of IQGAP1, we used genetically engineered mice deficient for IQGAP1 (16, 26). These Iqgap1-knockout (Iqgap1−/−) mice develop normally and have no apparent phenotypes (26). We observed a reduced level of PI3K signaling in Iqgap1−/− mice upon EGF stimulation. Upon treatment with 4NQO, we observed that loss of IQGAP1 reduced the incidence of carcinoma, the number of tumor foci, and disease severity. In the absence of IQGAP1, PI3K signaling was significantly decreased in 4NQO-induced HNC. In Iqgap1+/+ mice, IQGAP1 protein level was upregulated in HNC, consistent with that observed in human HNCs (20, 21). Survival analysis using RNA-seq data from The Cancer Genome Atlas (TCGA) program revealed that high expression of IQGAP1 correlates with poorer 5-year survival probabilities in patients with HNC. We also discovered a positive correlation between levels of IQGAP1 and PI3K signaling that is statistically significant utilizing a tissue microarray (TMA). Our studies support the hypothesis that IQGAP1 functions as an oncogene in head and neck carcinogenesis and does so, at least in part, by activating the PI3K/AKT signaling pathway.
Materials and Methods
Cell culture and siRNA knockdown
UPCI-SCC90 cells were purchased from ATCC. UM-SCC1 cells were purchased from Millipore. Cal33 cells were gifts from Dr. Jennifer Grandis from University of California, San Francisco (San Francisco, CA). All cells were maintained in DMEM supplemented with 10% FBS (Gibco).
In the HNC cells, siRNAs targeting human IQGAP1 (Dharmacon, L-004694) or control siRNAs (Dharmacon, D-001810-10) were transfected using Lipofectamine RNAiMAX (Thermo Fisher Scientific) for 72 hours.
Peptide treatment and cell counting
IQ3 peptides were generated as described previously (22). The HNC cells were seeded on 6-well culture dishes. Media were changed with or without IQ3 peptide added in the indicated concentrations every day for 3 days. For measuring cell viability, 50,000 cells were seeded in each well. Once cells attached, scramble or 30 μmol/L IQ3 peptides were treated for the indicated time. After peptide incubation, cells were lifted by Trypsin-EDTA (Thermo Fisher Scientific) and Trypan Blue–positive viable cells were counted using a hemocytometer. The experiments were independently repeated three times and the graphs are shown as mean ± SD.
Mice
Iqgap1+/+ and Iqgap1−/− mice (from Dr. David Sacks, NIH, Bethesda, MD; ref. 16) were generated on a mixed genetic background [50%FVB/50% (129 + C57BL/6)]. All mice were genotyped by PCR as described previously (16). Mice were housed in the Association for Assessment of Laboratory Animal Care–approved McArdle Laboratory Animal Care Unit. All procedures were carried out in accordance with an animal protocol approved by the University of Wisconsin Institutional Animal Care and Use Committee.
In vivo EGF stimulation
Mice were treated with EGF as described previously (27). Briefly, 5-week-old Iqgap1+/+ and Iqgap1−/− mice were injected subcutaneously with 5 μg/g body weight of hEGF (Prospec, CYT-217), or PBS alone as vehicle control. hEGF was stored as 1 mg/mL stock solution in PBS at −80°C. Mice were sacrificed 10 minutes after injection and dorsal skin was harvested and snap frozen in liquid nitrogen.
Protein lysate preparation and immunoblotting
Cells were lysed with a lysis buffer (1% Brij58, 150 mmol/L NaCl, 2 mmol/L CaCl2, 2 mmol/L MgCl2, 20 mmol/L HEPES pH 7.4) and protein concentration was measured using the bicinchoninic acid method (Thermo Fisher Scientific). Frozen skin was cut into small pieces on ice using razor blades, homogenized in 300-μL RIPA buffer [25 mmol/L Tris (pH 8), 150 mmol/L NaCl, 0.1%SDS, 0.5% sodium deoxycholate, 1%Triton X-100] with protease and phosphatase inhibitors using a plastic pestle (Axygen) and incubated on an orbital shaker at 4°C for 20 minutes. Homogenates were centrifuged at 14,000 rpm for 20 minutes at 4°C and supernatants (protein lysates) collected. Protein concentrations were determined using the Bradford Protein Assay (Bio-Rad). Equivalent amounts of protein were resolved on precast Mini-PROTEAN TGX 7.5% gels (Bio-Rad) and transferred to polyvinylidene difluoride membranes (Millipore). Membranes were blocked with 5% nonfat dry milk in TBST (Tris-buffered saline with 0.1% Tween-20). Primary antibodies used are summarized in Supplementary Table S1. Horseradish peroxidase (HRP)–conjugated secondary antibodies (1:10,000; Jackson ImmunoResearch) and chemiluminescent substrates (Clarity ECL Substrates; Bio-Rad) were used to visualize on a Bio-Rad ChemiDoc Imaging System.
