A Comparative Analysis of NOX4 Protein Expression in Malignant and Non-Malignant Thyroid Tumors

Fenniche, Salma; Oukabli, Mohamed; Oubaddou, Yassire; Chahdi, Hafsa; Damiri, Amal; Alghuzlan, Abir; Laraqui, Abdelilah; Dakka, Nadia; Bakri, Youssef; Dupuy, Corinne; Ameziane El Hassani, Rabii

doi:10.3390/cimb45070367

Open AccessArticle

A Comparative Analysis of NOX4 Protein Expression in Malignant and Non-Malignant Thyroid Tumors

by

Salma Fenniche

^1,2,3,4,

Mohamed Oukabli

^5,6,

Yassire Oubaddou

¹

,

Hafsa Chahdi

^5,6,

Amal Damiri

^5,6,

Abir Alghuzlan

^2,4

,

Abdelilah Laraqui

⁵,

Nadia Dakka

¹,

Youssef Bakri

¹,

Corinne Dupuy

^2,3,4 and

Rabii Ameziane El Hassani

^1,*

¹

Laboratory of Biology of Human Pathologies (BioPatH), Faculty of Sciences, Mohammed V University in Rabat, Rabat 1014, Morocco

²

Gustave Roussy Cancer Campus, Pavillon de Recherche N°2, F-94805 Villejuif, France

³

Faculty of Medicine and Pharmacy, University Paris-Saclay, F-91400 Orsay, France

⁴

Unité Mixte de Recherche UMR9019 Centre National de la Recherche Scientifique, Pavillon de Recherche N°2, F-94805 Villejuif, France

⁵

Service of Anatomical Pathology, Military Hospital of Instruction Mohammed V (HMIMV-R), Rabat 1014, Morocco

⁶

Faculty of Medicine and Pharmacy, Mohammed V University in Rabat, Rabat 10001, Morocco

^*

Author to whom correspondence should be addressed.

Curr. Issues Mol. Biol. 2023, 45(7), 5811-5823; https://doi.org/10.3390/cimb45070367

Submission received: 17 May 2023 / Revised: 8 June 2023 / Accepted: 14 June 2023 / Published: 13 July 2023

(This article belongs to the Special Issue Advanced Molecular Solutions for Cancer Therapy)

Download

Browse Figures

Versions Notes

Abstract

:

The comparative analysis of the expression of the reactive oxygen species-generating NADPH oxidase NOX4 from TCGA data shows that the NOX4 transcript is upregulated in papillary thyroid carcinomas (PTC)-BRAF^V600E tumors compared to PTC-BRAF^wt tumors. However, a comparative analysis of NOX4 at the protein level in malignant and non-malignant tumors is missing. We explored NOX4 protein expression by immunohistochemistry staining in malignant tumors (28 classical forms of PTC (C-PTC), 17 follicular variants of PTC (F-PTC), and three anaplastic thyroid carcinomas (ATCs)) and in non-malignant tumors (six lymphocytic thyroiditis, four Graves’ disease, ten goiters, and 20 hyperplasias). We detected the BRAF^V600E mutation by Sanger sequencing and digital droplet PCR. The results show that NOX4 was found to be higher (score ≥ 2) in C-PTC (92.9%) compared to F-PTC (52.9%) and ATC (33.3%) concerning malignant tumors. Interestingly, all C-PTC-BRAF^V600E expressed a high score for NOX4 at the protein level, strengthening the positive correlation between the BRAF^V600E mutation and NOX4 expression. In addition, independent of the mutational status of BRAF, we observed that 90% of C-PTC infiltrating tumors showed high NOX4 expression, suggesting that NOX4 may be considered a complementary biomarker in PTC aggressiveness. Interestingly, NOX4 was highly expressed in non-malignant thyroid diseases with different subcellular localizations.

Keywords:

papillary thyroid carcinomas; BRAF^V600E hot spot mutation; NADPH oxidase NOX4; biomarker

Graphical Abstract

1. Introduction

Thyroid cancer is the most common endocrine disease, and papillary thyroid carcinomas (PTC) are the most frequent forms of thyroid cancer from the follicular origin (78–90%), followed by follicular thyroid carcinomas (FTC) and anaplastic thyroid carcinomas (ATC) [1,2,3]. An alarming worldwide increase in PTC incidence has been reported, and the molecular/histological heterogeneity of PTC complicates their management from both diagnostic and prognostic perspectives [2,4,5,6,7,8,9]. The BRAF^V600E mutation is detected in 28–90% of PTC tumors, indicating that this driver mutation is a common event in these tumors [1,3,10,11,12,13,14,15,16].

BRAF^V600E is a potent activator of the MAPK pathway and is often associated with aggressiveness, metastasis, radioiodine refractoriness, and mortality in thyroid cancer [13,15,16,17,18]. BRAF^V600E is exclusively detected in PTC (mainly in classical PTC ‘C-PTC’ and rarely in the follicular variant of PTC ‘F-PTC’) and ATC, but never in FTC and rarely in benign thyroid adenomas [2,19,20]. BRAF^V600E is useful as a prognostic and predictive biomarker in managing thyroid cancer. Regarding 10-year survival, PTC and FTC have survival rates of about 90–98%, whereas poorly differentiated thyroid carcinomas (PDTC) and ATC have survival rates of 50% and <10%, respectively [1]. Interestingly, high-grade tumors (PDTC and ATC) can arise from PTC and FTC through progressive genetic alterations and dedifferentiation [1,21], suggesting that thyroid tumor dedifferentiation can occur independently of the BRAF^V600E mutation because FTC is always BRAF^wt. In addition, the absence of a positive correlation between the BRAF^V600E mutation and thyroid tumor aggressiveness was reported [22,23,24,25]. An interesting classification of PTC has been proposed that groups PTC tumors independently of their molecular signature. PTC-BRAF^V600E-like tumors, including PTC-BRAF^V600E and PTC-BRAF^wt, share higher transcriptional MAPK pathway activity and higher dedifferentiation [7,26]. Consequently, exploring additional biomarkers other than BRAF^V600E could improve the management of PTC patients.

Reactive oxygen species (ROS) have been suspected of being involved in thyroid tumorigenesis for several years, and the role of ROS-generating NADPH oxidases has been analyzed in thyroid carcinomas [17,27,28]. Weyemi U et al. observed that NADPH oxidase 4 (NOX4) protein is overexpressed in thyroid cancer tissue (11 PTC) compared to normal adjacent tissue (eight NAT) [27]. Azouzi N et al. established a positive link between BRAF^V600E and NOX4 expression (at the mRNA level) by exploring about 500 PTC (BRAF^V600E versus BRAF^wt) from the TCGA database ‘Genome Atlas’ [17]. This study explored NOX4 expression at the protein level in 134 thyroid tissues (48 malignant tissues, 46 normal tissues surrounding the tumors, and 40 non-malignant tissues). Our results showed that the NOX4 protein score is higher in PTC, and we strengthened the link between NOX4 protein expression and BRAF^V600E mutation in PTC. Interestingly, and unlike the mutational status of BRAF, NOX4 expression is higher in C-PTC infiltrating tumors, highlighting a potential role of NOX4 as a marker of aggressiveness in PTC. Finally, we observed an overexpression of NOX4 in non-malignant diseases with different subcellular localization.

