Case report: A heterozygous mutation in ZNF462 leads to growth hormone deficiency

1 Introduction

Weiss–Kruszka syndrome (WSKA) is usually characterized by mild overall developmental delays and common craniofacial abnormalities, according to the OMIM database (Amberger et al., 2019). It is a rare genetic disorder, usually associated with ZNF462 gene dysfunction, with reported autosomal dominant inheritance (Kruszka, 1993).

The ZNF462 gene is located on chromosome 9p31.2 and encodes the protein ZNF462, which belongs to the C2H2 zinc finger protein family (C2H2-ZNF) (Al-Naama et al., 2020). The function of ZNF462 is unclear, but studies have shown that it plays a key role in early embryonic development and neuronal differentiation (Laurent et al., 2009; Massé et al., 2011). ZNF462 is expressed in a graded pattern in the mouse cerebral cortex, with the strongest expression in the marginal zone, cortical plate, and subventricular zone of the cortical layer (Chang et al., 2007). Homozygous ZNF462 knockout (ZNF462−/−) has been shown to be fatal in mice, while heterozygous (ZNF462+/−) mice showed anxiety-like stunting behavior, low brain weight, and over-self-grooming; anxiety symptoms and over-self-grooming behavior were alleviated after imipramine treatment (Wang et al., 2017).

At present, 30 cases of WSKA associated with ZNF462 gene mutations have been reported. Among them, 28 studies did not investigate other genes but only the effect of ZNF462 mutation on WSKA disease. One study investigated the chromosomal rearrangement of ASXL2 and KIAA1803 in WSKA patients (Ramocki et al., 2003), and the other study reported that disrupted KLF12 and ZNF462 incurred similar WSKA symptoms (Cosemans et al., 2018). Our study reports a new mutation of ZNF462 that differs from those previously reported. We also discuss the effects of genes cooperating with ZNF462 on disease.

2 Case description2.1 Symptoms and physical and routine examination

A boy aged 8 years and 6 months came to the Affiliated Hospital at Kunming University of Science and Technology (the First People’s Hospital of Yunnan Province) for evaluation of growth retardation. His parents are non-consanguineous. The proband was born via spontaneous vaginal delivery at 40 weeks, with birth length 50.0 cm (27.3rd) and weight 2.8 kg (5.3rd). He has no brothers or sisters. The heights of his father and mother are 167.0 cm and 157.0 cm, respectively.

At the first visit, the height of the proband was 126.5 cm (14.0th), weight 34.1 kg, and BMI 21.3 kg/m2 (obese). He had a metopic ridge, arched eyebrows, bilateral ptosis, epicanthal folds, down-slanting palpebral fissures, a short upturned nose with a bulbous tip, and a marked cupid bow (Supplementary Figure S1). The ears were low-set, but his hearing was normal. There was no significant difference between the patient and his peers in speech or motor development, and no feeding difficulties or snoring problems. The proband has no other congenital abnormalities except cryptorchidism. There is no history of ptosis, dwarfism, or intellectual disability in other family members.

Upon the proband’s routine inspection, his liver, kidneys, electrolytes, blood fat, and thyroid were normal. Testing revealed a FSH of 1.45 mIU/ml (3.5–12.5 mIU/ml), LH < 0.100 pmol/L (1.24–8.62 pmol/L), E2 42.35 pmol/L (20–75 pmol/L), Prog 0.452 nmol/L, PRL 10.68 ng/ml, and T < 0.087 pmol/L. Serum 25 hydroxyvitamin D was 15.07 ng/ml (>30 ng/ml), and PTH was 49.1 pg/ml (14–72 pg/ml). The serum IGF-1 and IGFBP-3 levels were 174 ng/ml (64.00–358.00 ng/ml) and 4.09 ng/ml (1.6–6.5 ng/ml), respectively. A growth hormone excitation test with levodopa combined with arginine was conducted, and it produced a peak of 1.35 ng/ml, indicating complete growth hormone deficiency (GHD).

His bone age was 1.6 years older than his chronological age. According to his bone age and other elements, his final height should be 156.8 cm (<3rd percentile of the normal heights of peers in the same area). Cranial magnetic resonance imaging (MRI) showed demyelinating changes in both parietal lobes, but the structures of the corpus callosum and pituitary gland were intact. Sleep monitoring indicated obstructive sleep apnea (OSA). Bone mineral density (BMD) was normal (Z:1.4). Fundus examination and echocardiography were normal.