4NQO-induced head and neck carcinogenesis study
Six- to 8-week-old Iqgap1+/+ and Iqgap1−/− mice were treated with 4NQO (Sigma) in their drinking water at a concentration of 100 μg/mL or 20 μg/mL (stored at 4°C as a 5 mg/mL stock) for 16 weeks. Mice were then returned to normal drinking water for 5 (with 100 μg/mL 4NQO) or 8 weeks (with 20 μg/mL 4NQO). At the end of this period, mice were euthanized, grossly visible, overt tumors on the tongue and esophagus were quantified, and tissues were collected for histologic analysis.
Histologic analysis
The tongue and the esophagus were harvested and fixed in 4% paraformaldehyde (in PBS) for 24 hours and then switched to 70% ethanol for 24 hours, processed, embedded in paraffin, and sectioned at 5-μm intervals. Every 10th section was stained with hematoxylin and eosin and examined by pathologist D. Buehler in a blinded fashion for the most severe state of neoplasia.
Immunofluorescence
Tissue sections were deparaffinized in xylenes and rehydrated in 100%, 95%, 70%, and 50% ethanol and then in water. Antigen unmasking was performed by heating with 10 mmol/L citrate buffer (pH = 6) for 20 minutes. Blocking was performed with Superblock blocking buffer (Thermo Fisher Scientific) for 1 hour at room temperature. Slides were incubated in primary antibody at 4°C overnight in a humidified chamber. Alexa goat-anti-rabbit-594 (Invitrogen, 1:500) was applied the next day for 1 hour at room temperature. Sections were counterstained with DAPI and mounted in Prolong Diamond Antifade Mountant (Invitrogen). All images were taken with a Zeiss AxioImager M2 microscope using AxioVision software version 4.8.2.
pERK signals were detected using a tyramide-based signal amplification (TSA) method (28) as described previously (29). Tissues were incubated in anti-pERK (1:100) at 4°C, overnight, and then 1 hour in goat-anti-rabbit-HRP secondary antibody at 1:500 dilution in blocking buffer at room temperature the next day. TSA was then performed, followed by incubation with anti-streptavidin-647 (Invitrogen,1:500) for 1 hour at room temperature. Sections were counterstained and mounted.
Image analysis and statistical analysis
One-sided t tests were used to determine the significance of AKT, ERK, and S6 activation upon in vivo EGF stimulation. The percent activated protein was calculated by comparing the ratio of phosphorylated protein signal with total protein signal in both PBS-injected (control) and EGF-injected (stimulated) mice. Protein activation was then calculated by determining the fold change of percent activated protein between EGF/PBS-treated mice. Error bars (SD) were calculated by taking the average of four or six replicates.
To compare overt tumor incidences and overall cancer incidence among groups, a two-sided Fisher exact test was performed using MSTAT statistical software version 6.4.2 (http://www.mcardle.wisc.edu/mstat). Wilcoxon rank-sum test was performed to determine the significance of differences in number of overt tumor foci and total cancer foci using MSTAT. For disease severity, each microscopic tumor grade was assigned a ranking order (mild dysplasia = 1, moderate dysplasia = 2, severe dysplasia/carcinoma in situ = 3, well-differentiated invasive carcinoma = 4, moderately differentiated invasive carcinoma = 5, and poorly differentiated invasive carcinoma = 6) and analyzed using the Wilcoxon rank-sum test.
To quantify pS6 and pERK levels between groups of mice, 10 immunofluorescence microscopic images (200×) of regions of the normal and cancer tissue per mouse were captured. All images were taken under constant exposure time. Images were processed using ImageJ software version 10.2 (NIH, Bethesda, MD). pS6 and pERK levels on each image were calculated by integrated intensity of the signal, normalized to the DAPI signal from the same area. For statistical analysis, pS6 and pERK levels in the normal and cancer tissue were calculated separately by taking the average levels in each of the corresponding 10 images per mouse, and the data were pooled across replicates. A two-sided t test was used to determine the significance of signal differences between groups.