2. Materials and Methods

This study was approved by the Ethics Committee for Biomedical Research (CERB) of the Faculty of Medicine and Pharmacy in Rabat, with approval number 52/20.

2.1. Study Subjects

In this retrospective study, we collected 134 FFPE thyroid tissues from patients diagnosed at the Department of Anatomical Pathology in Military Hospital of Instruction Mohammed V in Rabat (HMIMV-R) between January 2015 and December 2021. Our cohort included 46 NAT, 28 classical forms of papillary thyroid carcinomas (C-PTC), 17 follicular variants of papillary thyroid carcinomas (F-PTC), three ATC, and 40 non-malignant thyroid tissues (including six lymphocytic thyroiditis, four Graves’ disease, ten goiters, and 20 hyperplasias). Malignant and non-malignant thyroid tissues were histologically classified according to the World Health Organization (WHO) classification (Lloyd R.V. et al., 4th Edition, IARC: Lyon 2017) by an experienced anatomopathologist at the time of diagnosis. In addition, retrospective diagnosis confirmation was performed by experienced anatomopathologists from both HMIMV in Rabat (Morocco) and Gustave Roussy Cancer Institute (France). FFPE block selection was based on (1) cell sufficiency (more than 90% of tumor cells in thyroid tumors/absence of tumor cells in non-tumoral tissues) and (2) FFPE block availability.

The collected information from the medical files of the selected patients constituted a database for this study, providing all clinicopathological features of the patients.

2.2. NOX4 Immunohistochemistry Staining

Immunohistochemical staining of NOX4 was performed using rabbit polyclonal anti-NOX4 (ab154244, Abcam, Cambridge, United Kingdom), and Dako EnVision™ FLEX High pH ‘LINK’/FLEX IHC Microscope Slides (Agilent, Santa Clara, California, United States) in an automaton (Autostainer Link 48; Agilent) according to the manufacturer’s protocols. These antibodies (Abs), whose immunogen corresponds to human NOX4 (aa 252–564), are suitable for IHC staining of FFPE tissue (IHC-P). The validation of NOX4 staining was performed after testing several Ab dilutions (1:250, 1:500, 1:750 in EnVision™ FLEX Antibody Diluent) on normal human kidney tissue (FFPE Block) (Supplementary Figure S2). Counterstaining was performed by hematoxylin ‘EnVision™ FLEX Hematoxylin’. Immunostaining of thyroid tissue without NOX4 Ab served as a negative control.

An experienced anatomopathologist from HMIMV in Rabat and Gustave Roussy Cancer Institute (France) assigned two scores to NOX4 protein expression. A score <2 corresponds to an absence or low expression of NOX4 protein, and a score ≥2 corresponds to a medium or high expression of NOX4 protein. As usually used by trained pathologist, the score of the staining intensity could be negative (0), weak (1), moderate (2), and strong (3) [29]. For our study, we classified scores <2 (including 0 and 1) and ≥2 (including 2 and 3).

In addition, the subcellular localization of NOX4 was noted. Slides were scanned with a NanoZoomer HT C9600 (Hamamatsu Photonics KK, Hamamatsu, Japan) digital scanner, using a ×40 objective. Scanned slides were uploaded on the CaloPix database (Tribvn Healthcare, Chatillon, France).

2.3. Mutational Analysis

BRAF^V600E hotspot mutation was analyzed in 48 malignant thyroid tissues, including 28 C-PTCs, 17 F-PTCs, and three ATCs, using Sanger direct sequencing and digital droplet PCR after genomic DNA extraction.

The genomic DNA extraction was performed in 8 sections of 10 μm each, according to the manufacturer’s ‘QIAamp DNA FFPE Tissue Kit (Qiagen)’ protocol, specially designed for purifying DNA from FFPE tissue sections. The quality and concentration of the extracted DNA were determined using the IMPLEN NanoPhotometer N60.

After genomic DNA extraction, PCRs were conducted using the HotStart Taq polymerase (Qiagen) with the following conditions: 95 °C for 15 min, followed by 42 cycles of 95 °C for 30 s, 53 °C for 30 s, and 72 °C for 45 s, and a final extension cycle of 72 °C for 10 min, all carried out in the Thermal Cycler (ProFlex PCR System; Thermo Fisher, Waltham, MA, USA). The forward and reverse primers for BRAF Exon 15 were (F) 5′-TCA TAA TGC TTG CTC TGA TAG GA-3′ and (R) 5′-GGC CAA AAA TTT AAT CAG TGG A-3′. The positive PCR products for BRAF^V600E, obtained after migration in 1.5% agarose gel electrophoresis, were purified using Exo-SAP before being bidirectionally sequenced with the Big Dye Terminator sequencing kit (Applied Biosystems, Foster City, CA, USA) at the UATRS Platform, CNRST, Rabat, Morocco. DNA sequences were analyzed with the SeqScape 2.7 software (Applied Biosystems, Waltham, MA, USA).

For digital droplet PCR, genomic DNA was extracted using the ‘Maxwell^® RSC DNA FFPE Kit’ from Promega/‘Maxwell^® RSC Instruments (Cat.# AS4500, AS8500)’ according to the manufacturer’s protocols (ASB1450). The extracted genomic DNA was sequenced using Droplet Digital PCR ‘ddPCR’ at the platform of molecular medicine in Gustave Roussy institute by determining the copy number of BRAF^V600E and BRAF^wt in each sample.

2.4. Statistical Analysis

All statistical analyses were performed using GraphPad Prism 8. Fisher’s exact and chi-square tests examined the associations between clinicopathological variables, BRAF^V600E, NOX4 protein expression, and NOX4 protein localization. A p-value of <0.05 was considered statistically significant for all analyses.

3. Results

3.1. Clinicopathological Characteristics of Patients

The analysis of the clinicopathologic data of our cohort revealed a female predominance (81%) (Table 1). The median age at diagnosis was 42.5 years, with a standard error of 2.4 years. Histologically, PTC comprise several histological subtypes (variants) that share specific nuclear features of PTC. We observed that C-PTC constituted the most frequent histological subtype (58.33%), followed by F-PTC (35.41%) and finally ATCs (6.26%) (Table 1). Based on aggressive features, we found that most thyroid cancers presented with a tumor size greater than 1 cm, while we noted the presence of vascular emboli in 15% of cases, capsular breach in 23% of cases, and lymph node metastases in 6.3% of cases (Table 1).

