ZC3H11A mutations cause high myopia by triggering PI3K-AKT and NF-κB mediated inflammatory reactions in humans and mice

Chong Chen; Qian Liu; Yu Rong; Cheng Tang; Xinyi Zhao; Dandan Li; Fan Lu; Jia Qu; Xinting Liu

doi:10.7554/eLife.91289.1

eLife assessment

This useful study reports an investigation of ZC3H11A as a cause of high myopia through the analysis of human data and experiments with genetic knockout of Zc3h11a in mice, providing a model of myopia. The evidence supporting the conclusions is currently incomplete. It could be strengthened by a more thorough genetic analysis, fuller presentation of human phenotypic data, and more explanation for the reasons why there was no increased axial length in mice with myopia. The work will be of interest to ophthalmologists and researchers working on myopia.

https://doi.org/10.7554/eLife.91289.1.sa3

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Abstract

High myopia (HM) is a severe form of refractive error that results in irreversible visual impairment and even blindness. However, the genetic and pathological mechanisms underlying this condition are not yet fully understood. From a adolescents myopia survey cohort of 1015 HM patients, pathogenic missense mutations were identified in the ZC3H11A gene in four patients by whole exome sequencing. This gene is a zinc finger and stress-induced protein that plays a significant role in regulating nuclear mRNA export. To better understand the function and molecular pathogenesis of myopia in relation to gene mutations, a Zc3h11a knock-out (KO) mouse model was created. The heterozygous KO (Het-KO) mice exhibited significant shifts in vision towards myopia. Electroretinography revealed that the b-wave amplitude was significantly lower in these mice under dark adaptation. Using immunofluorescence antibodies against specific retinal cell types, the density of bipolar cell-labelled proteins was found to be decreased. Transmission electron microscopy findings suggesting ultrastructural abnormalities of the retina and sclera. Retinal transcriptome sequencing showed that 769 genes were differentially expressed, and Zc3h11a was found to have a negative impact on the PI3K-AKT and NF-κB signalling pathways by quantitative PCR and western blotting. In addition, myopia-related factors, including TGF-β1, MMP-2 and IL-6 were found to be upregulated in the retina or sclera. In summary, this study characterized a new pathogenic gene associated with HM. The findings indicated that the ZC3H11A protein may serve as an innate immune and inflammatory response trigger, contributing to the early onset of myopia. These findings offer potential therapeutic intervention targets for controlling the development of HM.

Introduction

Myopia is a highly prevalent eye affliction that commonly develops during childhood and early adolescence. The prevalence of myopia among the adult population ranges from 10-30%, while parts of East and Southeast Asia have reported rates as high as 80-90% among young people (Baird et al., 2020; Holden et al., 2016). HM is a severe refractive error characterised by a diopter ≤ −6.00 D or an ocular axis greater than 26 mm. It is estimated that by 2050, the number of people with HM worldwide will reach 938 million, accounting for 9.8% of the total population. HM can trigger a range of adverse ocular changes, such as cataracts, glaucoma, retinal detachment, macular degeneration and possibly total blindness (Koga et al., 2014; Saw et al., 2005). While conventional methods for the prevention and control of myopia can provide some correction, they are not entirely effective in managing its progression, particularly during childhood and adolescence.

With the development of next-generation sequencing, whole exome sequencing (WES) and whole genome sequencing (WGS) have extended the findings of linkage studies to identify potential causes of syndromic HM (sHM) and non-syndromic HM (nsHM). To date, approximately 20 genes with causal associations have been identified in sHM, including ZNF644, SCO2, CCDC111, LRPAP1, SLC39A5, LEPREL1, P4HA2, OPN1LW, ARR3, BSG, NDUFAF7, CPSF1, TNFRSF21, DZIP1, XYLT1, CTSH, GRM6, LOXL3 and GLRA2 (Haarman et al., 2022; Tian et al., 2023; Yang et al., 2023; Ye et al., 2023). These discoveries have provided insight into the molecular mechanisms underlying HM. However, known candidate genes can only explain about 20% of the causes of this disease (Cai et al., 2019; Tedja et al., 2019). At the same time, the neuromodulators and signal molecules of HM are extremely complex, including sclera extracellular matrix (ECM) remodelling and endoplasmic reticulum (ER) stress (Ikeda et al., 2022), inflammatory responses, the release of dopamine and gamma-aminobutyric acid (GABA), or abnormalities in myopia-related signalling pathways, such as retinoic acid signalling, TGF-β signalling and HIF-1α signalling.

Screening mutations from a adolescents myopia survey cohort by WES, we identified zinc finger CCCH domain-containing protein 11A (ZC3H11A) as a HM candidate gene. This particular gene is a member of the zinc finger protein gene family. Several of its members have been linked to myopia or HM, including ZNF644, ZC3H11B, ZFP161 and ZENK. Like ZC3H11B, a gene that is conserved with respect to ZC3H11A in humans, the five genome-wide variants loci have previously been found to be strongly associated with greater axial length (AL) or HM (Schippert et al., 2007; Shi et al., 2011; Szczerkowska et al., 2019; Tang et al., 2020; Wang et al., 2004). Recent proteomic studies have indicated that ZC3H11A may be a constituent of the transcriptional export (TREX) complex. Additionally, it has been suggested that this protein is involved in stress-induced responses (Younis et al., 2018). Dysfunction of ZC3H11A results in enhanced NF-κB signalling through defective IκBα protein expression, which is accompanied by upregulation of numerous innate immune- and inflammation-related mRNAs, including IL-8, IL-6 and TNF in vitro (Jimi et al., 2019). Moreover, patients with myopia have a higher proportion of inflammation-associated cells, including neutrophils, while those with moderate myopia show strained immune system function (Lin et al., 2016; Qi et al., 2022). Conversely, some traditional Chinese medicines can control myopia progression by suppressing AKT and NF-κB mediated inflammatory reactions (Chen et al., 2022). However, the precise pathological mechanism of ZC3H11A in myopia development remains unclear, necessitating further research.

