1. Background
It is known that the FAMILY WITH SEQUENCE SIMILARITY 83, MEMBER H (FAM83H; OMIM: *611927) is the first gene causing the etiology of Amelogenesis Imperfecta (AI) in humans ( 1 ). Interes-tingly, such genetic potentials of Fam83h regarding teeth and enamel development in humans have not been applicable uniformly in mice ( 2 , 3 ). Several studies have shown that mutations in Fam83h are related to Autosomal Dominant Hypocalcified Amelogenesis Imperfecta (ADHCAI, OMIM #130900) ( 4 ). While Fam83h Knockout (KO) mice are identified with their scruffy coat and short lifetime, however, there has been no phenotypic description of teeth formation and development in Fam83h KnockOut (KO) mice ( 2 ). Our previous studies delineated the Fam83h KO outbred mice with scruffy cover, dry eyes-like phenotype, normal life-span, and a specific dental phenotype similar to AI ( 3 ). As a non-secretory protein, FAM83H has a domain at its N-terminus that interacts with CK1. CK1 is a mediator of the Wnt/β-catenin pathway which plays an important role in mineralization and tooth growth ( 5 ). Mutations in the N-terminus of FAM83H lead to a non-proper subcellular localization and cellular functions of FAM83H and also, prevent binding to Casein kinase 1 (CK1) ( 6 ) (Snijders, Lee, et al. 2017). Furthermore, activation of the Wnt/β-catenin pathway has been reported to be associated with mutations in the Fam83h ( 7 ). In this regard, the expression levels of CK1a, CK1e, and β-catenin in Fam83h KO mice were evaluated in a comparative fashion with wild-type mice. In another study, the signaling pathway of Wnt/β-catenin mediators in the skin of scruffy cover of Fam83h KO mice as a specific prerequisite factor for hair follicle stem cell was evaluated. Despite all these together, the genes responsible for the mineralization and tooth development were selected based on literature review and STRING: functional protein association networks. the Fam20a, Dspp, Dmp1, Enam, Ambn, Sppl2a, Mmp20, Fgf10, and the mediators of Wnt/β-catenin pathway, as genes responsible for the mineralization and tooth development were evaluated in the absence of the Fam83h.
2.Objective
The molecular mechanisms and interaction network of the Fam83h gene, as a novel important gene responsible for tooth mineralization, hemostasis and development are not well characterized. Also, the companionship of the hair follicle defects and dry eye phenotype in Fam83h KO mice is still unknown. So, the expression levels of mineralization and tooth formation-related genes, as well as mediators of Wnt/β-catenin pathway and Fgf10 which had common effects on the formation of hair follicles were measured in dental root and skin of Fam83h Knockout and wild-type at 5, 11 and 18 days of age.
3. Materials and Methods
3.1. Ethical Compliance
All protocols and experimental procedures were reviewed and approved by the Ethical Committee of Kurdistan University of Medical Sciences (IR.MUK.REC.1396/181).
3.2. Animals and Sample Preparation
The Fam83h KO mice (NC_000081:g.”7835_7877” del) were generated using Clustered Regularly Interspaced Short Palindromic Repeats(CRISPR) and CRISPR-associated (Cas) (CRISPR\Cas9) and genotypically and phenotypically characterized as described previously( 3 ). These mice were backcross and inbred at two first generations (F2), confirmed by Sanger sequencing and Western blot ( 3 ). The F2-genotyped mice were propagated through inbreeding (parental* pups or pups* pups (brother *sister)) until the F6 generation and the Fam83h KO mice line were confirmed, and established and rechecked by Sanger sequencing and Western blot (Supplementary Fig. 1B, C, D). At each age of 5, 11, and 18 days old, three Fam83h KO pups born from homozygous Fam83h KO mice showed phenotypes of their parents including discolored teeth, tooth growth retardation, dental disruption in incisors, molars with attrition, smaller size, and less tall were included in the study. Total RNA was extracted from the mandibles to evaluate gene expression levels. The tail biopsy and colon samples were obtained from F4 line homozygous Fam83h KO mice to check and confirm the Fam83h Knockout by Sanger sequencing and Western blotting. Three skin samples were also taken from 8 weeks-old Fam83h KO mice as well as their wild-type counterparts for gene expression level using qPCR. All mice had full access to food and water equally and were kept in IVC cage systems under standard laboratory conditions. Also, all laboratory works were carried out under standard conditions and in full accordance with the standards for working with laboratory animals approved by the medical ethics committee of Kurdistan University of Medical Sciences.