3.2. Clinicopathological Parameters of Each Histological Subtype of Thyroid Carcinomas

The comparative analysis between the histological type of 48 thyroid carcinomas (45 PTCs and three ATCs) and their clinicopathological characteristics revealed that 46.4% of C-PTC occurs in individuals aged ≥45 years old. However, 52.9% of F-PTCs occur in individuals aged <45 years old, while 66.7% of ATCs occur in individuals aged >45 years old (see Table 2). Regarding tumor size, we observed that most PTC tumors were >1 cm (64.3% for C-PTCs and 70.6% for F-PTC). As for vascular emboli and capsular breach, we found them, respectively, in 33.3% and 0% of ATCs, 17.9% and 32.1% of C-PTC, and 5.9% and 11.8% of F-PTC (see Table 2). However, we detected lymph node metastasis only in the classical form of PTC (10.7%) (Table 2).

3.3. BRAF^V600E Mutation in Thyroid Carcinomas

We analyzed the mutational profile of 48 thyroid carcinomas (45 PTC = 28 C-PTC + 17 F-PTC and three ATC) regarding the BRAF^V600E hotspot mutation using Sanger direct sequencing and digital droplet PCR (ddPCR). The mutational profiles of 41 samples (BRAF^V600E or BRAF^wt) were detected by Sanger direct sequencing, while ddPCR explored 7 samples. Genomic DNA extracted from FFPE block tissues is known to be extensively fragmented [30,31,32]. Therefore, seven samples whose results were not exploitable by Sanger direct sequencing were analyzed by ddPCR. (Figure S1 Supplementary Materials) shows an example of electropherogram sequences (Figure S1a Supplementary Materials) and an example of results from ddPCR (Figure S1b Supplementary Materials) for BRAF^V600E mutation in C-PTC and BRAF^wt in F-PTC. In this study, BRAF^V600E mutation was found exclusively in the classical form of PTC (10 C-PTC-BRAF^V600E/28 C-PTC: 35.7%), while no mutation was detected in the follicular variant of PTC and ATC (see Figure 1). This percentage is about 20.83% in all thyroid carcinomas (10 C-PTC-BRAF^V600E/48; 48 = 28 C-PTC + 17 F-PTC + 3 ATC) and 22.22% in all papillary thyroid carcinomas (ten C-PTC-BRAF^V600E/45; 45 = 28 C-PTC + 17 F-PTC). Finally, we did not observe any statistically significant association between BRAF^V600E mutation and the aggressiveness of thyroid carcinomas (see Table 3).

3.4. NOX4 Protein Expression in Human Malignant Thyroid Tissues

The antibody specificity and dilution choice (1:250) were validated in human kidney tissues (Figure S2) known to express NOX4 protein [33]. NOX4 protein expression was analyzed by immunohistochemistry staining in thyroid tumor tissues and their paired NAT (Figure 2a). Our results showed that 92.8% of C-PTC, 52.9% of F-PTC, and 33.3% of ATC express high levels of NOX4 protein (score ≥ 2) (see Figure 2b). No high NOX4 protein expression was observed in normal adjacent tissues (see Figure 2b). Notably, most FFPE thyroid tumor blocks contain both tumor areas and their normal adjacent tissues NAT (42/46 NAT), enabling us to immunostain both tumor and normal adjacent tissues on the same slide (see Figure 2a). Importantly, all thyroid tumors (BRAF^V600E) overexpressed NOX4 protein (100%: 10 C-PTC/10-C-PTC), highlighting the positive correlation between BRAF^V600E mutation and NOX4 protein expression in PTC (p-value < 0.0001) (see Figure 2c). However, a non-negligible percentage of BRAF^wt thyroid tumors (68.4%: 26/38) also exhibited a high level of NOX4 expression (see Figure 2c).

To investigate the involvement of NOX4 protein in thyroid tumor aggressiveness, we observed a statistically significant correlation between the overexpression of NOX4 protein and the presence of a capsular breach, indicating the association of NOX4 protein with the aggressiveness of thyroid carcinomas in our cohort (p-value = 0.0481) (see Table 4). Additionally, we evaluated NOX4 protein expression in infiltrating PTC tumors, characterized by the infiltration of tumor borders and consequently presenting a risk of metastasis initiation. We found that the majority of PTC infiltrating tumors exhibited a high level of NOX4 protein expression (83.3%: score ≥2 for all PTC and 90% for C-PTC: score ≥ 2) (see Figure 3a,b), highlighting a potential role of NOX4 protein in PTC aggressiveness. However, only 40% of infiltrating tumors (C-PTC) were BRAF^V600E positive (see Figure 3c), while all these tumors overexpressed NOX4 (100% of C-PTC BRAF^V600E: score ≥ 2) (see Figure 3d). Additionally, 83.3% of infiltrating C-PTC (BRAF^wt) overexpressed NOX4 protein independently of the presence of the BRAF^V600E mutation (Figure 3d) (Fisher’s test: p ≥ 0.999 for BRAF^wt infiltrating C-PTC versus BRAF^V600E infiltrating C-PTC).

3.5. NOX4 Protein Expression and Subcellular Localization in Non-Malignant Human Thyroid Tissues

We explored 40 non-malignant human thyroid disease tissues (six lymphocytic thyroiditis, four Graves’ disease, ten goiters, and 20 hyperplasias) and observed that the protein level of NOX4 was higher in Graves’ disease (100%: 4/4), goiters (80%: 8/10), and hyperplasias (70%: 14/20) (Figure 4a). Interestingly, we observed a different subcellular localization of NOX4 in non-malignant human thyroid tissues compared to malignant thyroid tissues (Figure 4c,d). NOX4 immunostaining revealed a perinuclear and cytoplasmic (intracellular) localization in both malignant thyroid tissues (100%: 48/48) and their normal adjacent tissues (100%: 46/46) (see Figure 4c). However, NOX4 localization was different in non-malignant thyroid tissues, being exclusively intracellular in both lymphocytic thyroiditis (100%: 6/6) and Graves’ disease (100%: 4/4), nuclear and intracellular in goiters (100%: 10/10), and at different localizations in hyperplasias: intracellular (15%: 3/20), nuclear (35%: 7/20), and intracellular and nuclear (50%: 10/20) (Figure 4b).

4. Discussion

PTC is a heterogeneous group of thyroid cancer, and its molecular and histological diversity constitute a real challenge for managing these tumors. Molecular exploration of new and/or complementary biomarkers could improve the management of PTC patients. ROS are involved in both physiological and pathological processes in the thyroid, and human cells can produce ROS through various enzymes, including NADPH oxidases (NOX1, NOX2, NOX3, NOX4, NOX5, DUOX1, and DUOX2). Thyrocytes express three NADPH oxidases (DUOX1, DUOX2, and NOX4) with different subcellular localizations and functions. In the thyroid gland, DUOX2 contributes mainly to thyroid hormone synthesis by providing H₂O₂ to thyroid peroxidase (TPO), while ROS-generating NADPH oxidases DUOX1 and NOX4 are associated with oxidative DNA damage that could promote thyroid radio-carcinogenesis and oncogenes thyroid cancer dedifferentiation, respectively [17,27,33,34,35].