TCGA survival analysis
TCGA RNA-seq data were accessed through the Human Protein Atlas website (https://www.proteinatlas.org/ENSG00000140575-IQGAP1/pathology/tissue/head+and+neck+cancer). Cutoff for IQGAP1 levels was suggested by the database as shown on the website. Only data for the first 5 years were analyzed because of the smaller number of censored subjects. Kaplan–Meier survival curve analysis and log-rank test were done using MSTAT.
TMA analysis
HNC TMA slide was provided by the Wisconsin Head and Neck Cancer SPORE. The TMA slide contains 411 cores collected from 137 patient specimens, including 180 primary, 153 recurrent, and 78 metastasized cancer cores. About 10% of sample cores were lost during sectioning and staining. Remaining 360 cores from 124 patients were analyzed. Within these 360 cores, there are 168 p16-positive, 162 p16-negative, and 30 p16-equivocal cores. p16 is the indicator for HPV status in clinics.
Multiplex staining on the TMA slide was carried out to measure DAPI, pS6, IQGAP1, and pan-cytoskeleton. The slide was stained sequentially. Day 1: same as in the previously described TSA method, with anti-pS6 antibody overnight at 4°C. Day 2: same secondary antibody and TSA incubation as described. Then the slide was probed overnight with both anti-IQGAP1 and anti-pan-cytokeratin. Day 3: the slide was incubated in a cocktail of fluorescent secondary antibodies at 1:200 dilution at room temperature for 1 hour, using anti-streptavidin-488 (Invitrogen, reading pS6), goat-anti-rabbit-546 (reading IQGAP1), and goat-anti-mouse-647 (reading pan-cytokeratin). The slide was then counterstained with DAPI and mounted. The stained TMA was scanned by the UW Translational Research Initiatives in Pathology facility using the Vectra multispectral imaging system at 20×. The acquired images were analyzed by the Perkin-Elmer inForm software, which identifies epithelia with pan-cytokeratin patterns, and individual cells with DAPI staining. Only signals from certain cell compartments (cytoplastic pS6 and membrane IQGAP1) in identified cells from epithelium were quantified. The expression levels of both markers were quantified and reported as H-scores. Spearman rank correlation test against these H-scores from both markers was conducted using MSTAT.
Results
IQGAP1 is necessary for efficient PI3K signaling in vitro and in vivo
Prior studies demonstrated that IQGAP1 scaffolds the PI3K signaling pathway (22), and blocking IQGAP1-mediated PI3K signaling reduced cell proliferation, migration, and invasion in UM-SCC47 cells (23). Because UM-SCC47 has no known mutation in PI3K signaling pathway (30), we tested the role of IQGAP1 and its PI3K-scaffolding ability in three additional HNC cell lines: UPCI:SCC-90 (SCC-90, PTEN mutation), Cal33 (PIK3CA mutation), and UM-SCC1 (SCC-1; refs. 30, 31). Knockdown of IQGAP1 led to reduced PI3K signaling in these cells (Fig. 1A). We then tested whether IQGAP1-mediated PI3K signaling is required for growth/survival of these HNC cell lines. Treatment with the cell-permeable IQ3 peptide, which inhibits IQGAP1′s ability to bind to PI3K, led to reduced PI3K signaling (Fig. 1B), and inhibited cell growth/survival of all cell lines (Fig. 1C). Thus, IQGAP1 contributes to the PI3K signaling pathway in cancer cells, and IQGAP1-mediated PI3K signaling is necessary for HNC cell growth/survival.
To assess whether IQGAP1 is necessary for activation of PI3K/AKT pathway signaling in vivo, we utilized Iqgap1-knockout mice (Iqgap1−/−; Supplementary Fig. S1A; ref. 26). PI3K signaling can be activated in vivo via EGF stimulation (27). Activation of the PI3K/AKT pathway by EGF was scored as the ratio of pAKT/AKT and pS6/S6. We found that AKT activation upon EGF stimulation was significantly lower in Iqgap1−/− mice compared with Iqgap1+/+ mice (P = 0.006, t test, one-sided; Fig. 1D and E). We also observed a significantly lower S6 activation in Iqgap1−/− mice compared with Iqgap1+/+ mice (P = 0.038; Fig. 1D and F). These data indicated that IQGAP1 is required for efficient activation of PI3K signaling upon EGF stimulation. Previous studies suggested that IQGAP1 scaffolds the Ras–MAPK signaling pathway (16, 32), another important pathway implicated in various epithelial cancers that can also be activated by EGF. We found that Iqgap1−/− mice did not display significantly different levels of ERK activation than Iqgap1+/+ mice (Supplementary Fig. S1B and S1C).