3.3. Sanger Sequencing
To re-approve the Knockout of Fam83h (NC_000081.7), genomic DNA was extracted from tail biopsies of F4 line homozygous KO mice line using a DNeasy Blood and Tissue Kits (Qiagen). PCR was performed using primers designed for Exon 2 of Fam83h ( 3 ). The PCR product of the targeted region was sequenced and genotyped (Supplementary Fig. 1).
3.4. Western-Blotting
To re-approve the Fam83h KO mice line, total protein was extracted from colon dissected samples of the F6 generation Fam83h KO and normal wild-type mice. Polyacrylamide gel electrophoresis for extracted samples was performed using 10% SDS-PAGE. The isolated protein bonds were then blotted on polyvinylidene difluoride (PVDF) membranes (Millipore, Bedford, MA). The blotted bonds were incubated with the primary anti-Fam83h (127.5 kDa) antibody (1:1000; Bethyl, A304-328A) overnight. After 3-times of washing, the blotted PVDF paper was incubated with HRP-conjugated secondary antibody, (1:10000; A120-101P) for an hour. Bands were finally visualized by an Enhanced Chemiluminescence (ECL) Detection Kit/System (Sigma). Glycerol-3-phosphate dehydrogenase (GAPDH), was used simultaneously as a reference protein for normalization.
3.5. RNA Isolation and Reverse Transcription
Total RNA was isolated from dental root and skin samples of mice using an RNeasy mini kit (QIAGEN, Hilden, Germany) according to the manual of the manufacturer. DNA contamination was removed from RNA samples using RNase-Free DNase I treatment. The concentration and purity of RNAs were then spectrophotometrically assessed using a microplate reader with take3 (Synergy HTX, BioTek, USA). Reverse transcription was performed using 1000 ng of each extracted RNA, random hexamer primers, and 100 U of reverse transcriptase (TaKaRa, Japan) at 42 °C for 70 minutes using Eppendorf Thermal Cycler (Eppendorf, Germany).
3.6. Primers and Quantitative Real-Time PCR (RT-qPCR)
Primers were designed for genes using databases of GenBank. For confirmation of designed primers and to check the other thermodynamic properties of selected primers NCBI primer-blast online tool was used. The sequences of the primers are shown in Table 1.
