A novel 2.4-kb PHKA2 deletion in a boy with glycogen storage disease type IXa

IF 1.3 4区 医学 Q3 PEDIATRICS
Takeshi Sato, Yosuke Ichihashi, Hideo Sugie, Tomohiro Ishii, Tomonobu Hasegawa
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His birth length and weight were 48.4 cm (−0.29 SD) and 2.81 kg (−0.42 SD), respectively. Short stature was noted at 15 months of age; at 18 months, he could not stand alone and motor delay was suspected. He was referred to our hospital at 23 months with length and weight of 79.0 cm (−2.2 SD) and 10.5 kg (−0.82 SD), respectively. He could walk with aid and speak meaning words. Physical examination showed a doll-like appearance, abdominal distension, and hepatomegaly. Laboratory examinations showed as follows: white blood cells, 8800/μL (neutrophils 1584/μL); aspartate aminotransferase, 899 U/L; alanine aminotransferase, 554 U/L; creatine kinase 60 U/L; alkaline phosphatase 966 U/L (age matched reference, 395–1339); γ-glutamyl transpeptidase 374 U/L (reference, 6.5–60.0); creatinine, 0.13 mg/dL; uric acid, 7.0 mg/dL. Fasting glucagon loading test showed glucose of 42 mg/dL (before loading) and 64 mg/dL (60 min after loading). Two-hour postprandial glucagon loading test showed glucose of 131 mg/dL (before loading) and 191 mg/dL (30 min after loading). Oral glucose tolerance tests showed basal lactate and pyruvate levels of 7.0 and 0.61 mg/dL, respectively, and peak lactate and pyruvate levels of 32.2 mg/dL (90 min after loading) and 3.03 mg/dL (30 min after loading), respectively. Computed tomography showed hepatomegaly with high density. Phosphorylase kinase enzyme analysis of red blood cells revealed 0.3 nmoL/min/gHb, compared to 9.1 and 10.1 nmoL/min/gHb in two healthy subjects. We thus diagnosed him as having GSD IXa. After obtaining informed consent from his parents, genomic DNA was extracted from peripheral blood samples of the proband and his mother. We tried to amplify all exons and the flanking introns of the exons in <i>PHKA2</i> (NM_000292.3) in the proband, but we obtained no polymerase chain reaction (PCR) products of exons 20 and 21. We designed several new forward primers located at the intron intervening exons 19 and 20 and the reverse primer located at exon 22. Using these primers, we performed PCR using DNA from the proband or his mother and obtained the products, with the size at 500–650 bp from the proband and 3000 bp and 500–650 bp from his mother (Figure 1A). The PCR products in the proband were subjected to direct sequencing from both directions on the autosequencer. We identified a 2423 base deletion in <i>PHKA2</i> [NC_000023.11(NM_000292.3):c.2226+9_2360+360del] encompassing 134 nucleotides of exon 21 and a breakpoint with imperfect 8- to 9-bp and perfect 3- to 4-bp similar nucleotide sequences near the junction (Figure 1B). This 2.4-kb deletion has not been reported previously in patients with GSD IXa and was not found in the following databases: gnomAD SVs v4 (https://gnomad.broadinstitute.org/), 8.3KJPN-SV, and JSV1 databases (https://jmorp.megabank.tohoku.ac.jp/); however, one study reported a patient with the deletion of exon 21 in <i>PHKA2</i> detected by multiple ligation-dependent probe amplification.<span><sup>2</sup></span> No other pathogenic alterations were identified. Complementary DNA analysis in the proband revealed the skipping of exon 21, indicating that the deletion introduced a premature stop codon, p.Pro789Serfs*21 (Figure 1C). We speculate that this variant would trigger nonsense-mediated mRNA decay, based on a previous study using hepatocyte-like cells generated from the dermal fibroblast cell line of a male patient with <i>PHKA2</i> c.2597+5G&gt;T, showing (i) the variant resulted in an aberrant splicing of <i>PHKA2</i> and the incorporation of a 27 bp into exon 23 with the immediate presence of a stop codon, (ii) <i>PHKA2</i> mRNA was down-regulated 7- to 11-fold, and (iii) mutant <i>PHKA2</i> protein expression was absent.<span><sup>3</sup></span></p><p>A previous study suggested that Alu-mediated recombination causes a 10-kb deletion of several exons in <i>PHKA2</i>.<span><sup>4</sup></span> To our knowledge, other mechanisms causing <i>PHKA2</i> microdeletions are unknown. In some diseases, microhomology at the junctions is considered to cause microdeletions through DNA rearrangement.<span><sup>5, 6</sup></span> Notably, in Duchenne and Becker muscular dystrophies, exon deletions within <i>DMD</i> occur possibly via microhomology of 2–5 bp at the junctions.<span><sup>6</sup></span> We speculate that microhomology, “gta” or “agta,” may have played an important role in DNA rearrangement in our patient. Meanwhile, the presence of imperfect direct repeats at mtDNA deletion breakpoints raised the possibility that our patient's imperfect 8- to 9-bp sequence may also contribute to the pathogenicity.<span><sup>7, 8</sup></span></p><p>In summary, we identified a novel 2.4-kb deletion in the <i>PHKA2</i> gene in a patient with GSD IXa. This case implies that DNA rearrangement via perfect and/or imperfect sequences may cause <i>PHKA2</i> microdeletion.</p><p>This study was supported by Novo Nordisk Pharma Ltd. and JCR Pharmaceuticals Co., Ltd.</p><p>The authors declare no conflicts of interest.</p><p>This study has been approved by the ethical committee at Keio University School of Medicine (20170130). 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引用次数: 0