The patient was evaluated by Wechsler intelligence assessment and Chinese children cognitive system. The comprehensive score of cognitive ability was 78 points that was lower than the average of his peers, and his cognitive level was located at the lowest 7.0% level of his peers. The results of the patient’s comprehensive attention test showed that the patient had attention deficit hyperactivity disorder (ADHD).

2.2 Materials and methods2.2.1 Sample information and sequencing profiles obtained

Peripheral blood samples from the patient were collected at the First People’s Hospital of Yunnan Province. Whole-exon sequencing was performed by Beijing Golden Gene Technology Co., Ltd. The obtained exon sequencing has been stored in the NCBI SRA database under the accession number SRR18969535.

2.2.2 Analysis of the exon sequencing profile to identify genomic mutations

FastQC (Andrews, 2010) was used to check the sequencing quality of the obtained whole-exon sequencing data, and clean reads were obtained by fastp (Chen et al., 2018). BWA (v0.7.5a-r405) (Richard & Heng, 2009) was used to align the clean reads of the sequencing file to human genome sequences (hg38) downloaded from the UCSC Genome Browser (Kent et al., 2002). The resulting SAM file was converted to a BAM file using SAMtools (Li et al., 2009). Next, the BAM file was sorted with SAMtools and used to identify mutations with GATK (v4.2.1.0) (McKenna et al., 2010). Briefly, the MarkDuplicates program was used to remove PCR duplicates; BaseRecalibrator and ApplyBQSR were used to recalibrate the base quality score; and then, Mutect2 was used to identify mutations in exons and to produce a VCF file of the identified mutations. Then, ANNOVAR (v20200607) (Wang et al., 2010) was used to annotate the VCF file to obtain the gene mutations.

2.2.3 Verification of the new mutation in ZNF462

Whole-blood samples from the patient and his parents were collected. Then, the DNA samples were extracted and sequenced by Sanger sequencing. The obtained sequences were aligned to the human genomic sequence (hg38) with BLASTN (Altschul et al., 1990). A heterozygous insertion of adenosine was found in the seventh exon of the ZNF462 gene by manual examination with IGV (Thorvaldsdottir et al., 2013). The protein–protein interaction network of ZNF462 was studied using STRING (v11.5) (Szklarczyk et al., 2021).

The reported mutations in ZNF462 were manually retrieved from the literature. Then, 30 reported mutations in ZNF462 and the new mutation in ZNF462 identified in this study were visualized with trackViewer (v1.6.1) (Ou & Zhu, 2019).

2.2.4 GO term analysis for ZNF462 and its interacting proteins

Gene Ontology (GO) enrichment analysis of ZNF462 and its interacting proteins was performed with KOBAS (v3.0) (Bu et al., 2021). The obtained GO terms were grouped into three major categories: molecular function, cellular component, and biological process. The top 10 GO terms with the smallest multiple test-corrected p-values in these three categories were chosen for visualization.

2.3 Results2.3.1 Characterizing the genomic mutations of the patient

To obtain a molecular diagnosis, exon sequencing was performed for the patient. Figure 1A shows the high-throughput sequencing reads for the seventh exon of the patient’s ZNF462 gene, where 54% of these sequences carried the A insertion (or duplication), suggesting a heterozygous mutation at the A insertion site in the patient. Using GATK to analyze the exon sequencing data revealed an insertion of adenosine at the seventh exon of the ZNF462 gene [NM_021224.6: c.6311dup; p. (Val2105GlyfsTer32)] (Figure 1B). Then, we sequenced the same genomic regions in the patient and his parents with Sanger sequencing (Figures 1C–E). In the Sanger sequencing results for the patient, there were continuous secondary peaks from the insertion site of adenosine (red oval in Figure 1C), suggesting two different sequences for the heterozygous insertion site of adenosine. However, as shown in Figures 1D,E, the Sanger sequencing of the mother and father clearly indicated no mutations. As shown in Figure 1F, due to a code shift introduced by the additional adenosine, valine (Val) at the 2105th amino acid was transformed into glycine (Gly); the subsequent 32 amino acids were encoded incorrectly and terminated prematurely. Therefore, the heterozygous A insertion may lead to a half-loss of functional ZNF462 protein in the patient. The mutation (NM_021224.6:c.6311dup) was not a reported SNP after being compared to dbSNP (v153) Figure 1G.

