Pathogenic relationship between phenotypes of ARPKD and novel compound heterozygous mutations of PKHD1.

Background: To investigate whether the novel mutation of PKHD1 could cause polycystic kidney disease by affecting splicing with a recessive inheritance pattern. Methods: A nonconsanguineous Chinese couple with two recurrent pregnancies showed fetal enlarged echogenic polycystic kidney and oligoamnios were recruited. Pedigree WES, minigene splicing assay experiment and following bioinformatics analysis were performed to verify the effects, and inheritance pattern of diseasing-causing mutations. Results: WES revealed that both fetuses were identified as carrying the same novel mutation c.3592_3628 + 45del, p.? and c.11207 T>C, p.(Ile3736Thr) in the PKHD1 gene (NM_138694.4), which inherited from the father and mother respectively. Both bioinformatic method prediction and minigene splicing assay experience results supported the mutation c.3592_3628 + 45del, p.? affects the splicing of the PKHD1 transcript, resulting in exon 31 skipping. Another missense mutation c.11207 T>C, p.(Ile3736Thr) has a low frequency in populations and is predicted to be deleterious by bioinformatic methods. Conclusion: These findings provide a direct clinical and functional evidence that the truncating mutations of the PKHD1 gene could lead to more severe phenotypes, and cause ARPKD as a homozygous or compound heterozygous pattern. Our study broadens the variant spectrum of the PKHD1 gene and provides a basis for genetic counseling and diagnosis of ARPKD.

[Analysis of a child with developmental disorder and epilepsy due to a homozygous variant of SLC25A12 gene].

OBJECTIVE: To explore the genetic basis for a child featuring global developmental delay and epilepsy. METHODS: A child who had presented at Guangzhou Women and Children's Medical Center Liuzhou Hospital on February 19, 2023 was selected as the study subject. Clinical data of the child was collected. The child was subjected to whole exome sequencing, and candidate variant was validated by Sanger sequencing and bioinformatic analysis. RESULTS: The child, an 8-month-old girl, had manifested with global developmental delay, epilepsy, and hyperlactacidemia. Cranial MRI revealed diverse hypomyelinating leukodystrophies. Electroencephalogram showed slow background activities. Genetic testing revealed that she has harbored a homozygous variant of the SLC25A12 gene, namely c.115T>G (p.Phe39Val), for which both of her parents were heterozygous carriers. Based on the guidelines from the American College of Medical Genetics and Genomics, the variant was predicted to be of uncertain significance (PM2_Supporting+PM3_Supporting+PP3_Moderate+PP4_Moderate). I-Mutant v3.0 software predicted that the variant may affect the stability of protein product. CONCLUSION: The homozygous c.115T>G (p.Phe39Val) variant of the SLC25A12 gene probably underlay the pathogenesis of the disease in this child.

Improved Genetic Characterization of Congenital Adrenal Hyperplasia by Long-Read Sequencing Compared with Multiplex Ligation-Dependent Probe Amplification Plus Sanger Sequencing.

Genetic analysis of congenital adrenal hyperplasia (CAH) has been challenging because of high homology between CYP21A2 and its pseudogene CYP21A1P. This study aimed to evaluate the clinical utility of long-read sequencing (LRS) in diagnosis of CAH attributable to 21-hydroxylase deficiency by comparing with multiplex ligation-dependent probe amplification plus Sanger sequencing. In this retrospective study, 69 samples, including 49 probands from 47 families with high-risk of CAH, were enrolled and blindly subjected to detection of CAH by LRS. The genotype results were compared with control methods, and discordant samples were validated by additional Sanger sequencing. LRS successfully identified biallelic variants of CYP21A2 in the 39 probands diagnosed as having CAH. The remaining 10 probands were not patients with CAH. Additionally, LRS directly identified two pathogenic single-nucleotide variations (SNVs; c.293-13C/A>G and c.955C>T) in the presence of interference caused by nearby insertions/deletions (indels). The cis-trans configuration of two or more SNVs and indels identified in 18 samples was directly determined by LRS without family analysis. Eight CYP21A1P/A2 or TNXA/B deletion chimeras, composed of five subtypes, were identified; and the junction sites were precisely determined. Moreover, LRS determined the exact genotype in two probands who had three heterozygous SNVs/indels and duplication, which could not be clarified by control methods. These findings highlight that LRS could assist in more accurate genotype imputation and more precise CAH diagnosis.

Optimizing peripheral blood chromosome analysis: effects of refrigeration time and blood volume.

OBJECTIVE: This study aims to investigate the impact of refrigeration time and blood volume on the success rate of peripheral blood chromosomal analysis using response surface methodology (RSM). METHODS: Peripheral blood samples from 30 volunteers were subjected to chromosomal analysis under different refrigeration duration periods (≤7 days, 8 days, 9 days, 10 days, 11 days, 12 days, 13 days, 14 days) along with different blood volumes (0.2 mL, 0.3 mL, 0.4 mL, 0.5 mL, 0.6 mL, 0.7 mL, and 0.8 mL). The effects of refrigeration time and blood volume on the success rate of peripheral blood chromosomal analysis were determined using the Chi-square test for trend, followed with Spearman's rank correlation coefficient, and RSM analysis to identify the optimal combination of refrigeration time and blood volume. RESULTS: The refrigeration time within 10 days had a minor impact on the success rate, while refrigeration time more than 11 days significantly decreased the success rate. An increase in blood volume slightly improved the success rate. The success rate showed both linear and nonlinear changes with refrigeration time, while the effect of blood volume was primarily linear. The highest success rate was observed at a refrigeration time of ≤7 days and a blood volume of 0.8 mL. The interaction between refrigeration time and blood volume had a significant impact on the success rate. CONCLUSION: It is recommended to keep the refrigeration time of blood samples within 7 days and control the blood volume at 0.8 mL to maximize the success rate of chromosomal analysis.