A 2-month-old male infant was referred to the Pediatric Endocrine Department of Guangxi Maternal and Child Health Hospital for skin hyperpigmentation and developmental delay on April 20th, 2018. Written informed consent for the infant and his parents was obtained from the infant's parents. The present study was approved by the Medical Ethics Committee of Guangxi Maternal and Child Health Hospital. Abdominal ultrasound was applied to assess the presence of hepatomegaly, and cardiac function was assessed by echocardiography and electrocardiography. Blood glucose, blood lipid and C-peptide levels were determined as previously reported (8). Serum insulin and sex hormone levels were measured by electrochemical luminescence immunoassay (Cobas E601; Roche Diagnostics).

Genomic DNA was extracted from 2 ml peripheral blood of the infant and his parents in accordance with the standard method of the Lab-Aid^® DNA extraction kit (Xiamen Zeesan Biotech Co, Ltd.). Human exome sequencing libraries were constructed using Agilent SureSelect Human All Exon V5 kit (Agilent Technologies, Inc.), and generated amplicons were sequenced with Illumina HiSeq 2500 system (Illumina, Inc.). After sequencing, reads were aligned to an indexed human reference genome (GRCh37/hg19) with Burrows-Wheeler transformation 0.7.15-r1140 (9). Duplicate reads were removed using Picard v.1.85 (http://picard.sourceforge.net) before further processing. Base recalibration and variant calling were performed using the Genome Analysis Toolkit v.2.3-4Lite (10). Finally, identified variants were saved in variant call format. In addition, in the present study there was an attempt to reveal CNVs with a read depth-based CNV detection algorithm. Translational Genomics Expert (LifeMap Sciences, Inc.) was used for variant prioritization. Integrative Genomics Viewer 2.4.15 (IGV 2.4.15) was used to visualize WES data and assess the coverage of the exons (http://software.broadinstitute.org/software/igv/). Variants detected in the infant, but absent in the ClinVar (www.ncbi.nlm.nih.gov/clinvar/), Human Gene Mutation Database (www.hgmd.cf.ac.uk/ac/), Single Nucleotide Polymorphism Database (dbSNP; www.ncbi.nlm.nih.gov/SNP), 1000 Genomes Project database (http://www.internationalgenome.org/1000-genomes-browsers/), Ensembl (http://grch37.ensembl.org/index.html) and Genome Aggregation Database 2.1 (gnomAD 2.1; http://gnomad.broadinstitute.org) were considered novel variants (11).

Sanger sequencing was performed to confirm the variant identified by WES. Specific primers for amplification and sequencing were designed in Primer3web version 4.1.0 (http://primer3.ut.ee/). The primer sequences of BSCL2 exon 6 were as follows: forward, 5′-CTACTCAGGGGTGGTTGAGG-3′ and reverse, 5′-CCCCACTTCCAGTCTCTCAG-3′. A pair of primers encompassing exon 3 was used to determine the breakpoints (BSCL2_BP3-forward: 5′-TCCCTTAAGTCCCTGGTCCA-3′; BSCL2_BP3-reverse: 5′-ACATTTCTAACACCTGCTGCAG-3′). The PCR product was sequenced with the 3730×l Genetic Analyzer (Applied Biosystems; Thermo Fisher Scientific, Inc.). Sequence data were aligned with the consensus coding sequence [human genome assembly 37 in nucleotide Basic Local Alignment Search Tool (BLAST; http://blast.ncbi.nlm.nih.gov/blast/)]. Mutation Surveyor software (https://softgenetics.com/mutationSurveyor.php; version 4.0.4) was used in visualizing the sequences.

To confirm the suspected exon 3 deletion in BSCL2, MLPA probes were designed and validated following a previous method (12) and the protocol from MRC-Holland BV (https://support.mlpa.com/downloads/files/designing-synthetic-mlpa-probes). A total of 11 pairs of MLPA probes were designed for BSCL2 (Table SI). These probes were dissolved and diluted in TE buffer, then added to the P200 reference probe mix, which was purchased from MRC-Holland BV and included reference probes and control fragments. The MLPA experiment was performed in accordance with the manufacturers' protocols, with MLPA reagents provided by MRC-Holland BV. Capillary electrophoresis was performed with the 3130 Genetic Analyzer (Applied Biosystems; Thermo Fisher Scientific, Inc.), and data were analyzed with Coffalyser (https://www.mrcholland.com/).