Gene Symbol | Sequences | Size (bp) | Accession number |
---|---|---|---|
Ambn | F:ATGAAGGGCCTGATCCTGTTC | 130 | NM_001303431.1 ___________________ |
R:GTCTCATTGTCTCAAGGCTCAAA | |||
Fam20a | F:GATGTGACGCGGGATAAGAAG | 100 | NM_001359593.1 _________________ |
R:GCTCGGTGGAACAGTAGTAGG | |||
Dspp | F:ATTCCGGTTCCCCAGTTAGTA | 128 | NM_010080.3 _______________ |
R:CTGTTGCTAGTGGTGCTGTT | |||
Mmp20 | F:GGCGAGATGGTGGCAAGAG | 166 | NM_013903.2 _______________ |
R:CTGGGAAGAGGCGGTAGTT | |||
Ck1 Alpha | F:TCCAAGGCCGAATTTATCGTC | 110 | NM_001357500.1 ___________________ |
R:ACTTCCTCGCCATTGGTGATG | |||
Ck1 epsilon | F:GAGCTGCGTGTGGGAAATAAG | 120 | NM_001359863.1 _________________ |
R:ACATTCGAGCTTGATGGCTACT | |||
Sppl2a | F:CATGTCATGCGTGATACTGCT | 156 | NM_023220.2 _______________ |
R:ACCCTGATAACTACTGGCAACT | |||
Fgf10 | F:TTTGGTGTCTTCGTTCCCTGT | 132 | NM_008002.4 _______________ |
R: TAGCTCCGCACATGCCTTC | |||
Dmp1 | F:CATTCTCCTTGTGTTCCTTTGGG | 185 | NM_001359013.1 _________________ |
R:TGTGGTCACTATTTGCCTGTG | |||
Enam | F:TGCAGAAATCCGACTTCTCCT | 114 | NM_017468.3 _______________ |
R:CATCTGGAATGGCATGGCA | |||
Beta-Catenin | F:ATGGAGCCGGACAGAAAAGC | 108 | NM_001165902.1 __________________ |
R: CTTGCCACTCAGGGAAGGA |
Real-time PCR with SYBR green detection was performed using a RotorGene 6000 machine (Corbett Research, Sydney, Australia). Briefly, for each sample, a reaction mixture containing 100 ng of each sample cDNA, 10 picomoles of each forward and reverse PCR primer, and 12.5 µL of SYBR Premix Ex Taq II (Takara, Japan) was provided in a microtube. A thermal cycle program of incubation at 94 ºC for 10 min for hot start followed by 42 cycles of 94 ºC for 20 sec, 60 ºC for 20 sec, and 72 ºC for 15 sec was applied. Melting curve analysis and 2% agarose gel electrophoresis were performed to verify the qPCR product. For normalization of gene expression, β-Actin was also checked with all samples. To calculate the relative expression levels of genes 2−ΔΔCt method was applied.
3.7. Histological Examination of the Skin Biopsies
A 1 cm2-sized punch skin biopsy was prepared from three Fam83h KO and three normal control mice under local anesthesia. Biopsy specimens were quickly fixed in the formalin solution and consequently embedded in paraffin. Then, the 5-µm thick sections were cut from the embedded tissues, mounted on slides, and stained with hematoxylin and eosin (H&E) to investigate the possible change in hair follicles and other peripheral environments of them.
3.8. Statistical Analysis
The stability of the mRNA expression of beta-actin was evaluated by using the MS Excel application geNorm. All data are presented as mean ± SD of mRNA folds change from three independent experiments for each sample. A one-way ANOVA test was used for calculating the statistical difference between gene expression of Fam83h KO and normal wild-type mice. The post-hoc Tukey’s test was then used for multiple comparisons of each group. Gene expression differences were calculated using Genex 6 software, and statistical analyses were performed using SPSS 21 software and plotting with GraphPad Prism 7.
4. Result
4.1.The Expression Levels of Fam20a, Dspp, and Dmp1 as Important Genes for Dental Mineralization of the Tooth in the Absence of Fam83h in Tooth Roots
The gene expression level of Family With Sequence Simi-larity 20, Member A; (Fam20a), Dentin Sialophospho-protein (Dspp), and Dentin Matrix Acidic Phospho-protein 1 (Dmp1) were evaluated as important genes for dental mineralization in Fam83h KO compared with normal-wild type mice. Fam20a expression level in Fam83h KO mice was not significantly different from normal-wild type mice at 5, 11, and 18 days old (P> 0.05). The trend of expression of the Dmp1 gene was increased along with age increased in both normal-wild type and Fam83h KO. Also, the expression of Dmp1 on days 5 and 11 was not statistically significant(P >0.05), while in day 18 was significantly decreased in the Fam83h KO mice compared with normal-wild type mic(P =0.0023). There was a significant decrease in the expression level of Dspp in Fam83h KO at all three ages 5,11 and 18 days old in comparison with the normal-wild type mice in tooth roots (P <0.0001). The expression pattern of Dspp has fluctuated which increased to its highest level on day 11th of birth in both normal-wild types and Fam83h KO (Fig. 1A).