IQGAP1 contributes to overt head and neck tumorigenesis in vivo
As shown above, IQGAP1 is necessary, both in vitro and in vivo, for efficient PI3K/AKT signaling. This pathway is often activated in HNC (5), and disruption of IQGAP1-mediated PI3K signaling by the IQ3 peptide decreased HNC cell survival (Fig. 1B and C). Therefore, we next tested whether loss of IQGAP1 prevents or reduces the onset and/or severity of HNC using a well-established mouse model for keratinizing squamous cell carcinoma of the head and neck (25). Groups of Iqgap1+/+ and Iqgap1−/− mice were given 4NQO, the synthetic oral carcinogen, in their drinking water for 16 weeks, followed by 5 or 8 weeks of normal drinking water (Fig. 2A). Mouse weight was used as a criterion to monitor mouse health. With 100 μg/mL 4NQO, morbidity issues, as reflected by weight loss, arose in a few Iqgap1+/+ mice by week 16, the endpoint of 4NQO treatment, and worsened as the experiment proceeded. Interestingly, no weight loss was evident in the Iqgap1−/− group of mice. We ended the 100 μg/mL dosage study early, at 21 weeks instead of 24 weeks, because more than 20% of Iqgap1+/+ mice showed significant weight loss. With 20 μg/mL 4NQO, no significant morbidity issues were observed.
Both groups developed tongue and esophageal overt tumors in all animals when treated with 100 μg/mL 4NQO. When treated with 20 μg/mL 4NQO, Iqgap1−/− mice showed lower, although not significant, overt tumor incidence compared with Iqgap1+/+ mice (82% vs. 61%, Fig. 2B). Iqgap1−/− mice also had fewer overt tumors per mouse compared with Iqgap1+/+ mice (Fig. 2C). Although this difference was not significant with 100 μg/mL 4NQO, Iqgap1−/− mice treated with 20 μg/mL 4NQO developed significantly fewer overt tumors per mouse than Iqgap1+/+ mice (mean: 2.68 vs. 1.57, P = 0.05, Wilcoxon rank-sum test, two-sided). Together, these overt tumor data demonstrate that IQGAP1 contributes to tumorigenesis in the head and neck region in vivo.
IQGAP1 contributes to the frequency and severity of invasive squamous cell carcinoma
We next assessed disease severity in both the tongue and esophageal cancers by histopathologic grading of dysplasia and invasive carcinoma (Table 1). When treated with 100 μg/mL 4NQO, 68.4% of Iqgap1+/+ mice and 62.5% of Iqgap1−/− mice developed invasive carcinoma, whereas treated with 20 μg/mL 4NQO, Iqgap1+/+ mice developed significantly higher incidence of invasive carcinoma than Iqgap1−/− mice (73% vs. 39%, P < 0.05, Fisher exact test, two-sided, Fig. 3A), indicating that IQGAP1 affects the overall percentage of mice developing cancer. Iqgap1+/+ mice also developed overall significantly more high-grade tumors than Iqgap1−/- mice in both treatment groups (Table 1), demonstrating that IQGAP1 contributes to increased disease severity upon 4NQO treatment in vivo.