The infant was the second child born to nonconsanguineous healthy parents. He was a full-term baby with normal delivery, and he had a healthy sister. His weight was 2,500 g (−1 SD) at birth and 3,900 g (−3 SD, which indicates that the weight of the infant was lower than healthy infants) at 2 months. He had a thin appearance and advanced bone age (3 months). Generalized lipoatrophy and skin hyperpigmentation were observed. Moreover, he had a triangular face, marked umbilical prominence, a long and large penis, and a swollen right scrotum (Fig. 1). Echocardiography and abdominal ultrasound indicated atrial septal defect and hepatomegaly, respectively, and no splenomegaly. Liver function tests were normal. Other abnormal biochemical examinations were as follows: Insulin and C-peptide levels were elevated [956.6 pmol/l, normal range (NR): 17.8–173 pmol/l and >21.85 ng/ml, NR: 1.1–4.4 ng/ml, respectively], which indicated insulin resistance. The triglyceride level was increased (26.63 mmol/l, NR: 0.56–1.70 mmol/l), whereas the levels of high-density lipoprotein cholesterol (0.52 mmol/l, NR: 1.16–1.55 mmol/l), low-density lipoprotein cholesterol (2.36 mmol/l, NR: 2.70–3.13 mmol/l), apolipoprotein A1 (0.52 g/l, NR: 1.20–1.60 g/l), and apolipoprotein B (0.67 g/l, NR: 0.80–1.05 g/l) were all decreased, indicating hypertriglyceridemia. Sex hormone levels were decreased also (testosterone: 0.85 ng/ml, NR: 1.75–7.81 ng/ml; estradiol: 5.00 pg/ml, NR: 20.00–75.00 pg/ml).

WES revealed a c.545_546insCCG heterozygous variant in exon 6 of the BSCL2 gene (GenBank accession no. NM_032667.6). This variant was confirmed by Sanger sequencing (Fig. 2B). It led to a disruptive inframe indel at position 182 (p.Glu182delinsAspArg). The variant was inherited from the mother. This variant has been documented in the dbSNP database (rs747297291) and at an extremely low frequency in the gnomAD database. It has been detected in trans with a pathogenic variant in a Chinese patient with CGL (13), indicating that it is a recurrent pathogenic variant in the Chinese population.

There were no additional SNVs detected in BSCL2 or any other rare SNVs that could explain the phenotypes. CNV assessment by the visual review of BSCL2 coverage using the IGV browser suggested a heterozygous deletion at 11q12.3 (62,469,824-62,470,137) involving exon 3 of BSCL2 (Fig. 2A). To confirm this heterozygous deletion, MLPA probes covering exon 3 of BSCL2 and other control regions were designed. The copy number ratios of the BSCL2 exon 3 of the infant, his father and his mother were 0.65, 0.62 and 1.01, respectively (Fig. 2C), indicating the presence of an Ex3del in the infant and his father. The Ex3del was a null variant and absent in the dbSNP, the 1000 Genomes Project database, Ensembl, gnomAD and local normal controls. Notably, a similar exon 3 deletion has been reported as a founder mutation in Peruvian patients with CGL (7).

Gap-PCR was performed to further confirm and map the exact breakpoints of the exon 3 deletion. As revealed in Fig. 3A, a 483-bp amplicon that represented the deleted allele was present in the proband and in the father but not in the mother. Sequencing this amplicon confirmed the deletion and revealed the breakpoints of a 1,274 bp deletion (chr11:62,469,829-62,471,102; c.213-1081_c.294+111), including complete exon 3 and part of introns 2 and 3 (Fig. 3B and C). An 11-bp microhomology was identified at the breakpoints. Thus, this deletion is different from the founder deletion variant detected in Peruvian patients with CGL (7). The deletion would lead to a frameshift and premature termination (p.Thr72Cysfs*2) that is predicted to result in nonsense-mediated mRNA decay.

The maternally inherited variant c.545_546insCCG is rare in the general population (PM2) (13,14). It has been reported in trans with a pathogenic variant at least twice (PM3_Strong) and shortens the protein product (PM4) (13). The patient's phenotype is consistent and specific with CGL (PP4). This variant is classified as likely pathogenic on the basis of ACMG/AMP guidelines for variant classification (15). In the present study, it was speculated that Ex3del was a loss-of-function variant (PVS1) that was absent from the general population (PM2), and PP4 was also applicable; thus, it can be classified as pathogenic.