4.2. The Expression Levels of Enam, Ambn, Sppl2a, Mmp20, and Fgf10 as Contributing Genes to the Formation and/or Homeostasis of Enamel Matrix in the Absence of Fam83h in Tooth Roots
The expression level of Enamelin (Enam), Ameloblastin (Ambn), Signal Peptide Peptidase Like 2A (Sppl2a), Matrix Metallopeptidase 20 (Mmp20) , and Fibroblast Growth Factor 10 (Fgf10) were also comparatively assessed between Fam83h KO and normal wild-type mice in roots of teeth. Enam, Ambn, and Mmp20 are important genes in the formation of the enamel matrix which are related to Fam83h gene networks ( 8 ). There was no significant changes in the expression levels of Enam in Fam83h KO mice at days 5, 11, and 18 of birth compared with normal wild-type mice (P> 0.05). Also, changes in the expression level of Enam and Sppl2a (Fig. 1B) were similar in Fam83h KO and normal wild-type mice at all ages. However, the expression levels of the Ambn and Mmp20 at three different ages (5, 11, and 18 days old) in KO mice showed a significant decrease (P <0.0001) compared with normal wild-type mice. In addition, the expression levels of Fgf10 as tooth stem cell hemostasis factor demonstrated a significant decrease on days 5, 11 (P=0.0001 for both), and 18 (P= 0.0077) in the Fam83h KO mice compared to the normal wild-type mice. Furthermore, the expression level of Fgf10 showed a rising pattern from day 5 to day 18 of birth in both Fam83h KO and normal-wild type mice (Fig. 2A).
4.3. The Expression Levels of the Genes Related to Canonical Wnt/β-Catenin of Fam83h KO Mice Compared with Normal Wild-Type Mice in Tooth Roots
The expression levels of CK1a and CK1e genes in Fam83h KO mice decreased significantly on days 11 and 18 of birth compared with normal wild-type mice (CK1a; day11 P=0.0075 and day18 P=0.0176, CK1e; day11and 18 P=0.0001). This descending pattern was not significant for 5 days-old puppies (P> 0.05). Both CK1a and CK1e showed more expression on day 18. Also, the expression level of the β-catenin (b-CAT) in Fam83h KO mice decreased significantly in all three ages including 5, 11, and 18 days compared with normal wild-type mice (on days 5, 11, and 18 were P= 0.0332, P=0.0474, and P= 0.031 respectively). The expression level of this gene reduced over time, from day 5 to 18 (Fig. 3A).
4.4. Fgf10 and WNT Mediators’ Expression Level and the Histological Assessment in the Absence of Fam83h in the Skin
The Expression level of Fgf10 in the skin showed a significant decrease (P=0.0010) in Fam83h KO mice compared to normal-wild type mice (Fig. 2B). Also, the expression level of CK1a, CK1e, and β-catenin as mediators of the Wnt/β-catenin pathway were measured in the skin sample of both Fam83h KO and normal-wild type mice. The results showed a significant reduction of CK1a (P=0.0065), CK1e (P=0.0075), and β-catenin (P=0.0495) in Fam83h KO compared with normal-wild type mice (Fig. 2B). The histological examination of skin samples was done for both Fam83h KO and normal-wild type mice at 8 weeks age of post-natal to determine the possible effect of Fam83h KO on the hair follicles. The histological evaluation revealed an obvious difference in the development of hair follicles between these two groups. In normal control mice, the hair follicles presented normal morphology at the anagen phase. In contrast, Fam83h knockout mice showed undifferentiated and disrupted hair follicles at the same phase (Fig. 2C).