The current study identified four HM-related variants in the ZC3H11A gene among a cohort of 1015 adolescents. Additionally, KO mice were constructed using the CRISPR/Cas9 system and their myopic phenotypes, visual function, bipolar cell apoptosis, and retinal and scleral microstructure were assessed. Moreover, RNA sequencing and expression experiment was performed to identify perturbed molecules and pathways and to examine the interactions between these factors in relation to HM. The above results will provide new ideas for the prevention and control of high myopia, especially early-onset, uncorrectable and familial myopia.

Results

ZC3H11A mutations are associated with HM in a Chinese cohort

The subjects were selected from the Myopia Associated Genetics and Intervention Consortium (MAGIC), our previously published research involving large-scale myopia cohorts and genomic sequencing data. Four missense mutations in the ZC3H11A gene (c.412G>A, p.V138I; c.128G>A, p.G43E; c.461C>T, p.P154L; and c.2239T>A, p.S747T) were identified in the 1015 HM patients aged from 15 to 18 years. The uncorrected visual acuity (UCVA) and ocular axial length of these patients are presented in Table 1. A tessellated fundus was observed in patient 1 and patient 3. All of the identified mutations exhibited very low frequencies in the Exome Aggregation Consortium (ExAC) or Genome Aggregation Database (gnomAD), with CADD > 22.7. Among them, c.412G>A, c.128G>A and c.461C>T were located in or around a domain named zf-CCCH_3 (Figure 1A and B). Furthermore, all of the mutation sites were located in highly conserved amino acids across different species (Figure 1C). Four mutations resulted in a higher degree of conformational flexibility and altered the negative charge at the corresponding sites (Figure 1D and E).

Structural modelling of ZC3H11A gene mutations.
(A) Illustration of exons and mutation sites of ZC3H11A; exons 5-8 of ZC3H11A encode the zf-CCCH_3 protein domain. (B) A structural model of the full-length human ZC3H11A protein was generated using PyMOL; the locations of the four mutation sites are marked. (C) The p.G43E mutation is located in exon 6, while the p.V138I and p.P154L mutations are in exon 8, and the p.S747T mutation is in exon 20. (D) Multiple sequence alignment of the proteins where ZC3H11A mutations are found in multiple species. (E) These mutations can result in a higher degree of conformational flexibility at the corresponding sites, potentially destabilizing the structural domain.

The clinical features and mutations of affected patients

Zc3h11a Het-KO mice exhibited myopic phenotypes

Het-KO mice were constructed at four weeks of age against a C57BL/6J background using CRISPR/Cas9 technology (Figure supplement 1). Retinal fundus images and ocular histomorphology of Zc3h11a Het-KO mice at eight weeks postnatal were assessed against those of their wild-type (WT) counterparts. No significant structural differences were observed (Figure supplement 2). These findings suggest that the deletion of Zc3h11a does not alter the retinal structure or ocular histomorphology. Therefore, Zc3h11a Het-KO mice are a relevant model for the investigation of the role of Zc3h11a in refractive development.

Refraction and axial length in Zc3h11a Het-KO mice were found to be significantly greater than in WT littermates (independent samples t-test, p<0.05; Figure 2A and B). The difference between the two genotypes was statistically significant at weeks 4 and 6. Correspondingly, the vitreous chamber depth of Zc3h11a Het-KO mice was deeper than that of WT littermates (independent samples t-test, p<0.05; Figure 2C). There were no significant differences in the anterior chamber depth, lens diameter and body weight between the two groups (Figure 2D-F). These results suggest that the Het-KO of the Zc3h11a gene may lead to an increase in myopia in mice.

Comparison of ocular biometrics and body weights of Zc3h11a Het-KO (n=14) and WT (n=10) littermates during weeks 4-10 of development.
(A, B) Refraction and axial length in Zc3h11a Het-KO mice. (C) Vitreous chamber depth. (D-F) Anterior chamber depth, lens depth and body weight. The effect of genotype on time-dependent refractive development was assessed through independent samples t-tests. P-values are indicated as follows: *P<0.05, **P<0.01, ***P<0.001 and ****<0.0001.