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FIGURE 1. Identified mutation locus of ZNF462 in the patient. (A) Locus of the adenosine insertion in ZNF462 and the exome sequencing reads at the locus. The reads marked with purple “I”s are those with the adenosine insertions. (B) Insertion of adenosine occurs in the seventh exon of ZNF462 (NM_021224.6). (C–E) Sanger sequencing results of the patient and his parents. Red ovals indicate the insertion site of adenosine. (F) Amino acid sequences of ZNF462 without (up) and with the adenosine insertion (down). In the mutated ZNF462 amino acid sequence, the adenosine insertion causes a variation from Val to Gly and different subsequent amino acids, and introduces premature translation terminations. (G) When compared with the dbSNP (r153) in the UCSC Genome Browser, the identified insertion site of adenosine was not a known SNP, as indicated by the red rectangle.

2.3.2 The protein–protein interaction network of ZNF462

We next examined the interacting proteins of ZNF462 with STRING (v11.5) (Talisetti et al., 2003), as shown in Figure 2A. To determine the function of the ZNF462 protein and its interacting proteins, GO enrichment analysis was used with KOBAS. The top GO terms for these genes are “polyubiquitin modification-dependent protein binding,” “RNA polymerase II complex binding,” “proteasome binding,” “metal ion-binding,” “peroxisome proliferator-activated receptor binding,” “3′-5′ exonuclease activity,” “DNA binding,” and “RNA polymerase II intronic transcription regulatory region sequence-specific DNA binding,” as shown in Figure 2B.

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FIGURE 2. Proteins interacting with ZNF462 and mutations in ZNF462. (A) Proteins interacting with ZNF462. STRING (v 11.5) was used to prepare the figure. (B) Enriched GO terms for genes in (A). Only top GO terms were shown, and details are provided in Materials and Methods. (C) Reported mutations in ZMF462 that are related to WSKA. The blue mutation is the one newly identified in this study. See Supplementary Table S1 for details. (D) Diseases and symptoms caused by genetic mutations in ZNF462, VPS13B, and ASXL2. Common symptoms of at least two diseases are shown in blue.

We also manually retrieved the previously reported ZNF462 mutations related to WSKA, then visualized them with the mutation newly identified in this study (Figure 2C). Most reported mutations are located in the third exon of ZNF462 (details in Supplementary Table S1). The new mutation identified in this study is located in the seventh exon of the ZNF462 gene.

Among the proteins interacting with ZNF462, the ASXL2 gene encodes a member of the epigenetic regulator family that binds various histone modification enzymes and participates in the assembly of transcription factors at specific genomic sites (Lai & Wang, 2013). Recent studies have found that pathogenic mutations in the ASXL2 gene could lead to Shashi–Pena syndrome, which is characterized by facial abnormalities and developmental delays (Shashi et al., 2016) (Figure 2D). ASXL2-deficient mice showed weight loss, enlarged hearts, and skeletal abnormalities (Baskind et al., 2009). Chromosome translocation t (2; 9) leads to a fused transcript of ASXL2 and KIAA1803, resulting in a complex phenotype of the corpus callosum, ocular colobomas, and periventricular ectopic dysplasia (Ramocki et al., 2003). Weiss et al. (2017) have suggested that ZNF462 and ASXL2 might work together in the WSAK phenotype.

VPS13B is another protein interacting with ZNF462 (Figure 2A). Mutations in the VPS13B gene have been associated with Cohen’s syndrome, a rare autosomal recessive syndrome associated with a variety of clinical manifestations including growth retardation, hypotonia, joint hyperactivity, microcephaly, intellectual impairment, and craniofacial and limb abnormalities (Cohen et al., 1973) (Figure 2D). The VPS13 protein family is involved in vesicular transportation and membrane events (Kolehmainen et al., 2004). To date, more than 150 VPS13B mutations have been reported in more than 200 patients with Cohen syndrome (Momtazmanesh et al., 2020).

VAX1 interacts with both ZNF462 and ASXL2 (Figure 2A). Heterozygous deletion of Vax1 leads to infertility in mice and irregular estrous cycles in female mice (Hoffmann et al., 2014).

These results suggest that mutations in other genes interacting with ZNF462 (Figure 2A) may result in symptoms similar to WSKA (Figure 2D). We hypothesize that ZNF462 and its interacting proteins may form a protein complex that is important for normal development and which awaits more studies to reveal its detailed functions.

3 Diagnosis and treatment

In summary, the patient was diagnosed with WSKA syndrome, GHD, dwarfism, intellectual disability, and ADHD. The proband had bilateral cryptorchidism and underwent surgery 3 months later. To promote his height growth, the proband received 3.4U/day (0.1 U/kg/day) subcutaneous injections of recombinant human growth hormone (rhGH). However, the IGF of this patient significantly increased and exceeded the normal range after normal and even lower usage of rhGH (Table 1). Considering the side effects of high IGF-1 levels, the patient discontinued rhGH treatment, and the IGF-1 dropped to the normal range. Finally, the patient had grown 6.5 cm in 7 months during the rhGH injections. After stopping the rhGH injections, the patient only grew 1 cm in 3 months. The patient was therefore given rhGH again, and his ADHD improved after using tomoxetine.