5. Discussion
It is suggested that Fam83h correlated with Wnt/β-catenin and could mediate regulation of the organization of cell cytoskeleton and play an important role in ameloblast maturation and differentiation of the enamel matrix ( 9 ). The absence of Fam83h might increase the potential phenotype of dental deficiency in mice as an important factor that affects dental mineralization and development in mice ( 3 ). There is an inconsistency in the phenotypic manifestation of Fam83h deletion in outbred and inbred mice as well as the other related phenotypes in humans. Therefore, in the present study, we evaluated the expression levels of Fam83h-related genes and wnt/β-catenin pathway which have an important role in the formation and mineralization of teeth in tooth roots. Furthermore, along with histology assessment, we evaluated Fgf10 as a gene related to the development of hair follicles and also, the mediators of the Wnt/β-catenin signaling pathway as a prerequisite for hair follicle stem cell specification ( 10 ) evaluated in the skin.
Dmp1 is associated with craniofacial abnormalities and Periodontal Breakdown ( 11 ). The expression level of this gene is significantly decreased only on the 18th day of birth in Fam83h KO mice compared with normal wild-type mice. The deficiency of Dmp1 does not seem to have a significant effect on tooth formation and mineralization. It is demonstrated that Dspp, which is mainly expressed in odontoblasts, is associated with dentinogenesis imperfecta II, dentinogenesis imperfecta III ( 12 , 13 ), and dentin dysplasia (DD) ( 14 ) which the hypo-mineralization are common phenotype among them. The expression level of Dspp significantly decreased in 5, 11, and 18 days old mice.
Fam20a is an important factor for dental mineralization and is a critical gene for the mineralization of bone, dentin, and enamel ( 15 ). Previously, Fam20a deficient mice were associated with a delay in the eruption of molars as well as hyperplasia of the gingival epithelium ( 16 ). The expression levels of the Fam20a did not change at any of the studied ages.
Previous studies reported Enam and Ambn as necessary genes for the formation of enamel matrix, which is expressed during the secretory stage of ameloblast ( 17 ). The expression level of Ambn decreased significantly during the three assessed ages in Fam83h KO mice compared with normal wild-type mice. Expression of the Enam gene as another gene required for proper enamel formation in Fam83h KO mice ( 18 ) remained unchanged during the studied ages in Fam83h KO mice compared with normal wild-type mice. Ameloblastin (AMBN) is an adhesion molecule synthesized by odontoblasts and ameloblasts. Previous studies, Reported that the enamel layer in Enam and Ambn KO mice was similarly either a thin or missing enamel layer ( 19 ) .
Sppl2a and Mmp20 are two important genes for the homeostasis of enamel through their association with Fam83h. Sppl2a as a critical intramembranous protein is essential for maintaining cellular homeostasis in the ameloblasts ( 20 ). Mmp20 is an enamel metalloproteinase that cleaves enamel matrix proteins ( 21 ). MMP20 is one of the genes involved in AI etiology and related to the hypomineralization of dentine( 22 ) that we investigate its expression level in this study. The expression level of Sppl2a did not change in the evaluated ages, while the Mmp20 expression level showed a significant decrease at all ages of 5, 11, and 18 days of birth in Fam83h KO mice compared with normal wild-type mice.
The results of the Fgf10 expression assessment demonstrated a significant decrease on days 5, 11, and 18 of birth in the Fam83h KO mice in comparison with normal wild-type mice. Previous studies have shown an important role for Fgf10 in the development and maintenance of stem cell compartment during the prenatal ( 23 ) and postnatal ( 24 , 25 ) period in incisor cervical loops.