Reduced b-wave amplitude and bipolar cell-labelled protein density in Zc3h11a Het-KO mice

To confirm if Zc3h11a is responsible for refractive development regulation, visual function was assessed by electroretinography (ERG). Upon dark adaptation, b-wave amplitudes in seven-week-old Het-KO mice were significantly lower at dark 3.0 and dark 10.0 compared to WT mice (Figure 3A and C). On the contrary, there were no differences in a-wave amplitudes between the Het-KO and WT groups (Figure 3B). Based on the ERG results, variations between Het-KO and WT littermates can be observed. The ERG b-wave, predominantly generated by bipolar cells, was significantly modified in both the 3.0 and 10.0 dark adaptation conditions. Immunofluorescence analyses were performed on frozen retinal sections to investigate this phenomenon further. Specifically, Zc3h11a, PKCα, Opsin-1 and Rhodopsin markers were utilised to detect the Zc3h11a protein, rod-bipolar cells, cone cells and rod cells, respectively (Figure 3D-F). Additionally, the differences in the Zc3h11a and PKCα protein contents of the retina were quantified through western blot analysis. Notably, the protein densities of Zc3h11a and PKCα were decreased in the Het-KO group (Figure 3G and H). However, there were no significant differences in the densities of cone and rod cells between the two groups (Figure 3I and J).

Electroretinography and immunohistochemical localization of Zc3h11a, PKCα, Opsin-1 and Rhodopsin in WT and Het-KO mice eyes.
(A) Representative scotopic ERG responses from Het-KO and WT eyes at dark 0.01, 3.0 and 10.0 cds/m². (B, C) Statistical analysis of a-wave and b-wave amplitudes. Mean ± standard deviation, n=12/group. (D-F) Immunofluorescence-stained samples to detect Zc3h11a, bipolar cells, cone and rod cells. (G, H) Lower levels of Zc3h11a and PKCα (E. H) expression were observed in Het-KO mice (I, J) The expression levels of Opsin-1 and Rhodopsin between Het-KO and WT mice. Statistical significance was defined as *P<0.05, **P<0.01 and ***P<0.001, as determined by independent samples t-tests.

Retinal ultrastructure alterations in het-KO mice model

Transmission electron microscopy (TEM) was used to analyse retinal ultrastructure of in 10-week-old mice. In the inner nuclear layer (INL) of the retina, in contrast to WT mice, Het-KO mouse cells had enlarged perinuclear gaps (black arrow), perinuclear cytoplasmic oedema (blue arrow), and thinned and lightened cytoplasm (Figure 4A and B). However, in the outer nuclear layer (ONL), no significant difference in cell morphology was observed between the two groups of mice (Figure 4C and D). Furthermore, when compared to the WT group, the Het-KO mice exhibited relatively damaged photoreceptor cell membrane discs (MB), in which the outer layer was detached and sparsely distributed locally (Figure 4E and F). There were also a small number of broken membrane discs, as well as some disorganized and loosely arranged ones (red arrow), with a slight increase in size (Figure 4G and H).

TEM showing the retinal ultrastructure of WT and Het-KO mice.
(A, B) Cellular morphology of the INL in which bipolar cells are located in WT (A) and Het-KO mice (B). (C, D) Cellular morphology of the ONL in which the optic cells are located in WT (C) and Het-KO mice (D). (E, F) MB structure in WT mice. (G, H) MB structure of Het-KO mice.

RNA-Seq analysis of molecular and pathways changes in Zc3h11a Het-KO mice retinas

In the retina transcriptome analysis, 769 genes were differentially expressed (Fold change (FC) of at least two and a P value < 0.05) in the Zc3h11a Het-KO group, of which, 303 were upregulated and 466 were downregulated (Figure 5A and B). GO enrichment analysis revealed that these were primarily involved in biological processes (such as zinc ion transmembrane transport, RNA biosynthetic and metabolic process, and negative regulation of NIK/NF-κb signalling) and molecular functions (such as calcium ion binding and zinc ion transmembrane transporter activity) (Figure 5C and D). KEGG pathway enrichment analysis indicated that the differentially expression genes (DEGs) in the Zc3h11a Het-KO group were primarily involved in the PI3K-AKT signalling pathway, MAPK signalling pathway, human virus infection and neuropsychiatric disease (Figure 5E).

RNA-Seq analysis of molecular and pathway differences between WT control and Het-KO retinas.
(A, B) Volcano maps were utilized to visualize the differentially expressed genes (DEGs) between WT control and Het-KO mouse retinas. (C, D) GO enrichment analysis of DEGs in the Het-KO group (E) KEGG pathway enrichment analysis of DEGs in the Het-KO group.

Zc3h11a negatively regulates the PI3K-AKT and NF-κB pathways

PI3K-AKT is one of the most important pathways for cell survival, division, autophagy and differentiation (Alzahrani, 2019). Meanwhile, it has been found that ZC3H11A can regulate the NF-κB pathway at the level of IκB mRNA export in ZC3-KO cells (Darweesh et al., 2022). IκBα is a critical protein that governs NF-κB function predominantly within the cytoplasmic compartment. It plays a pivotal role in inhibiting the activation of NF-Κb (Dyson and Komives, 2012; Manavalan et al., 2010). In addition, AKT promotes IκBα phosphorylation to undergo degradation, which enhances the nuclear translocation of NF-kB (Alzahrani, 2019; Torrealba et al., 2020). Accordingly, we investigated whether ZC3H11A has any regulatory influence on the transcriptional activation of PI3K-AKT and NF-κB in vivo. To this end, we evaluated the mRNA and protein expression levels of ZC3H11A, PI3K, AKT, p-AKT, IκBα and NF-κB in the retina. The expression levels of ZC3H11A, PI3K, AKT, p-AKT and NF-κB were significantly upregulated, while IκBα was downregulated in Het-KO mice (Figure 6A-L). These findings strongly suggest that ZC3H11A exerts a negative impact on the PI3K-AKT and NF-κB pathways.