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TABLE 1. Timeline with relevant data from the episode of care.

4 Discussion

The patient showed growth retardation associated with GHD, but his level of IGF-1 and advanced bone age were inconsistent with the clinical symptoms of GHD. We speculate that the patient was IGF-1-insensitive and that a mutation in his ZNF462 gene caused WSKA, a rare genetic disease often accompanied by growth retardation, craniofacial malformation, and/or corpus callosum dysplasia (González-Tarancón et al., 2020).

Since the first case of WSKA was reported in 2003 (Talisetti et al., 2003), only 30 patients have been reported. According to Table 2, most of them (74%) have some type of developmental delay, with speech delay being the most common, accounting for 42%, and motor delay being the second, noticed in 39% of patients. Almost half of patients have hypotonia, which is a contributor to motor delay. A few of them (16%) have intellectual disabilities. It cannot be ignored that 39% of patients have feeding problems.

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TABLE 2. Common clinical manifestations and frequency of WSKA patients.

We found that common craniofacial features include ptosis (87%), down-slanted palpebral fissures (58%), exaggerated cupid bow/wide philtrum (58%), arched eyebrows (52%), ear malformation/hearing loss (52%), short upturned nose with bulbous tip (45%), metopic ridging/craniosynostosis (45%), and epicanthal folds (42%). Corpus callosum dysgenesis is the most frequent manifestation of craniocerebral dysplasia, which is also considered to be a typical manifestation of WSKA but occurs in only 23% of patients.

Twenty-six percent of patients have autism spectrum disorder (ASD), which is consistent with the idea that ZNF462 disorder is an independent risk factor for autism (Krumm et al., 2015). However, this patient shows ADHD, which may be related to the demyelination of white matter in the parietal lobe (Silk et al., 2009). However, patients 5, 8, and 28 also have attention disorder. Furthermore, ASD, attention deficit, and ADHD have high rates of co-occurrence (Ohta et al., 2020). Therefore, the patient’s ADHD might be caused by his ZNF462 genetic mutation.

Seventy-four percent of WSKA patients have developmental delay, but only 12 patients had their height described. The patient identified in this study has WSKA with GHD, which is similar to the patient reported by Park et al. (2021). However, Park reported a patient with low bone age, empty sella syndrome, adenohypophysis dysfunction, and delayed puberty, while our patient’s pituitary structure is intact (Park et al., 2021). It may be that the ZNF462 mutation is responsible for the lack of growth hormone in WSKA patients, rather than the structural and functional dysfunction of the pituitary gland.

The patient identified in this study has a mutation at 9p31.2 on the ZNF462 gene and shows GHD and short stature. Meanwhile, he presented with ptosis, arched eyebrows, down-slanting palpebral fissures, a short upturned nose with a bulbous tip, a marked cupid bow, and ADHD. This is the first report of a ZNF462 gene mutation in patients with GHD but no pituitary lesions. It also provides new insights into endocrine symptoms related to dwarfism. When patients present with GHD and these craniofacial features, we should suspect WSKA.

Data availability statement

The data presented in the study are deposited in the NCBI SRA repository, accession number SRR18969535.

Ethics statement

The studies involving human participants were reviewed and approved by the Ethics Committee of the First People’s Hospital of Yunnan Province. Written informed consent to participate in this study was provided by the participant’s legal guardian/next of kin. Written informed consent was obtained from the individual(s) and minor(s)’ legal guardian/next of kin for the publication of any potentially identifiable images or data included in this article.

Author contributions

YiZ and YuZ: conceived and designed this study; YiZ: clinical diagnosis, examinations of the patient, and collection of the clinical samples; JL and SW: writing of the original draft, analyzing sequencing data, and preparing figures; YiZ, YuZ, SW, and WL: writing and revision.

Funding

This work was supported by the Yunnan Provincial Department of Science and Technology and Kunming Medical University Joint Foundation for Applied Basic Research (No. 202001AY070001-119) and Yunnan Clinical Medical Center Open Project (No. 2019LCZXKF-NM07) to YiZ, as well as a grant from the National Natural Science Foundation of China (No. 31460295) and an Open Research Fund (No. SKLGE-2107) from the State Key Laboratory of Genetic Engineering, Fudan University, China to YuZ.

Conflict of interest

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher’s note

All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors, and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.

Supplementary material

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fgene.2022.1015021/full#supplementary-material

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