Importantly, unlike the other NADPH oxidases, the level of NOX4 protein is directly related to the level of ROS generation. Therefore, a high level of NOX4 may promote oxidative DNA damage and genomic instability in thyroid cells [33]. In this study, we analyzed NOX4 expression at the protein level by immunostaining in 134 thyroid tissues (48 thyroid carcinomas, 46 normal adjacent tissues, and 40 non-malignant thyroid tissues) to improve our understanding of the potential role of NOX4 as a predictive marker of aggressiveness in PTC. Overall, we observed a high level of NOX4 protein in thyroid cancer tissues compared to normal adjacent tissues (92.9% of C-PTC, 52.9% of F-PTC, and 33.3% of ATC and 0% of NAT), which is consistent with previous reports with fewer tissues [28,36] (Figure 2b).

We previously showed a positive correlation between NOX4 mRNA and BRAF^V600E mutation in about 500 PTC from TCGA data [17], but this has not been established at the protein level in thyroid cancer tissues. In this study, all PTC-BRAF^V600E overexpressed NOX4 protein (Figure 2c). However, 68.4% of PTC-BRAF^wt also showed a high score of NOX4 protein (Figure 2c), emphasizing that NOX4 expression could be upregulated in thyroid cancer independently of BRAF mutational status. The TGF-β pathway plays a key role in thyroid tumorigenesis. The oncogenic effect of BRAF^V600E in thyroid cells was shown to be mediated in part by TGF-β [37], and NOX4 is upregulated in thyroid cancer cells under the control of the BRAF^V600E-TGF-β axis [17]. The tumor microenvironment, including cancer-associated fibroblasts (CAF) and myeloid cells such as macrophages, also produces TGF-β [38]. Therefore, the microenvironment may contribute to inducing NOX4 in tumoral cells.

To establish the link between NOX4 protein and the infiltrating ability of PTC, we explored the presence or absence of a frank capsular breach, as its presence indicates the ability of tumors to extend/invade and promote extrathyroidal extension. More than 90% of C-PTC infiltrating tumors overexpressed NOX4 protein (score ≥ 2), suggesting a role of NOX4 in thyroid tumor aggressiveness (Figure 3).

Certainly, the expression level of NOX4 protein in terms of ROS production can be related to the incidence of oxidative DNA damage in thyrocytes. Therefore, the cellular localization of NOX4 appears to be of great interest. Indeed, the nuclear and perinuclear localization of ROS-generating NOX4 can promote genomic instability associated with thyrocyte transformation. The perinuclear localization of NOX4 observed in malignant human thyroid tissues (Figure 4) is concordant with this, as genomic instability is a characteristic of malignant tumors. Interestingly, goiter and hyperplasia tissues with a high score of NOX4 protein also showed nuclear and perinuclear localization (Figure 4), questioning the potential role of NOX4 in the progression of these non-malignant diseases to thyroid cancer. Indeed, a high risk of cancer was reported in goiters (18%) [39], and thyroid hyperplasia is reported as the most frequent benign disease associated with PTC [40]. Graves’ disease also shows a high level of NOX4 protein (Figure 4a), and this result can be explained by the constitutive activation of the TSH receptor (stimulating antibody, mutations) in Graves’ disease tissue [41]. The upregulation of NOX4 by TSH has previously been reported [27].

5. Conclusions

Taken together, the main conclusion of our study is that NOX4 expression could be a potential co-marker of thyroid cancer aggressiveness. However, complementary studies are needed to explore this possibility further. Indeed, BRAF^V600E mutation is not often associated with thyroid aggressiveness [22,23,24,25]. Several isoforms of NOX4 exist (from GenCards and Aceview), and an antibody recognizing the conserved catalytic core of NOX4 cannot discriminate between the different isoforms in thyroid tissues. Therefore, identifying NOX4 isoforms associated with different diseases may improve diagnosis and/or prognosis.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/cimb45070367/s1, Figure S1: An example of electropherogram sequences (Figure S1a) and an example of results from ddPCR (Figure S1b) for BRAF^V600E mutation in C-PTC and BRAF^wt in F-PTC. Figure S2: NOX4 Immunoexpression in normal kidney cells. Validation of anti-NOX4 antibody (ab154244) using different dilutions test (1:250,1:500 and 1:750).

Author Contributions

Conceptualization, R.A.E.H.; methodology, S.F., Y.O., M.O. and A.A.; software, S.F. and Y.O.; validation, S.F., Y.O., H.C., A.D. and A.L.; formal analysis, Y.B., N.D., M.O., C.D. and R.A.E.H.; investigation, R.A.E.H., Y.B., M.O. and C.D.; resources, R.A.E.H. and M.O.; data curation, S.F. and Y.O.; writing—original draft preparation, R.A.E.H., S.F. and Y.O.; writing—review and editing, R.A.E.H., C.D., Y.B., M.O., S.F. and Y.O.; visualization, R.A.E.H.; supervision, R.A.E.H., C.D., Y.B., N.D. and M.O.; project administration, R.A.E.H.; funding acquisition, R.A.E.H., C.D. and Y.B. All authors have read and agreed to the published version of the manuscript.

Funding

Research funded by (1) Cancer Research Institute (IRC). www.irc.ma; Project: 767/AAmP2019. (2) PHC TOUBKAL N° TBK/20/113 N°CAMPUS: 43586YA (Maroc/France) (2020-2022); (3) Agence Nationale Des Plantes Médicinales Et Aromatiques (ANPMA’); and (4) doctoral scholarship to S. FENNICHE from CNRST, Maroc (Bourse d’excellence); (5): Publication fees supported by the “Cancer Research Institute IRC”, Kingdom of Morocco. www.irc.ma.

Institutional Review Board Statement

This study was approved by the Ethics Committee for Biomedical Research (CERB) of the Faculty of Medicine and Pharmacy in Rabat, with approval number 52/20.

Informed Consent Statement

Not applicable.

Data Availability Statement

Archived datasets are not available due to the ethic restriction.

Acknowledgments

We thank Abderrahmane Al Bouzidi for his constructive contribution at the initiation of this research work.

Conflicts of Interest

The authors declare no conflict of interest.