Effect of Zc3h11a on the expression of genes and proteins related to the PI3K-AKT and NF-κB signalling pathways in the retina.
(A-C) The ZC3H11A, PI3K and AKT gene levels (n=3) were evaluated. (D, E) The IκBα and NF-κB gene levels (n=3). (F) Protein expression levels of ZC3H11A, PI3K, AKT, p-AKT and GAPDH were detected by western blot. (G-I) Quantitative analysis of the ZC3H11A and PI3K levels were normalized to GAPDH, while p-AKT levels were normalized to AKT (n=3). (J) The protein expression levels of IκBα, NF-κB and GAPDH were determined by western blot analysis. (K, L) Quantitative analyses of IκBα and NF-κB were normalized to GAPDH (n=3).

TGF-β1, MMP-2 and IL-6 were increased in Zc3h11a Het-KO mice

In animal models of myopia, it has been established that intraocular concentrations of TGF-β1 are elevated (Chen et al., 2013; Liu et al., 2022), especially in the retina and sclera. The abnormal expression of matrix metalloproteinase-2 (MMP-2) and interleukin-6 (IL-6) can induce myopia, and these are regulated by NF-κB (Libermann and Baltimore, 1990; Wu and Schmid-Schönbein, 2011). To investigate the hypothesis that the TGF-β1 and NF-κB signalling pathways exhibit hyperactivity in the retina in the presence of reduced Zc3h11a, we assessed the expression of TGF-β1, MMP-2 and IL-6 at the mRNA levels in the retina and sclera of WT and Het-KO mice, while analysing scleral TEM. Additionally, we confirmed changes in the expression levels of TGF-β1 and MMP-2 in the retina at the protein level. qPCR analysis showed increased expression of TGF-β1, MMP-2, and IL-6 in the sclera and retina of Het-KO mice compared with WT mice (Figure 7A and B). Scleral TEM results suggested that scleral collagen fibres in Het-KO mice were disorganized over a large area with irregular transverse and longitudinal arrangement (Figure 7C). The western blot results showed increased expression levels of TGF-β1 and MMP-2 in the retinas of Zc3h11a Het-KO mice (Figure 7D).

Effect of Zc3h11a on the expression of TGF-β1, MMP-2 and IL-6 in the retina and sclera.
(A, B) Examination of TGF-β1, MMP-2 and IL-6 gene expression in the sclera (A) and retina (B) (n=3). (C) TEM structure of sclera. (D) Determination of TGF-β1 and MMP-2 protein expression levels, normalized to GAPDH, through western blot analysis (n=3).

Discussion

This study identified and validated a new candidate gene in a large high myopia cohort, ZC3H11A. Moreover, the study provided evidence of the presence of moderate or HM phenotypes and damaged bipolar cells in vivo by constructing Het-KO mice for the first time. TEM analysis showed ultrastructural changes in parts of both the retina and sclera of Het-KO mice. To understand how ZC3H11A regulates the development of HM, retinal transcriptome sequencing was performed. The results revealed that Zc3h11a upregulates the PI3K-AKT and NF-κB signalling pathways. In addition, the expression levels of myopia-related factors, such as TGF-β1, MMP-2 and IL-6, were upregulated in the retina and sclera of the Het-KO mice. Therefore, it can be speculated that the ZC3H11A protein may act as an innate immune and inflammatory response trigger, contributing to the early onset of HM.

ZC3H11A is involved in the export and post-transcriptional regulation of selected mRNA transcripts required to maintain metabolic processes in embryonic cells; these are essential for the viability of early mouse embryos (Younis et al., 2023). In studies of chickens, mice and humans, the zinc finger protein ZENK was found to play a role in the development of refractive myopic excursion and lengthening of the ocular axis. Moreover, early growth response gene type 1 Egr-1 (the human homolog of ZENK) activates the TGF-β1 gene by binding to its promoter, which is thought to be associated with myopia (Baron et al., 2006; Xiao et al., 2022). Another zinc protein finger protein 644 isoform, ZNF644, has recently been identified by WES as causing HM in Han Chinese families (Shi et al., 2011). ZC3H11A is also a zinc finger protein, and the findings of the current study revealed that Zc3h11a Het-KO mice showed a myopic shift, which is consistent with previous studies reporting reduced protein expression of Zc3h11a in an unilateral induced myopic mouse model (Fan et al., 2012).

In vertebrate models, refractive development and ocular axial growth are visually controlled (Wallman and Winawer, 2004). The regulation of axial length or refractive error occurs through complex light-dependent retina-to-sclera signalling (Tkatchenko and Tkatchenko, 2019). Optical scatter information is processed by the retina and then converted into molecular signals that regulate peripheral retinal growth and scleral connective tissue renewal, ultimately affecting the growth rate of the posterior segment of the eye (Harper and Summers, 2015; Tkatchenko et al., 2006; Tkatchenko et al., 2018). All cell types of the retina contain myopia-related genes and retinal circuitry driving refractive error. In this study, Het-KO mice were found to have reduced b-wave amplitudes, diminished relative fluorescence intensity of bipolar cells and ultrastructural changes in inner nuclear layer (INL) of the retina. Therefore, it is presumed that retinal circuitry changes result in impairment of visual signal processing and transduction causing HM.