A. 100 μg/mL 4NQO for 16 weeks + 5 weeks of normal drinking water . | ||||||||
---|---|---|---|---|---|---|---|---|
. | . | . | Dysplasia . | Carcinoma . | ||||
Total . | n . | Normal . | Mild . | Moderate . | Severe . | Well-differentiated (grade 1) . | Moderately differentiated (grade 2) . | Poorly differentiated (grade 3) . |
Iqgap1+/+ | 19 | 0 | 1 | 1 | 4 | 2 | 5 | 6 |
Iqgap1−/− | 16 | 0 | 1 | 1 | 5 | 8 | 1 | 0 |
A. 100 μg/mL 4NQO for 16 weeks + 5 weeks of normal drinking water . | ||||||||
---|---|---|---|---|---|---|---|---|
. | . | . | Dysplasia . | Carcinoma . | ||||
Total . | n . | Normal . | Mild . | Moderate . | Severe . | Well-differentiated (grade 1) . | Moderately differentiated (grade 2) . | Poorly differentiated (grade 3) . |
Iqgap1+/+ | 19 | 0 | 1 | 1 | 4 | 2 | 5 | 6 |
Iqgap1−/− | 16 | 0 | 1 | 1 | 5 | 8 | 1 | 0 |
B. 20 μg/mL 4NQO for 16 weeks + 8 weeks of normal drinking water . | ||||||||
---|---|---|---|---|---|---|---|---|
. | . | . | Dysplasia . | Carcinoma . | ||||
Total . | n . | Normal . | Mild . | Moderate . | Severe . | Well-differentiated (grade 1) . | Moderately differentiated (grade 2) . | Poorly differentiated (grade 3) . |
Iqgap1+/+ | 22 | 0 | 1 | 2 | 3 | 9 | 6 | 1 |
Iqgap1−/− | 28 | 0 | 5 | 2 | 10 | 4 | 5 | 2 |
B. 20 μg/mL 4NQO for 16 weeks + 8 weeks of normal drinking water . | ||||||||
---|---|---|---|---|---|---|---|---|
. | . | . | Dysplasia . | Carcinoma . | ||||
Total . | n . | Normal . | Mild . | Moderate . | Severe . | Well-differentiated (grade 1) . | Moderately differentiated (grade 2) . | Poorly differentiated (grade 3) . |
Iqgap1+/+ | 22 | 0 | 1 | 2 | 3 | 9 | 6 | 1 |
Iqgap1−/− | 28 | 0 | 5 | 2 | 10 | 4 | 5 | 2 |
Note: To determine whether there is a statistical difference in disease severity between Iqgap1+/+ and Iqgap1−/− mice, each stage of disease was assigned an integer from 0 to 6, the value increasing as the disease stage worsened, with normal (within normal limits) assigned a value of 0 and grade 3 carcinoma assigned a value of 6. Statistical analysis: A, disease severity between Iqgap1+/+ and Iqgap1−/− mice. Mean 4.42 versus 3.43. P = 0.01, Wilcoxon rank-sum test, one-sided. B, Disease severity between Iqgap1+/+ and Iqgap1−/− mice: Mean 3.91 versus 3.28. P = 0.05, Wilcoxon rank-sum test, one-sided.
To test whether there are any gender-specific differences in the effect of IQGAP1 on head and neck disease severity, a detailed breakdown of disease severity depending on gender is summarized in Supplementary Fig. S2A. In mice treated with 100 μg/mL 4NQO, no difference was observed between females and males in either experiment groups. In mice treated with 20 μg/mL 4NQO, female mice in both genotypes developed slightly more severe disease than male mice, although neither reached significance. With the loss of IQGAP1, females demonstrated a higher cancer incidence than males, although again the difference did not reach statistical significance (Supplementary Fig. S2B).
To test whether there is any site-specific difference in the effect of IQGAP1 on head and neck disease severity, we compared the disease severity depending on tumor-arising sites, esophagus or tongue (Supplementary Fig. S3A). When treated with 100 μg/mL 4NQO, Iqgap1−/− mice developed slightly less severe disease than Iqgap1+/+ mice in both esophagus and tongue, although neither reached significance. When treated with 20 μg/mL 4NQO, Iqgap1−/− mice developed significantly less severe disease than Iqgap1+/+ mice in the tongue (mean 2.8 vs. 1.8, P = 0.03, Wilcoxon rank-sum test, two-sided). The same trend was observed in the esophagus, although it did not reach significance. When we compared the cancer incidence on both sites, Iqgap1−/− mice showed lower cancer incidence, although not significant, than Iqgap1+/+ mice when treated with 100 μg/mL 4NQO (Supplementary Fig. S3B). When treated with 20 μg/mL 4NQO, Iqgap1−/− mice demonstrated significantly lower cancer incidence than Iqgap1+/+ mice in the esophagus (P = 0.04, Fisher exact test, two-sided). The same trend was observed in the tongue with a difference that approached significance (Supplementary Fig. S3B).
We then assessed the multiplicity of cancer foci and found that Iqgap1+/+ mice treated with 100 μg/mL 4NQO developed significantly higher numbers of cancer foci per mouse compared with like-treated Iqgap1−/− mice (Fig. 3B, mean: 2.3 vs. 1.09, P < 0.001, Wilcoxon rank-sum test, two-sided). We also observed that with the same treatment, Iqgap1+/+ mice developed significantly higher numbers of poorly differentiated, high-grade cancer compared with the Iqgap1−/− mice, which developed mostly well-differentiated, low-grade cancer foci (Fig. 3C, mean: 6.13 vs. 5.09, P < 0.001, Wilcoxon rank-sum test, two-sided). In mice treated with 20 μg/mL 4NQO, the same trends for both number of cancer foci and cancer grade were observed between Iqgap1+/+ and Iqgap1−/− mice, although the differences did not reach statistical significance. These data further demonstrate that IQGAP1 contributes to head and neck carcinogenesis.