References

Nikiforov, Y.E.; Nikiforova, M.N. Molecular Genetics and Diagnosis of Thyroid Cancer. Nat. Rev. Endocrinol. 2011, 7, 569–580. [Google Scholar] [CrossRef] [PubMed]
Hu, J.; Yuan, I.J.; Mirshahidi, S.; Simental, A.; Lee, S.C.; Yuan, X. Thyroid Carcinoma: Phenotypic Features, Underlying Biology and Potential Relevance for Targeting Therapy. Int. J. Mol. Sci. 2021, 22, 1950. [Google Scholar] [CrossRef] [PubMed]
Kaabouch, M.; Chahdi, H.; Azouzi, N.; Oukabli, M.; Rharrassi, I.; Boudhas, A.; Jaddi, H.; Ababou, M.; Dakka, N.; Boichard, A.; et al. BRAFV600E Hot Spot Mutation in Thyroid Carcinomas: First Moroccan Experience from a Single-Institution Retrospective Study. Afr. Health Sci. 2020, 20, 1849–1856. [Google Scholar] [CrossRef] [PubMed]
Agarwal, S.; Bychkov, A.; Jung, C.-K. Emerging Biomarkers in Thyroid Practice and Research. Cancers 2021, 14, 204. [Google Scholar] [CrossRef]
Aschebrook-Kilfoy, B.; Schechter, R.B.; Shih, Y.-C.T.; Kaplan, E.L.; Chiu, B.C.H.; Angelos, P.; Grogan, R.H. The Clinical and Economic Burden of a Sustained Increase in Thyroid Cancer Incidence. Cancer Epidemiol. Biomark. Prev. 2013, 22, 1252–1259. [Google Scholar] [CrossRef]
Kilfoy, B.A.; Zheng, T.; Holford, T.R.; Han, X.; Ward, M.H.; Sjodin, A.; Zhang, Y.; Bai, Y.; Zhu, C.; Guo, G.L.; et al. International Patterns and Trends in Thyroid Cancer Incidence, 1973–2002. Cancer Causes Control 2009, 20, 525–531. [Google Scholar] [CrossRef]
Agrawal, N.; Akbani, R.; Aksoy, B.A.; Ally, A.; Arachchi, H.; Asa, S.L.; Auman, J.T.; Balasundaram, M.; Balu, S.; Baylin, S.B.; et al. Integrated Genomic Characterization of Papillary Thyroid Carcinoma. Cell 2014, 159, 676–690. [Google Scholar] [CrossRef]
Giordano, T.J. Follicular Cell Thyroid Neoplasia: Insights from Genomics and The Cancer Genome Atlas Research Network. Curr. Opin. Oncol. 2016, 28, 1–4. [Google Scholar] [CrossRef]
Jung, C.K.; Little, M.P.; Lubin, J.H.; Brenner, A.V.; Wells, S.A.; Sigurdson, A.J.; Nikiforov, Y.E. The Increase in Thyroid Cancer Incidence during the Last Four Decades Is Accompanied by a High Frequency of BRAF Mutations and a Sharp Increase in RAS Mutations. J. Clin. Endocrinol. Metab. 2014, 99, E276–E285. [Google Scholar] [CrossRef]
Newfield, R.S.; Jiang, W.; Sugganth, D.X.; Hantash, F.M.; Lee, E.; Newbury, R.O. Mutational Analysis Using Next Generation Sequencing in Pediatric Thyroid Cancer Reveals BRAF and Fusion Oncogenes Are Common. Int. J. Pediatr. Otorhinolaryngol. 2022, 157, 111121. [Google Scholar] [CrossRef]
Nikita, M.E.; Jiang, W.; Cheng, S.-M.; Hantash, F.M.; McPhaul, M.J.; Newbury, R.O.; Phillips, S.A.; Reitz, R.E.; Waldman, F.M.; Newfield, R.S. Mutational Analysis in Pediatric Thyroid Cancer and Correlations with Age, Ethnicity, and Clinical Presentation. Thyroid 2016, 26, 227–234. [Google Scholar] [CrossRef]
Pérez-Fernández, L.; Sastre, J.; Zafón, C.; Oleaga, A.; Castelblanco, E.; Capel, I.; Galofré, J.C.; Guadalix-Iglesias, S.; De la Vieja, A.; Riesco-Eizaguirre, G. Validation of Dynamic Risk Stratification and Impact of BRAF in Risk Assessment of Thyroid Cancer, a Nation-Wide Multicenter Study. Front. Endocrinol. 2023, 13, 1071775. [Google Scholar] [CrossRef]
Kebebew, E.; Weng, J.; Bauer, J.; Ranvier, G.; Clark, O.H.; Duh, Q.-Y.; Shibru, D.; Bastian, B.; Griffin, A. The Prevalence and Prognostic Value of BRAF Mutation in Thyroid Cancer. Ann. Surg. 2007, 246, 466–471. [Google Scholar] [CrossRef]
Kimura, E.T.; Nikiforova, M.N.; Zhu, Z.; Knauf, J.A.; Nikiforov, Y.E.; Fagin, J.A. High Prevalence of BRAF Mutations in Thyroid Cancer: Genetic Evidence for Constitutive Activation of the RET/PTC-RAS-BRAF Signaling Pathway in Papillary Thyroid Carcinoma. Cancer Res. 2003, 63, 1454–1457. [Google Scholar]
Xing, M.; Alzahrani, A.S.; Carson, K.A.; Viola, D.; Elisei, R.; Bendlova, B.; Yip, L.; Mian, C.; Vianello, F.; Tuttle, R.M.; et al. Association Between BRAF V600E Mutation and Mortality in Patients with Papillary Thyroid Cancer. JAMA 2013, 309, 1493. [Google Scholar] [CrossRef]
Ulisse, S.; Baldini, E.; Lauro, A.; Pironi, D.; Tripodi, D.; Lori, E.; Ferent, I.C.; Amabile, M.I.; Catania, A.; Di Matteo, F.M.; et al. Papillary Thyroid Cancer Prognosis: An Evolving Field. Cancers 2021, 13, 5567. [Google Scholar] [CrossRef]
Azouzi, N.; Cailloux, J.; Cazarin, J.M.; Knauf, J.A.; Cracchiolo, J.; Al Ghuzlan, A.; Hartl, D.; Polak, M.; Carré, A.; El Mzibri, M.; et al. NADPH Oxidase NOX4 Is a Critical Mediator of BRAF V600E—Induced Downregulation of the Sodium/Iodide Symporter in Papillary Thyroid Carcinomas. Antioxid. Redox Signal. 2017, 26, 864–877. [Google Scholar] [CrossRef]
Ieni, A.; Vita, R.; Pizzimenti, C.; Benvenga, S.; Tuccari, G. Intratumoral Heterogeneity in Differentiated Thyroid Tumors: An Intriguing Reappraisal in the Era of Personalized Medicine. J. Pers. Med. 2021, 11, 333. [Google Scholar] [CrossRef]
Bangaraiahgari, R.; Panchangam, R.B.; Puthenveetil, P.; Mayilvaganan, S.; Bangaraiahgari, R.; Reddy Banala, R.; Karunakaran, P.; Md, R. Is There Adenoma-Carcinoma Sequence between Benign Adenoma and Papillary Cancer of Thyroid: A Genomic Linkage Study. Ann. Med. Surg. 2020, 60, 695–700. [Google Scholar] [CrossRef]
Park, J.Y.; Kim, W.Y.; Hwang, T.S.; Lee, S.S.; Kim, H.; Han, H.S.; Lim, S.D.; Kim, W.S.; Yoo, Y.B.; Park, K.S. BRAF and RAS Mutations in Follicular Variants of Papillary Thyroid Carcinoma. Endocr. Pathol. 2013, 24, 69–76. [Google Scholar] [CrossRef]
Baloch, Z.W.; Asa, S.L.; Barletta, J.A.; Ghossein, R.A.; Juhlin, C.C.; Jung, C.K.; LiVolsi, V.A.; Papotti, M.G.; Sobrinho-Simões, M.; Tallini, G.; et al. Overview of the 2022 WHO Classification of Thyroid Neoplasms. Endocr. Pathol. 2022, 33, 27–63. [Google Scholar] [CrossRef] [PubMed]