Aberrant activation of the PI3K-AKT and NF-κB signalling pathways has been identified in highly myopic retinas. Following the sequencing evidence indicating elevations in PI3K-AKT and NF-κB signalling (Lin et al., 2016), we sought to explore the potential interplay between these pathways in mice. The results revealed that a decrease in Zc3h11a inhibited the translocation of IκBα from the nucleus to the cytoplasm. IκBα is a downstream factor of PI3K-AKT and binds to NF-κB (p65) in the cytoplasm, inhibiting its nuclear translocation. The qPCR and western Blot results verified that Zc3h11a negatively regulates both the PI3K-AKT and NF-κB signalling pathways. Thus, Zc3h11a may exert an influence on these pathways by modulating the cytoplasmic levels of IκBα, contributing to the development of myopia.

NF-κB was first discovered 25 years ago and described as a key regulator of induced gene expression in the immune system, playing a central role in the coordinated control of intrinsic immune and inflammatory responses (Hayden and Ghosh, 2011; Morgan and Liu, 2011). The downstream factors of this pathway include IL-6, IL-8, TNF-α, MMP-2, TGF-β1, etc (Jimi et al., 2019; Yoshida and Whitsett, 2006). Studies have demonstrated that the MMP-2 and IL-6 expression levels are increased in myopic eyes and that inhibiting MMP-2 or IL-6 expression will provide some degree of control over myopia progression (Lin et al., 2016; Zhao et al., 2018). Identification of the PI3K-AKT-NF-κB signalling pathway and downstream myopia effect in our study may open up new opportunities for the prevention and treatment of HM and fundus lesions in the future.

There are a number of limitations of this study that should be acknowledged. First, Zc3h11a homozygous KO (Homo-KO) mice were not obtained in our study because homozygous deletion of exons may confer embryonic lethality (Younis et al., 2023). Second, while the current study observed a reduced b-wave amplitude and bipolar cell fluorescence staining intensity in Het-KO mice, an in-depth exploration of the underlying mechanism was beyond the scope of the research. Finally, there was a limited observation time in this study and the effect of ZC3H11A on the late refractive system was not assessed.

Overall, this study has provided four key findings. First, it was confirmed that the ZC3H11A is a new candidate gene is associated with HM in a cohort of Chinese Han individuals. Secondly, changes in Zc3h11a expression were found to affect retinal function, particularly in bipolar cells. Third, changes in Zc3h11a expression were found to cause alterations in numerous signalling pathways, the most notable being the PI3K-AKT and NF-κB pathways. Fourth, changes in Zc3h11a expression were found to cause changes in the myopia-related genes TGF-β1, MMP-2 and IL-6. The above results suggest that Zc3h11a promotes the translocation of IκBα from the nucleus to the cytoplasm, thereby exerting negative feedback regulation of the PI3K-AKT signalling pathway and inhibiting the NF-κB signalling pathway. At the same time, the increase in TGF-β1 in myopic eyes stimulates the PI3K-AKT signalling pathway, which leads to activation of the PI3K-AKT signalling pathway, resulting in downstream degradation of IκBα after phosphorylation. This, in turn, increases the nuclear translocation of NF-κB. To sum up, Zc3h11a promotes the myopia-associated factor TGF-β1 by acting directly or indirectly on both the PI3K-AKT and NF-κB signalling pathway-mediated inflammatory reactions and the expression of MMP-2 and IL-6, which together, promote the development of early myopia (Figure 8).

Schematic representation of the PI3K-AKT-NF-κB signalling pathway in retina.

Therefore, this model can be used as one of the new strategies for intervention and treatment of high myopia. However, because the causes of myopia or HM are complex and involve different tissues and molecular pathways in the eye, it is likely that future research will identify more genes and molecular mechanisms that could provide guidance for clinical intervention and treatment.

Materials and methods

Ethics approval and consent to participate

The studies that involved human participants were approved by the Eye Hospital, Wenzhou Medical University (Wenzhou, China), and were carried out in strict adherence to the guidelines of the Helsinki Declaration. All participants provided informed consent. Furthermore, all animal experiments were approved by the Animal Care and Ethics Committee at Wenzhou Medical University and were performed according to the guidelines set forth in the Association for Research in Vision and Ophthalmology Statement for the Use of Animals in Ophthalmic and Visual Research. (https://www.arvo.org/About/policies/statement-for-the-use-of-animals-in-ophthalmic-and-vision-research/).

Recruitment of subjects

A total of 1015 sporadic HM patients were recruited from the Eye Hospital of Wenzhou Medical University for MAGIC project. HM was defined as SE ≤ −6.00 D in either eye (Flitcroft et al., 2019). Detailed ophthalmic examinations, including visual acuity, axial length, slit-lamp, fundus photography and optical coherence tomography were performed.

WES and the detection of variants

DNA was extracted from all probands using a FlexiGene DNA Kit (Qiagen, Venlo, The Netherlands), according to the manufacturer’s protocol. DNA from all probands underwent WES using a Twist Human Core Exome Kit and an Illumina NovaSeq 6000 sequencing system (150PE) (Berry Genomics Institute, Beijing, China). The mean depth and coverage of the target region were approximately 78.26× and 99.7%, respectively. Sequence reads were aligned to the reference human genome (UCSC hg19) using the Burrows-Wheeler aligner (BWA). The variants were called and annotated with Verita Trekker and Enliven software (Transcript ID, ENST00000332127.4, Berrry Genomics Institute), respectively.