IQGAP1 protein levels are upregulated in HNC
IQGAP1 is overexpressed in many human cancers (12, 20, 21, 33, 34). We therefore looked at levels of IQGAP1 protein in our 4NQO-induced HNC model by immunofluorescence. Higher levels of IQGAP1 protein were detected in cancer tissue compared with normal tissue of both the tongue and the esophagus of Iqgap1+/+ mice (Fig. 4A; Supplementary Fig. S1A). The upregulation of IQGAP1 in 4NQO-induced HNC in mice is consistent with prior studies reporting overexpression of IQGAP1 in patients with HNC (20, 21).
PI3K signaling is downregulated in IQGAP1-null mice at tumor sites
IQGAP1 regulates diverse cellular pathways including scaffolding and facilitating Ras–MAPK pathway and PI3K–AKT pathways and promoting Wnt signaling by enhancing nuclear localization of β-catenin, and so forth (13, 15, 16, 22). We wanted to determine which pathways contributed to IQGAP1-mediated head and neck carcinogenesis. Given that the 4NQO HNC mouse model is an EGFR-driven cancer model (25), in addition to previous data showing that PI3K signaling decreased in the absence of IQGAP1, we evaluated whether PI3K signaling decreases in Iqgap1−/− experimental mice. In the esophagus, the 4NQO-induced cancers arising in the Iqgap1−/− mice had a significantly lower level of pS6 than the cancers arising in the Iqgap1+/+ mice (Fig. 4B, P = 0.02, t test, two-sided). The data are consistent with the hypothesis that IQGAP1 contributes to 4NQO-induced HNC by driving PI3K signaling. However, IQGAP1 status did not correlate significantly with pS6 levels in tongue cancers (Supplementary Fig. S3), suggesting that IQGAP1 may exhibit tissue-specific differences in pathway modulation in promoting HNC.
ERK signaling significantly decreases in 4NQO-induced tumors, independent of IQGAP1 status
Our data demonstrate that levels of ERK activation upon EGF stimulation in vivo were not significantly changed in the presence or absence of IQGAP1 (Supplementary Fig. S1B and S1C). However, because of previously suggested role for IQGAP1-scaffolded Ras-MAPK in cancer development (16, 32, 35, 36), we decided to examine the ERK-signaling levels in our 4NQO-induced HNCs. In the esophageal carcinomas, ERK signaling was significantly reduced in 4NQO-induced HNCs, regardless of IQGAP1 status (P = 0.004 < 0.05, t test, two-sided; Supplementary Fig. S1D and S1E). There was no significant difference in pERK levels in tumor and normal tissue between Iqgap1+/+ and Iqgap1−/− mice (normal: P = 0.71; tumor: P = 0.06, t test, two-sided; Supplementary Fig. S1F). These data indicate that IQGAP1 may not contribute to HNC through ERK signaling.
High expression of IQGAP1 correlates with poorer survival in patients with HNC
Previous research using human HNC TMAs demonstrated that high levels of IQGAP1 protein correlate with poor survival in patients with HNC (21). To further study the relationship between IQGAP1 and survival of patients HNC, we analyzed RNA-seq data generated by TCGA. IQGAP1 transcript levels in patient samples were reported as median FPKM (number fragments per kilobase of exon per million reads). Using a Kaplan–Meier survival curve analysis, we found that patients with HNC with high levels of IQGAP1 mRNA were associated with a significantly lower 5-year survival probability in patients with HNC (Fig. 5A, P < 0.001, log-rank test, two-sided).
Levels of IQGAP1 positively correlate with levels of PI3K signaling in samples of patients with HNC
With the knowledge that IQGAP1 correlates with survival of patients with HNC, we investigated whether the levels of IQGAP1 correlate with PI3K signaling in an HNC TMA. The levels of IQGAP1 and pS6 were reported as H-scores. Because our study did not involve HPV, we focused on p16-negative samples. Using a Spearman rank correlation test, we observed a positive correlation between IQGAP1 and pS6, with a coefficient ρ = 0.28, which was highly significant (P < 0.001, Fig. 5B; Supplementary Fig. S5).