Ito, Y.; Yoshida, H.; Maruo, R.; Morita, S.; Takano, T.; Hirokawa, M.; Yabuta, T.; Fukushima, M.; Inoue, H.; Tomoda, C.; et al. BRAF Mutation in Papillary Thyroid Carcinoma in a Japanese Population: Its Lack of Correlation with High-Risk Clinicopathological Features and Disease-Free Survival of Patients. Endocr. J. 2009, 56, 89–97. [Google Scholar] [CrossRef] [PubMed]
Trovisco, V.; Soares, P.; Preto, A.; De Castro, I.V.; Lima, J.; Castro, P.; Máximo, V.; Botelho, T.; Moreira, S.; Meireles, A.M.; et al. Type and Prevalence of BRAF Mutations Are Closely Associated with Papillary Thyroid Carcinoma Histotype and Patients’ Age but Not with Tumour Aggressiveness. Virchows Arch. 2005, 446, 589–595. [Google Scholar] [CrossRef] [PubMed]
Barbaro, D.; Incensati, R.M.; Materazzi, G.; Boni, G.; Grosso, M.; Panicucci, E.; Lapi, P.; Pasquini, C.; Miccoli, P. The BRAF V600E Mutation in Papillary Thyroid Cancer with Positive or Suspected Pre-Surgical Cytological Finding Is Not Associated with Advanced Stages or Worse Prognosis. Endocrine 2014, 45, 462–468. [Google Scholar] [CrossRef]
Gandolfi, G.; Sancisi, V.; Torricelli, F.; Ragazzi, M.; Frasoldati, A.; Piana, S.; Ciarrocchi, A. Allele Percentage of the BRAF V600E Mutation in Papillary Thyroid Carcinomas and Corresponding Lymph Node Metastases: No Evidence for a Role in Tumor Progression. J. Clin. Endocrinol. Metab. 2013, 98, E934–E942. [Google Scholar] [CrossRef]
Landa, I.; Ibrahimpasic, T.; Boucai, L.; Sinha, R.; Knauf, J.A.; Shah, R.H.; Dogan, S.; Ricarte-Filho, J.C.; Krishnamoorthy, G.P.; Xu, B.; et al. Genomic and Transcriptomic Hallmarks of Poorly Differentiated and Anaplastic Thyroid Cancers. J. Clin. Investig. 2016, 126, 1052–1066. [Google Scholar] [CrossRef]
Weyemi, U.; Caillou, B.; Talbot, M.; Ameziane-El-Hassani, R.; Lacroix, L.; Lagent-Chevallier, O.; Al Ghuzlan, A.; Roos, D.; Bidart, J.-M.; Virion, A.; et al. Intracellular Expression of Reactive Oxygen Species-Generating NADPH Oxidase NOX4 in Normal and Cancer Thyroid Tissues. Endocr. Relat. Cancer 2010, 17, 27–37. [Google Scholar] [CrossRef]
Muzza, M.; Pogliaghi, G.; Colombo, C.; Carbone, E.; Cirello, V.; Palazzo, S.; Frattini, F.; Gentilini, D.; Gazzano, G.; Persani, L.; et al. Oxidative Stress Correlates with More Aggressive Features in Thyroid Cancer. Cancers 2022, 14, 5857. [Google Scholar] [CrossRef]
Cizkova, K.; Foltynkova, T.; Gachechiladze, M.; Tauber, Z. Comparative Analysis of Immunohistochemical Staining Intensity Determined by Light Microscopy, ImageJ and QuPath in Placental Hofbauer Cells. Acta Histochem. Cytochem. 2021, 54, 21–29. [Google Scholar] [CrossRef]
Ofner, R.; Ritter, C.; Ugurel, S.; Cerroni, L.; Stiller, M.; Bogenrieder, T.; Solca, F.; Schrama, D.; Becker, J.C. Non-Reproducible Sequence Artifacts in FFPE Tissue: An Experience Report. J. Cancer Res. Clin. Oncol. 2017, 143, 1199–1207. [Google Scholar] [CrossRef]
Wong, S.Q.; Li, J.; Tan, A.Y.C.; Vedururu, R.; Pang, J.M.B.; Do, H.; Ellul, J.; Doig, K.; Bell, A.; Macarthur, G.A.; et al. Sequence Artefacts in a Prospective Series of Formalin-Fixed Tumours Tested for Mutations in Hotspot Regions by Massively Parallel Sequencing. BMC Med. Genom. 2014, 7, 23. [Google Scholar] [CrossRef]
Cazzato, G.; Caporusso, C.; Arezzo, F.; Cimmino, A.; Colagrande, A.; Loizzi, V.; Cormio, G.; Lettini, T.; Maiorano, E.; Scarcella, V.; et al. Formalin-Fixed and Paraffin-Embedded Samples for Next Generation Sequencing: Problems and Solutions. Genes 2021, 12, 1472. [Google Scholar] [CrossRef]
Ameziane-El-Hassani, R.; Schlumberger, M.; Dupuy, C. NADPH Oxidases: New Actors in Thyroid Cancer? Nat. Rev. Endocrinol. 2016, 12, 485–494. [Google Scholar] [CrossRef]
Ameziane El Hassani, R.; Buffet, C.; Leboulleux, S.; Dupuy, C. Oxidative Stress in Thyroid Carcinomas: Biological and Clinical Significance. Endocr. Relat. Cancer 2019, 26, R131–R143. [Google Scholar] [CrossRef]
Ameziane-El-Hassani, R.; Talbot, M.; de Souza Dos Santos, M.C.; Al Ghuzlan, A.; Hartl, D.; Bidart, J.-M.; De Deken, X.; Miot, F.; Diallo, I.; de Vathaire, F.; et al. NADPH Oxidase DUOX1 Promotes Long-Term Persistence of Oxidative Stress after an Exposure to Irradiation. Proc. Natl. Acad. Sci. USA 2015, 112, 5051–5056. [Google Scholar] [CrossRef]
Weyemi, U.; Lagente-Chevallier, O.; Boufraqech, M.; Prenois, F.; Courtin, F.; Caillou, B.; Talbot, M.; Dardalhon, M.; Al Ghuzlan, A.; Bidart, J.-M.; et al. ROS-Generating NADPH Oxidase NOX4 Is a Critical Mediator in Oncogenic H-Ras-Induced DNA Damage and Subsequent Senescence. Oncogene 2012, 31, 1117–1129. [Google Scholar] [CrossRef]
Riesco-Eizaguirre, G.; Rodríguez, I.; De la Vieja, A.; Costamagna, E.; Carrasco, N.; Nistal, M.; Santisteban, P. The BRAFV600E Oncogene Induces Transforming Growth Factor β Secretion Leading to Sodium Iodide Symporter Repression and Increased Malignancy in Thyroid Cancer. Cancer Res. 2009, 69, 8317–8325. [Google Scholar] [CrossRef]
Rabold, K.; Zoodsma, M.; Grondman, I.; Kuijpers, Y.; Bremmers, M.; Jaeger, M.; Zhang, B.; Hobo, W.; Bonenkamp, H.J.; de Wilt, J.H.W.; et al. Reprogramming of Myeloid Cells and Their Progenitors in Patients with Non-Medullary Thyroid Carcinoma. Nat. Commun. 2022, 13, 6149. [Google Scholar] [CrossRef]
Smith, J.J.; Chen, X.; Schneider, D.F.; Broome, J.T.; Sippel, R.S.; Chen, H.; Solórzano, C.C. Cancer after Thyroidectomy: A Multi-Institutional Experience with 1523 Patients. J. Am. Coll. Surg. 2013, 216, 571–577. [Google Scholar] [CrossRef]
de Carlos, J.; Ernaga, A.; Irigaray, A.; Pineda, J.J.; Echegoyen, A.; Salvador, P.; Anda, E. Incidentally Discovered Papillary Thyroid Microcarcinoma in Patients Undergoing Thyroid Surgery for Benign Disease. Endocrine 2022, 77, 325–332. [Google Scholar] [CrossRef]
Führer, D. Constitutive TSH Receptor Activation as a Hallmark of Thyroid Autonomy. Endocrine 2020, 68, 274–278. [Google Scholar] [CrossRef] [PubMed]