Het-KO mice model construction, husbandry and ocular biometric measurements

Het-KO mice were constructed at four weeks of age against a C57BL/6J background using CRISPR/Cas9 technology at GemPharmatech Co.,Ltd (Nanjing, China). Exon5-exon6 of the Zc3h11a transcript was recommended as the KO region; this region contains a 244bp coding sequence. Littermates of Het-KO and WT mice were used for all experiments. All animals were housed in the animal husbandry room of Wenzhou Medical University. Mice were housed in standard transparent mouse cages at 22±2°C with a 12-hour light/12-hour dark cycle (light from 8 am to 8 pm, brightness approximately 200-300 lux) and free access to food and water. To exclude the effect of ocular developmental malformations, mice with small eyes and ocular lesions were excluded from the observation cohort. Body weight, refraction and ocular biometrics of Het-KO (n=14) and WT (n=10) mice were assessed at 4, 5, 6, 8 and 10 weeks of age.

Electroretinography

To evaluate the effect of Zc3h11a on the electrophysiological properties of various neuronal populations in the retina, ERG was performed on the right eye of Het-KO and WT littermates at seven weeks of age, at the same time of day (n=12). Both scotopic and photopic ERG responses were evaluated. The mice were dark-adapted overnight, and all procedures were performed under dim red light (<1 lux). The animals were anaesthetized with intraperitoneal injection of pentobarbital sodium (40 mg/kg) and the pupils were dilated with 0.5% tropicamide. A heating table (37℃) was used to maintain body temperature. ERG was recorded using a Roland Electrophysiological System (RETI-Port21, Roland Consult, Germany) with ring-shaped corneal electrodes. Three light intensities (0.01, 3.0 and 10.0 cds/m²) were applied to each animal. The following parameters were measured: a-wave amplitude and b-wave amplitude. Photopic ERG was measured at a light intensity of 3.0 cds/m² after 10 min light adaption at 25 cds/m². The responses of the Het-KO eyes (right) were compared with those of the WT eyes (right).

Immunofluorescence

Whole mouse eyes (10 weeks, littermates Het-KO and WT) were fixed with 4% para-formaldehyde (BL539A, Biosharp, China) for 1 h and 30% sucrose for dehydration overnight. Then, they were fabric-embedded in a frozen fabric matrix compound at −20℃. Prepared tissue blocks were segmented with a cryostat at a thickness of 12 microns and collected on clean adhesive slides. The slices containing the sections were air-dried at room temperature (RT) for 15 min. After washing 3× with 1× PBS for 5 min, 5% BSA (SW3015, Solarbio, China) and 0.03% triton-X100 (P0096, Beyotime, China) diluted with 1× PBS were added as permeable membrane-blocking buffers. The slides were incubated for 1 h at RT in a humid chamber. Then, they were incubated overnight at 4℃ with the specific primary antibody Zc3h11a (1:50, 26081, Proteintech, USA). PKC α (1:200, ab32518, Abcam, UK), Opsin-1 (1:200, NB110-74730, Novus Biologicals, USA) and Rhodopsin (1:200, NBP2-25160, Novus Biologicals, USA) were added and the slices were incubated further at 4℃ in a humid chamber overnight. After washing 4× with 1× PBS for 6 min, goat anti-rabbit Alexa Fluor 488 (1:500, ab150077, Abcam, UK) was added and the slides were incubated for 90 min at RT. After washing, the slides were mounted with an antifade medium containing DAPI (P0131, Beyotime, China) to visualize the cell nucleus. Sections incubated with 5% BSA and without primary antibodies were used as negative controls. A fluorescence microscope (LSM 880, ZEISS, Germany) was used to examine the slides and capture images. The experiments were repeated in duplicate with three different samples.

Transmission electron microscopy

At 10 weeks of age, two mice of each genotype were euthanized, and their eyes were removed. The eyes were fixed in a solution containing 2.5% glutaraldehyde and 0.01 M phosphate buffer (PB) (pH 7.0-7.5) for 15 min while the optic cups were dissected. The optic cups were then fixed with 1% osmium acid at room temperature away from light for 2h, after which they were rinsed three times with 0.1 MPB for 15min each time. Tissues were sequentially dehydrated in 30%-50%-70%-80%-95%-100%-100% ethanol upstream for 20 min each time, and 100% acetone twice for 15 min each time. Finally, the tissues were embedded in epoxy resin (Polybed 812) mixed 1:1 with acetone. Ultrathin sections were prepared using diamond knives and an EM UC7 ultramicrotome (Leica, Germany), then the sections were stained with 2% aqueous dioxygen acetate and 1% phosphotungstic acid (pH 3.2). Finally, the structures were examined using a transmission electron microscope (HT7700, Hitachi, Tokyo, Japan).