We were also interested in whether levels of IQGAP1 correlate with responses to PI3K signaling inhibitors. We obtained five patient-derived xenografts (PDX) samples that were previously tested for response to an mTORC inhibitor, AZD8055 (31). Four of these PDXs, UWSCC1, UWSCC6, UWSCC17, and UWSCC64, were sensitive to the inhibitor, whereas UWSCC13 was resistant to the inhibitor (31). We observed that the IQGAP1 levels varied a lot within these five PDXs and did not demonstrate any pattern correlating with the responses to the inhibitor (Supplementary Fig. S6). Analysis of a larger cohort may be necessary to determine whether the IQGAP1 levels correlate with response to PI3K signaling pathway inhibitors.
Discussion
In this report, we demonstrate that IQGAP1 is necessary for growth/survival of human HNC cells in vitro and contributes to the incidence and severity of HNC disease in an in vivo mouse model of head and neck keratinizing squamous cell carcinoma. Specifically, knockdown of IQGAP1 reduced PI3K signaling in HNC cells. Likewise, IQGAP1 was necessary for efficient PI3K signaling in vivo. Disruption of IQGAP1-mediated PI3K signaling by a cell-permeable peptide inhibited HNC cell survival. Utilizing the 4NQO-induced HNC model that is dependent upon EGFR signaling, we observed that Iqgap1−/− mice showed fewer cancer foci, less cancer incidence, and less overall head and neck disease severity, providing compelling evidence that IQGAP1 contributes to HNC in vivo. IQGAP1 protein levels were upregulated in cancer foci in both the tongue and the esophagus of 4NQO-treated Iqgap1+/+ mice, consistent with what is seen in human HNC. PI3K signaling in the 4NQO-induced esophageal cancers was downregulated in the Iqgap1−/− mice compared with Iqgap1+/+ mice, consistent with the hypothesis that IQGAP1 is acting through PI3K signaling to promote HNC. Analysis of TCGA RNA-seq data demonstrated that high levels of IQGAP1 significantly correlate with poor 5-year survival in patients with HNC. A positive correlation between IQGAP1 and PI3K signaling was also observed using an HNC TMA.
Upon 4NQO treatment, esophageal PI3K signaling in Iqgap1−/− mice was significantly lower in cancer sites when compared with Iqgap1+/+ mice, supporting that IQGAP1 promotes HNC by driving PI3K signaling, given that IQGAP1 scaffolds PI3K signaling (22). However, no significant difference was observed for PI3K signaling in tongue (Supplementary Fig. S4), suggesting that there may be site-specific differences in how IQGAP1 contributes to HNC. This is supported by the differences of disease severity and cancer incidences between the two genotypes of mice in esophagus and tongue (Supplementary Fig. S3). Upon 20 μg/mL 4NQO, with the loss of IQGAP1, we observed a significant decrease in overall disease severity in tongue but not in esophagus (Supplementary Fig. S3A); meanwhile, a significantly reduced cancer incidence was observed in esophagus but not in tongue (Supplementary Fig. S3B). A hypothesis for these observations is that in the tongue of Iqgap1−/− mice, another factor(s) acts to maintain signaling when IQGAP1 is absent. One candidate for this other factor is IQGAP3, another member of the IQGAP family that has highly homologous structural motifs to IQGAP1 (37, 38). IQGAP3 functions similarly to IQGAP1, including its interactions with Rac1 and Cdc42 for actin filament regulation, and promotes the Ras/ERK signaling (37, 39, 40). Interestingly, when IQGAP1 was knocked down in human hepatocellular cancer cells, levels of IQGAP3 protein increased (41). Although it is still unknown whether IQGAP3 scaffolds for PI3K signaling, it is possible that under certain circumstances, IQGAP3 compensates and maintains PI3K signaling when IQGAP1 is absent. However, our own data do not currently support this hypothesis. In mouse skin lysates, we observed a significant increase in levels of IQGAP3 protein with the loss of IQGAP1 in female mice but not in male mice (P < 0.001, t test, two-sided; Supplementary Fig. S7A and S7B). Iqgap1−/− female mice had significantly higher levels of IQGAP3 than Iqgap1−/− male mice (P < 0.001, t test, two-sided; Supplementary Fig. S7C). Nevertheless, we did not see a significant difference in disease severity or cancer incidence in the head and neck region between female and male mice in either the Iqgap1+/+ or Iqgap1−/− context (Supplementary Fig. S2). This finding raises a question about whether IQGAP3 compensates for IQGAP1 in carcinogenesis in an epithelial context.