Figure 1. BRAF^V600E mutation in thyroid carcinomas. Association between BRAF^V600E mutation and histological type of thyroid carcinomas (n = 48). In total, 100% of thyroid carcinoma harboring BRAF^V600E are exclusively C-PTC. ATC: anaplastic thyroid carcinoma (n = 3). C-PTC: classical forms of papillary thyroid carcinoma (n = 28). F-PTC: follicular variants of papillary thyroid carcinoma (n = 17). BRAF^V600E (n = 10), BRAF^wt (n = 38). The statistical tests performed by GraphPad 8. * The statistical significance is affirmed by a p-value less than 0.05. *: p-value ≤ 0.05.

Figure 2. NOX4 protein expression in thyroid carcinomas. (a) Representative example of NOX4 protein expression in C-PTC. Red lines represent tumor tissue sections, and green lines represent normal adjacent tissue (NAT) sections on the same slide (×10). There is a high expression level of NOX4 protein in C-PTC and a low expression level of NOX4 in its adjacent normal tissue (NAT). (b) Comparative analysis of NOX4 protein expression in human thyroid tumors (n = 48:28 C-PTC, 17 F-PTC, 3 ATC) compared to their normal adjacent tissues (46 NAT). Percentage calculated according to the number of each score <2 and ≥2. The score <2 represents an absence or very low and low expression of NOX4 protein (n = 58). The score ≥2 represents a middle or/and high expression level of NOX4 protein (n = 36). (c) Association between BRAF^V600E mutation and NOX4 expression. In total, 100% of thyroid carcinoma harboring BRAF^V600E mutation showed high expression level of NOX4 protein. BRAF^V600E (n = 10), BRAF^wt (n = 38). The statistical tests are performed by GraphPad 8. * The statistical significance is affirmed by a p-value under 0.05. *: p-value ≤ 0.05, ****: p-value ≤ 0.0001.

Figure 3. Correlation of infiltrating character followed by the limitation of the border of the tumor with NOX4 protein expression and BRAF^V600E mutation in PTC (n = 21: 17 c-PTC, 4 F-PTC). (a) In total, 83% (10/12) of papillary thyroid carcinoma with an infiltrating character show overexpression of NOX4 protein (n = 12). (b) C-PTC: high expression of NOX4 protein in infiltrating tumors (n = 10) (90% (9/10)) with a score ≥2. (c) C-PTC: 40% (4/10) of papillary thyroid carcinoma with an infiltrating character harbor BRAF^V600E mutation. (d) In total, 100% of infiltrating C-PTC harboring BRAF^V600E mutation overexpress NOX4 protein. Percentage calculated according to the total number of infiltrating tumors of each histological type.

Figure 4. Immunohistochemical analysis of NOX4 protein expression and subcellular localization in thyroid carcinomas and non-malignant thyroid diseases. (a) NOX4 protein expression in 40 non-malignant thyroid diseases (six lymphocytic thyroiditis, four Graves’ disease, ten goiters, and 20 hyperplasias. (b) Subcellular localization of NOX4 protein in 40 non-malignant thyroid diseases (six lymphocytic thyroiditis, four Graves’ disease, ten goiters, and 20 hyperplasias). (c) Subcellular localization of NOX4 protein in 94 malignant thyroid tissues (28 c-PTC, 17 F-PTC, 3 ATC, and 46 NAT). The statistical tests performed by GraphPad 8. * The statistical significance is affirmed by a p-value less than 0.05. *: p-value ≤ 0.05, ****: p-value ≤ 0.0001.

Table 1. Clinicopathological parameters of patients with thyroid tumors (n = 48).

Clinicopathological Parameters	n (%)
Gender
Female	39 (81%)
Male	9 (19%)
Age
Median ± standard error	42.5 ± 2.4
Histological variant
C-PTC	28/48 (58.33%)
F-PTC	17/48 (35.41%)
ATC	3/48 (6.26%)
Tumor size
≤1 cm	7/48 (15%)
>1 cm	30/48 (63%)
unknown	11/48 (23%)
vascular emboli
Presence	7/48 (15%)
Absence	41/48 (85%)
Capsular breach
Presence	11/48 (23%)
Absence	37/48 (77%)
lymph node metastasis
Presence	3/48 (6.3%)
Absence	34/48 (70.8%)
Unknown	11/48 (22.9%)

PTC: papillary thyroid carcinomas, C-PTC: classical form of papillary thyroid carcinomas, F-PTC: follicular variants of papillary thyroid carcinomas, ATC: anaplastic thyroid carcinomas. Unknown: absence of this information in both registers and medical files.

Table 2. Clinicopathological parameters of each histological subtype of thyroid carcinomas (n = 48).