RNA sequencing analysis of molecular and pathway changes in the mouse retina

Mice aged four weeks were executed by cervical dislocation after CO2 asphyxiation. Then, the eyes were enucleated and dissected to obtain the entire retinas. Three eye retinas from the Zc3h11a Het-KO and WT groups were used for the mRNA sequencing experiments and performed by Biomarker Biotechnology Co. (Beijing, China). The mRNA sequences were mapped to the genome (GRCm38). WebGestalt (http://www.webgestalt.org/) was used to generate GO terms and KEGG pathways.

qRT-PCR

To determine the reliability of the transcriptome results, qPCR validation was performed. RNA was isolated using Trizol reagent (RC112, Vazyme, China), and the purity was confirmed by the OD260/280 nm absorption ratio (1.9-2.1) (Nanodrop 2000, Thermo Scientific, USA). Total RNA (2 µg) was reverse transcribed to cDNA using a cDNA Synthesis Kit (R323, Vazyme, China). qPCR was performed with a RT-PCR detection system (Applied Biosystems, California, USA) using a SYBR Premix Ex Taq Kit (Q711, Vazyme, China), according to the manufacturer’s instructions. qRT-PCR was performed (ABI-Q6, California, USA) in a 20 µL reaction, under the following conditions: 95°C for 10 min, followed by 40 cycles of amplification at 95°C for 10 s and 60°C for 60 s. Melting curve analysis was used to determine specific amplification. All experiments were performed in triplicate. Relative quantification was performed using the ΔΔCt method. The specific gene products were amplified using the following primer pairs (Table supplement 1).

Western blot

The mouse retina was separated immediately after enucleation of the eyeball and lysed in RIPA (10 mM Tris-Cl, 100 mM NaCl, 1 mM EDTA, 1 mM NaF, 20 mM Na₄P₂O₇, 2 mM Na₃VO₄, 1% Triton X-100, 10% glycerol, 0.1% sodium dodecyl sulphate and 0.5% deoxycholate) lysis buffer containing protease and phosphatase inhibitors (P1045, Beyotime, China). Equal amounts of protein (15 μg) were separated on 10% Tris-glycine gel, transferred to PVDF (polyvinylidene fluoride) membranes, and blocked with 5% skim milk. The primary antibodies used included ZC3H11A (ab99930, Abcam, UK), AKT (#4691, Cell Signaling Technology, USA), p-AKT (#4060, Cell Signaling Technology, USA), IκBα (ab32518, Abcam, UK), NF-κB (ab32536, Abcam, UK), TGF-β1 (21898, Proteintech, USA) and MMP-2 (ab92536, Abcam, UK) diluted to 1:1000 in TBST-5% milk. Then, the membranes were incubated with goat anti-rabbit IgG conjugated with HRP (1:2000 in TBST-5% milk) (SA00001-2, Proteintech, USA) for 90 min at room temperature and developed using western blotting reagents (BL523B, Bioshark, China). GAPDH (AF2823, Byotime, China) was used as the internal control.

Software and statistical analysis

All experiments were repeated at least once, and sample sizes and reported results reflect the cumulative data for all trials of each experiment. Each result is expressed as the mean ± standard deviation (SD). Pearson’s test was used to assess the normality of the data. The normally distributed data were subjected to parametric analyses. Unpaired Student’s t-tests were used for parametric analyses between two groups. Data that were not normally distributed or had a sample size that was too small, were subjected to nonparametric analyses. Nonparametric tests between two groups were performed using the Wilcoxon signed-rank test for matched pairs, the Mann-Whitney U-test or the Kruskal-Wallis test for multiple comparisons (GraphPad Prism 9, La Jolla, CA). A difference was considered statistically significant when the p-value was less than 0.05 and highly significant if it was less than 0.01 or less than 0.001.

Acknowledgements

The authors wish to thank all of the members of our lab. Additionally, we thank Xiangtian Zhou (Eye Hospital, Wenzhou Medical University) and Institute of PSI Genomics Co., Ltd for their technical assistance.

Additional information Funding

This work was supported by the National Natural Science Foundation of China (82101176), Key Research and Development Program of Zhejiang Province (2021C03102), Natural Science Foundation of Zhejiang Province (LTGD23H120002), National Key Research and Development Program for Active Health and Aging Response (2020YFC2008200), and Health Technology Plan Project in Zhejiang Province (2021KY808).

Author Contributions

Conceptualisation, Xinting Liu, Jia Qu and Fan Lu; methodology, Chong Chen and Qian Liu; data analysis, Chong Chen, Qian Liu, Cheng Tang and Yu Rong; investigation and cohort construction, Xinting Liu, Jia Qu, Fan Lu, Dandan Li and Xinyi Zhao; writing original draft preparation, Chong Chen, Qian Liu and Xinting Liu; writing-review and editing, Xinting Liu, Jia Qu and Fan Lu; funding acquisition, Xinting Liu, Jia Qu and Fan Lu. All authors have read and agreed to the published version of the manuscript.

Ethics approval

The study was approved by the Institutional Review Board of Eye Hospital, Wenzhou Medical University, Zhejiang, China (Approval number: 2019-215-K-192). Informed consent was obtained from each subject. The study was approved by the Animal Care and Ethics Committee at Wenzhou Medical University (Wenzhou, China).

Data availability

All data generated or analysed during this study are included in the manuscript and supporting files.