Based on the expression profile summarized above, there was a significant reduction in the expression level of Ambn, Mmp20, Dspp, and Fgf10 in Fam83h KO mice compared with normal wild-type mice. These results were reported for the first time and were consistent with previous reports and showed an association between Fam83h KO mice and an abnormal dental phenotype. Significant reduction in the expression level of genes related to dental mineralization such as Ambn as a necessary gene for enamel matrix formation, Mmp20 as a major role in the cleavage of the enamel matrix and essential for normal tooth development, Dspp as a gene mainly expressed in odontoblasts and essential for proper mineralization of teeth. Fgf10, is an important gene for the maintenance of stem cells in developing mouse tooth roots, largely justifying the phenotype including discolored, fractured, and eroded teeth after breastfeeding in mandible incisors of Fam83h KO mice. Based on the results of this study and discussed topics, the phenotype of teeth in Fam83h KO mice shows evidence of disrupted, undeveloped, petite incisors and smaller size molars with attrition in comparison with Normal wild-type mice (Fig. 1), which might be related to the decrease of mineralization in the absence of Fam83h.
The result of the evaluation of the expression of Ck1a, Ck1e, and β-catenin as mediators of Wnt/β-catenin pathway showed a significant decrease in the expression levels of Ck1a and Ck1e in Fam83h KO mice on days 11 and 18 of birth. The expression level of β-catenin also significantly decreased at 5, 11, and 18 days of birth. Previous studies showed a relationship between Fam83h mutations and the Wnt/β-catenin pathway. Yang et al. reported that mutations of Fam83h inhibit the mineralization of ameloblasts by activating the Wnt/β-catenin pathway ( 7 ). Fan et al. also demonstrated that continuous activation of β-catenin leads to incisor enamel hypo-mineralization ( 26 ). In another study, Bae et al. reported that the excess level of the Wnt/β-catenin signaling pathway disturbs normal process of tooth-root formation ( 27 ). To explain these findings, it should be noted that the β-catenin is degraded by a multiprotein complex called “destruction complex” in which CK1a together with GSK-3 causes phosphorylation and degradation of β-catenin via ubiquitination ( 28 ). Kim et, al. have shown that nuclear and cytoplasmic localization of β-catenin could reduce in response to Fam83h knock-down, and ubiquitination and proteasomal degradation of β-catenin increased with Fam83h knock-down ( 29 ). In addition, Kuga et al showed that overexpression of Fam83h promotes the accumulation of CK1 in nuclear speckles ( 30 ). it can be concluded that the Fam83h deletion resulted in the decrease of the Wnt/β-catenin signaling pathway via reducing the expression levels of Ck1a, Ck1e, and β-catenin. Accordingly, based on our previous and current data, it is plausible to believe that the absence of Fam83h would cause the cytoplasmic elevation of Ck1a, leading to the formation of “destruction complex”. This is basically an intuitive presumption because the lack of Fam83h would prevent the employment of Ck1a ( 6 , 31 ), increasing Ck1a in the cellular cytoplasmic environment. Further, it can be proposed that increased formation rate of destruction complex would result in degradation of β-catenin that subsequently curbes the Wnt/β-catenin signaling pathway. Therefore, as an instinctive possibility, unemployed Ck1a maybe considered as a negative regulator of the Wnt/β-catenin signaling pathway ( 32 ). Furthermore, decreased level of Ck1e expression culminated in reduction of Dvl-1 phosphorylation. Given the role of Dvl-1 phosphorylation as a Wnt/β-catenin positive regulator ( 33 ), such reduction could be considered as an additional reason for Wnt/β-catenin reduced activity in the absence of Fam83h.
Further, the reduced expression level of Ambn, Mmp20, Dspp, and Fgf10 were compatible with the reduced expression level of Wnt/β-catenin signaling pathway in Fam83h KO mice. Zhou et al. and Liu et al. showed that the continuou s signaling activity of the Wnt/β-catenin pathway in the dental epithelium of mice induced ectopic expression of Dspp ( 34 , 35 ). Koizumi et al. noted that enhanced expression of Dspp and Dmp1 was completely suppressed by the Wnt antagonist ( 36 ). Importantly, it was previously documented that the Mmp20 plays an important role in the migration of normal ameloblast through tight control of the Wnt/β-catenin signaling pathway ( 37 ). Altogether, it is conspicuous that lack of Fam83h, along with the reduction of the Wnt/β-catenin signaling pathway, would conduce in the concurrent reduction of mineral-related genes.