Clinicopathological Parameters	PTC (n = 45)	C-PTC (n = 28)	F-PTC (n = 17)	ATC (n = 3)	C-PTC-F-PTC Chi-Square/Fisher’s Exact Test (p-Value < 0.05)
Age					0.1516
<45	19/45 (42.2%)	10/28 (35.7%)	9/17 (52.9%)	1/3 (33.3%)
≥45	16/45 (35.6%)	13/28 (46.4%)	3/17 (17.7%)	2/3 (66.7%)
unknown	10/45 (22.2%)	5/28 (17.9%)	5/17 (29.4%)	-
Tumor size					>0.9999
≤1 cm	7/45 (15.6%)	4/28 (14.3%)	3/17 (17.6%)	-
>1 cm	30/45 (66.7%)	18/28 (64.3%)	12/17 (70.6%)	-
Unknown	8/45 (17.7%)	6/28 (21.4%)	2/17 (11.8%)	3 (100%)
vascular emboli					0.3846
Presence	6/45 (13.3%)	5/28 (17.9%)	1/17 (5.9%)	1/3 (33.3%)
Absence	39/45 (86.7%)	23/28 (82.1%)	16/17 (94.1%)	2/3 (66.7%)
Capsular breach					0.1647
Presence	11/45 (24.4%)	9/28 (32.1%)	2/17 (11.8%)	0 (0%)
Absence	34/45 (75.6%)	19/28 (67.9%)	15/17 (88.2%)	3/3 (100%)
lymph node metastasis					0.2432
Presence	3/45 (6.6%)	3/28 (10.7%)	0 (0%)	0 (0%)
Absence	34/45 (75.6%)	18/28 (64.2%)	16/17 (94.1%)	0 (0%)
Unknown	8/45 (17.8%)	7/28 (25%)	1/17 (5.9%)	3/3 (100%)

PTC: papillary thyroid carcinomas, C-PTC: classical form of papillary thyroid carcinomas, F-PTC: follicular variants of papillary thyroid carcinomas, ATC: anaplastic thyroid carcinomas. Unknown: absence of this information in both registers and medical files.

Table 3. BRAF^V600E mutation and C-PTC clinicopathological parameters (n = 28).

Clinicopathological Parameters	C-PTC BRAF^V600E (n = 10)	C-PTC BRAF^wt (n = 18)	Total	Chi-Square/Fisher’s Exact Test (p-Value < 0.05)
Tumor size				>0.9999
≤1 cm	1/10 (10%)	2/18 (11.1%)	3
>1 cm	7/10 (70%)	12/18 (66.7%)	19
unknown	2/10 (20%)	4/18 (22.2%)	6
lymph node metastasis				>0.9999
Presence	1/10 (10%)	2/18 (11.1%)	3
Absence	8/10 (80%)	10/18 (55.6%)	18
unknown	1/10 (10%)	6/18 (33.3%)	7
vascular emboli				0.8253
Presence	2/10 (20%)	3/18 (16.7%)	5
Absence	8/10 (80%)	15/18 (83.3%)	23
Capsular breach				0.5070
Presence	4/10 (40%)	5/18 (27.8%)	9
Absence	6/10 (60%)	13/18 (72.2%)	19

C-PTC: Classical form of papillary thyroid carcinomas. Unknown: absence of this information in both registers and medical files.

Table 4. NOX4 protein expression and clinicopathological parameters of thyroid tumors.

Clinicopathological Parameters	n (%)	NOX4 Overexpression (Score: ≥2)	NOX4 Low Expression (Score: <2)	Fisher’s Exact Test (p-Value < 0.05)
Gender				>0.9999
Female	39/48 (81%)	30/39 (76.9%)	9/39 (23.1%)
Male	9/48 (19%)	7/9 (77.8%)	2/9 (22.2%)
Histological variant				<0.0001
C-PTC	28/48 (58.33%)	26/28 (92.9%)	2/28 (7.1%)
F-PTC	17/48 (35.41%)	9/17 (52.9%)	8/17 (47.1%)
ATC	3/48 (6.26%)	1/3 (33.3%)	2/3 (66.7%)
Tumor size				0.3079
≤1 cm	7/48 (15%)	7/7 (100%)	0 (0%)
>1 cm	30/48 (63%)	22/30 (73.3%)	8/30 (26.7%)
unknown	11/48 (23%)	7/11 (63.4%)	4/11 (36.6%)
vascular emboli
Presence	7/48 (15%)	6/7 (85.7%)	1/7 (14.3%)
Absence	41/48 (85%)	30/41 (73.2%)	11/41 (26.8%)	0.6621
Capsular breach
Presence	11/48 (23%)	11/11 (100%)	0/11 (0%)
Absence	37/48 (77%)	25/37 (67.6%)	12/37 (32.4%)	0.0442
lymph node metastasis				0.5483
Presence	3/48 (6.3%)	3/3 (100%)	0/3 (0%)
Absence	34/48 (70.8%)	24/34 (70.6%)	10/34 (29.4%)
unknown	11/48 (22.9%)	9/11 (81.8%)	2/11 (18.2%)

PTC: papillary thyroid carcinomas, C-PTC: classical form of papillary thyroid carcinomas, F-PTC: follicular variant of papillary thyroid carcinomas, ATC: anaplastic thyroid carcinomas. NOX4: NADPH oxidase 4. Unknown: absence of this information in both registers and medical files.

Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

© 2023 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).

Share and Cite

MDPI and ACS Style

Fenniche, S.; Oukabli, M.; Oubaddou, Y.; Chahdi, H.; Damiri, A.; Alghuzlan, A.; Laraqui, A.; Dakka, N.; Bakri, Y.; Dupuy, C.; et al. A Comparative Analysis of NOX4 Protein Expression in Malignant and Non-Malignant Thyroid Tumors. Curr. Issues Mol. Biol. 2023, 45, 5811-5823. https://doi.org/10.3390/cimb45070367

AMA Style

Fenniche S, Oukabli M, Oubaddou Y, Chahdi H, Damiri A, Alghuzlan A, Laraqui A, Dakka N, Bakri Y, Dupuy C, et al. A Comparative Analysis of NOX4 Protein Expression in Malignant and Non-Malignant Thyroid Tumors. Current Issues in Molecular Biology. 2023; 45(7):5811-5823. https://doi.org/10.3390/cimb45070367

Chicago/Turabian Style

Fenniche, Salma, Mohamed Oukabli, Yassire Oubaddou, Hafsa Chahdi, Amal Damiri, Abir Alghuzlan, Abdelilah Laraqui, Nadia Dakka, Youssef Bakri, Corinne Dupuy, and et al. 2023. "A Comparative Analysis of NOX4 Protein Expression in Malignant and Non-Malignant Thyroid Tumors" Current Issues in Molecular Biology 45, no. 7: 5811-5823. https://doi.org/10.3390/cimb45070367

Article Menu

A Comparative Analysis of NOX4 Protein Expression in Malignant and Non-Malignant Thyroid Tumors

Abstract

1. Introduction