Although we have focused on IQGAP1-mediated PI3K signaling, we cannot discount the possibility that IQGAP1 may act through other pathways to promote HNC. Jameson and colleagues proposed that in a Ras-driven skin cancer model, Iqgap1−/− mice were resistant to skin tumorigenesis, and this reduced tumorigenesis was due to the lack of IQGAP1-scaffolded Ras–MAPK signaling (16). In our study, we observed a significant reduction in Ras–MAPK signaling, in HNC, but this was regardless of IQGAP1 status, which indicates that IQGAP1-mediated Ras–MAPK signaling is not driving HNC in our model (Supplementary Fig. S1). Multiple studies have also linked IQGAP1 with Wnt/ β-catenin signaling in cancer promotion (42–44). IQGAP1 is required for sufficient R-spondin–induced Wnt/β-catenin signaling (44). In thyroid cancer, knockdown of IQGAP1 reduced Wnt/β-catenin signaling both in vitro and in vivo, inhibiting tumor growth and epithelial–mesenchymal transition (43). In a hepatocellular carcinoma cell line, IQGAP1 coimmunoprecipitated with β-catenin, increased β-catenin expression and nuclear β-catenin level, and activated downstream transcription (42). In fact, increased levels of nuclear β-catenin were observed in a subset of HNCs (45). We envisage using, in the future, an unbiased proteomic approach to better understand what signaling pathways are altered in IQGAP1-null tissue.
Because the Iqgap1 gene was deactivated in all cell types in Iqgap1−/− mice, we cannot rule out the possibility that the reduced cancer phenotypes observed in Iqgap1−/− mice were due to the IQGAP1′s involvement in mediating immune responses. IQGAP1 has been implicated in regulating immune cells' functions. IQGAP1-deficient T cells were shown to have enhanced T-cell receptor–mediated signaling and increased cytokine production (46). Primary and naïve CD8+ T cells isolated from Iqgap1−/− mice showed increased levels of cytokine production upon stimulation (47). However, IQGAP1 seems to have different roles in other types of immune cells. Loss of IQGAP1 diminished the cytotoxic activity of a natural killer (NK)-like cell line (48). IQGAP1 also mediates NK-cell activation and antitumor responses in vivo (49). In macrophages, IQGAP1 is involved in the phagocytosis and the activation of caspase-1 upon infection (50–52). The exact role of IQGAP1 in mediating immune response in the context of HNC remains unclear at this point.
Overall, this study demonstrates that IQGAP1 contributes to HNC and, at least in part, through PI3K signaling. This is the first time that IQGAP1 is shown to promote HNC in an in vivo model. By understanding how IQGAP1 contributes to HNC, we may identify new drug targets that mediate IQGAP1-mediated oncogenicity, providing new therapies to treat patients with HNCs.
Disclosure of Potential Conflicts of Interest
No potential conflicts of interest were disclosed.
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Authors' Contributions
Conception and design: T. Wei, S. Choi, R.A. Anderson, P.F. Lambert
Development of methodology: S. Choi
Acquisition of data (provided animals, acquired and managed patients, provided facilities, etc.): T. Wei, S. Choi, D. Buehler
Analysis and interpretation of data (e.g., statistical analysis, biostatistics, computational analysis): T. Wei, S. Choi, D. Buehler, R.A. Anderson
Writing, review, and/or revision of the manuscript: T. Wei, S. Choi, D. Buehler, R.A. Anderson, P.F. Lambert
Administrative, technical, or material support (i.e., reporting or organizing data, constructing databases): T. Wei, S. Choi, P.F. Lambert
Study supervision: R.A. Anderson, P.F. Lambert
Acknowledgments
This study was supported by the following NIH grants: CA210807, CA022443, DE026787. This study made use of core facilities of the University of Wisconsin Carbone Cancer Center (NIH grant CA014520). The authors thank Professor Alan Rapraeger as well as other members of the Lambert lab for useful discussions. The author(s) thank the University of Wisconsin Translational Research Initiatives in Pathology laboratory (TRIP), supported by the UW Department of Pathology and Laboratory Medicine, UWCCC (P30 CA014520), and the Office of the Director—NIH (S10OD023526) for use of its facilities and services. The TMA analysis was supported by the Specialized Program of Research Excellence (SPORE) program, through the NIH National Institute of Dental and Craniofacial Research (NIDCR) and National Cancer Institute (NCI), grant P50DE026787.
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