Supplementary files

Generation of Zc3h11a KO mice.
(A) Generation of Zc3h11a KO mice in C57BL/6J background using CRISPR/Cas9 technology. (B-C) Primers for genotyping and examples of genotyping results of Zc3h11a Het-KO mice and wild-type mice

Fundus photographs and HE staining of Het and WT mice at 8^th week.
(A. B) Fundus photographs of WT (A) and Het-KO mice (B) (n=3). (C. D) HE staining of retina in WT (C) and Het-KO mice (D) (n=3).

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Article and author information

Author information

Chong Chen
National Engineering Research Center of Ophthalmology and Optometry, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China, National Clinical Research Center for Ocular Diseases, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China, State Key Laboratory of Ophthalmology, Optometry and Visual Science, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China
- These authors contributed equally to this work.
Qian Liu
National Engineering Research Center of Ophthalmology and Optometry, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China, National Clinical Research Center for Ocular Diseases, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China, State Key Laboratory of Ophthalmology, Optometry and Visual Science, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China
- These authors contributed equally to this work.
Yu Rong
National Engineering Research Center of Ophthalmology and Optometry, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China, National Clinical Research Center for Ocular Diseases, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China, State Key Laboratory of Ophthalmology, Optometry and Visual Science, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China
Cheng Tang
National Engineering Research Center of Ophthalmology and Optometry, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China, National Clinical Research Center for Ocular Diseases, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China, State Key Laboratory of Ophthalmology, Optometry and Visual Science, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China
Xinyi Zhao
National Engineering Research Center of Ophthalmology and Optometry, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China, National Clinical Research Center for Ocular Diseases, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China, State Key Laboratory of Ophthalmology, Optometry and Visual Science, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China
Dandan Li
National Engineering Research Center of Ophthalmology and Optometry, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China, National Clinical Research Center for Ocular Diseases, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China, State Key Laboratory of Ophthalmology, Optometry and Visual Science, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China
Fan Lu
National Engineering Research Center of Ophthalmology and Optometry, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China, National Clinical Research Center for Ocular Diseases, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China, State Key Laboratory of Ophthalmology, Optometry and Visual Science, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China
- For correspondence: liuxt@eye.ac.cn; qujia@eye.ac.cn; lufan62@eye.ac.cn
Jia Qu
National Engineering Research Center of Ophthalmology and Optometry, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China, National Clinical Research Center for Ocular Diseases, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China, State Key Laboratory of Ophthalmology, Optometry and Visual Science, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China
- For correspondence: liuxt@eye.ac.cn; qujia@eye.ac.cn; lufan62@eye.ac.cn
Xinting Liu
National Engineering Research Center of Ophthalmology and Optometry, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China, National Clinical Research Center for Ocular Diseases, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China, State Key Laboratory of Ophthalmology, Optometry and Visual Science, Eye Hospital, Wenzhou Medical University, Wenzhou, 325027, China
- For correspondence: liuxt@eye.ac.cn; qujia@eye.ac.cn; lufan62@eye.ac.cn

Version history

Sent for peer review: August 9, 2023
Preprint posted: August 30, 2023
Reviewed Preprint version 1: October 23, 2023

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Significance of findings

Strength of evidence

Abstract

Introduction

Results

ZC3H11A mutations are associated with HM in a Chinese cohort

Structural modelling of ZC3H11A gene mutations.

The clinical features and mutations of affected patients

Zc3h11a Het-KO mice exhibited myopic phenotypes

Comparison of ocular biometrics and body weights of Zc3h11a Het-KO (n=14) and WT (n=10) littermates during weeks 4-10 of development.

Reduced b-wave amplitude and bipolar cell-labelled protein density in Zc3h11a Het-KO mice

Electroretinography and immunohistochemical localization of Zc3h11a, PKCα, Opsin-1 and Rhodopsin in WT and Het-KO mice eyes.

Retinal ultrastructure alterations in het-KO mice model

TEM showing the retinal ultrastructure of WT and Het-KO mice.

RNA-Seq analysis of molecular and pathways changes in Zc3h11a Het-KO mice retinas

RNA-Seq analysis of molecular and pathway differences between WT control and Het-KO retinas.

Zc3h11a negatively regulates the PI3K-AKT and NF-κB pathways

Effect of Zc3h11a on the expression of genes and proteins related to the PI3K-AKT and NF-κB signalling pathways in the retina.

TGF-β1, MMP-2 and IL-6 were increased in Zc3h11a Het-KO mice

Effect of Zc3h11a on the expression of TGF-β1, MMP-2 and IL-6 in the retina and sclera.

Discussion

Materials and methods

Ethics approval and consent to participate

Recruitment of subjects

WES and the detection of variants

Het-KO mice model construction, husbandry and ocular biometric measurements

Electroretinography

Immunofluorescence

Transmission electron microscopy

RNA sequencing analysis of molecular and pathway changes in the mouse retina

qRT-PCR

Western blot

Software and statistical analysis

Acknowledgements

Additional information Funding

Author Contributions

Ethics approval

Data availability

Supplementary files

Generation of Zc3h11a KO mice.

Fundus photographs and HE staining of Het and WT mice at 8th week.

Sequence of oligonucleotides

References

Article and author information

Author information

Chong Chen#

Qian Liu#

Yu Rong

Cheng Tang

Xinyi Zhao

Dandan Li

Fan Lu

Jia Qu

Xinting Liu

Version history

Copyright

Metrics

Fundus photographs and HE staining of Het and WT mice at 8^th week.

Chong Chen

Qian Liu