Importantly, in addition to dental development process, the Fam83h and Wnt/β-catenin axis are actively involved in the development of hair follicles ( 38 ). Our findings demonstrated reduction in the expression level of Ck1a, Ck1e, and β-catenin genes in the skin tissues of Fam83h KO mice compared to their Wild-Type counterparts. Such reduction was also detected in the expression level of Fgf10 in the skin of Fam83h KO mice compared to Wild-Type mice. Fgf10 is known as a promoter for hair growth-inducing the anagen phase of resting follicles ( 39 , 40 ). Also, Fgf10 controls the development of hair follicles in a orchestrated fashion with Wnt/β-catenin signaling pathway ( 41 , 42 ). Interestingly, the Wnt/β-catenin pathway plays an important role in the initiation, development, and growth of hair follicles ( 43 ). It is worth mentioning that several studies have documented that Fgf10 was the only member of the Fibroblast Growth Factor genes (Fgfs) family, which was selectively expressed in the mesenchyme during the early stage of follicle morphogenesis, contributing to the maintenance of follicle growth ( 44 ). It is also, reported that Fgf10 together with β-catenin can induce the development and growth of hair follicles ( 41 ). Thus, the reduction of Fgf10 elucidates the scruffy coat phenotype in Fam83h KO mice. Furthermore, it was shown that a novel mutation in Fgf10 could be responsible for slit-eye mice model having a dry eye ( 40 , 45 ). Given all above plus targeting Fgf10 expression as a therapeutic modality in the treatment of dry eyes in a rabbit model ( 46 ) supports the identification of dry eye phenotype in Fam83h KO mice model. Altogether, It is reasonable to conclude that the absence of Fam83h along with decreased Fgf10 and Wnt/β-catenin expression could be responsible for dry-eye and scruffy coat phenotypes in Fam83h KO mice. Figure 3 summarizes the discussion and proposed potentials.
In conclusion, our data provides evidence that the lack of Fam83h gene curtails Wnt/β-catenin pathway, causing few potential alterations at the cellular and molecular levels. A potential mechanism for such effects could be based on the accumulation of unemployed Ck1a, elevation of destruction complex, and decreased CK1e as well as Dvl-1 signaling. Importantly, it is possible that reduction in both mineralization genes and Wnt/β-catenin signaling in the absence of Fam83h gene may be responsible for the deficiency of dental formation and mineralization. In addition, our data here indicates that reduction in both Fgf10 gene and Wnt/β- catenin pathway in the skin may affect hair follicular maturation. Given the central role of Wnt/β- catenin pathway in several pivotal biological processes, it is reasonable to speculate that deficiency in Fam83h causes the down-regulation of Wnt/β- catenin signaling, leading to a wide spectrum of phenotypic alterations in a complex and multi-factorial manner, warranting further research. especially evaluating the protein interaction networks, and finding the hub genes which may be common among the Wnt signaling pathway, fam83h, and other related genes can be the future research topics to better understand Fam83h biological manner.
Acknowledgments
Thanks to the Cell and Molecular Research Center of Kurdistan University of Medical Sciences, also grateful to all of those that have had the pleasure to work during this and other related projects.This study was funded by grant number IR.MUK.REC.1396/181 provided by Kurdistan University of Medical Sciences.
Competing interests
The authors have no conflict of interest to declare regarding this manuscript.
Author Contributions
SN designed and performed testing as well as drafted the manuscript. SN, ZV, FF, and SP validate the methodology and tests.SN, MBK, BN, MRK, SP, FF, SB preparation of the manuscript.BB, SN, SP, Scientific consultant, and content and writing editor. FF and SN supervised the entire study. All authors revised and approved the final manuscript.
Data Availability Statement
The data that support the findings of this study are available from the corresponding author upon reasonable request.
Manifestation
Part of the current article has already been published as a Conference Proceeding, available at :
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