Abstract

Glycogen storage disease type IXa (GSD IXa) results from a defect in the alpha subunit of phosphorylase kinase encoded by PHKA2 with X-linked inheritance. Clinical manifestations include fasting hypoglycemia, hepatomegaly, and growth failure. Various PHKA2 pathogenic variants have been reported, including microdeletions.1 To date, few breakpoints have been identified, and mechanisms causing microdeletions are not well understood. We report on a pediatric patient with GSD IXa and a novel microdeletion in PHKA2.

The male proband was the first child of healthy, non-consanguineous Japanese parents. His birth length and weight were 48.4 cm (−0.29 SD) and 2.81 kg (−0.42 SD), respectively. Short stature was noted at 15 months of age; at 18 months, he could not stand alone and motor delay was suspected. He was referred to our hospital at 23 months with length and weight of 79.0 cm (−2.2 SD) and 10.5 kg (−0.82 SD), respectively. He could walk with aid and speak meaning words. Physical examination showed a doll-like appearance, abdominal distension, and hepatomegaly. Laboratory examinations showed as follows: white blood cells, 8800/μL (neutrophils 1584/μL); aspartate aminotransferase, 899 U/L; alanine aminotransferase, 554 U/L; creatine kinase 60 U/L; alkaline phosphatase 966 U/L (age matched reference, 395–1339); γ-glutamyl transpeptidase 374 U/L (reference, 6.5–60.0); creatinine, 0.13 mg/dL; uric acid, 7.0 mg/dL. Fasting glucagon loading test showed glucose of 42 mg/dL (before loading) and 64 mg/dL (60 min after loading). Two-hour postprandial glucagon loading test showed glucose of 131 mg/dL (before loading) and 191 mg/dL (30 min after loading). Oral glucose tolerance tests showed basal lactate and pyruvate levels of 7.0 and 0.61 mg/dL, respectively, and peak lactate and pyruvate levels of 32.2 mg/dL (90 min after loading) and 3.03 mg/dL (30 min after loading), respectively. Computed tomography showed hepatomegaly with high density. Phosphorylase kinase enzyme analysis of red blood cells revealed 0.3 nmoL/min/gHb, compared to 9.1 and 10.1 nmoL/min/gHb in two healthy subjects. We thus diagnosed him as having GSD IXa. After obtaining informed consent from his parents, genomic DNA was extracted from peripheral blood samples of the proband and his mother. We tried to amplify all exons and the flanking introns of the exons in PHKA2 (NM_000292.3) in the proband, but we obtained no polymerase chain reaction (PCR) products of exons 20 and 21. We designed several new forward primers located at the intron intervening exons 19 and 20 and the reverse primer located at exon 22. Using these primers, we performed PCR using DNA from the proband or his mother and obtained the products, with the size at 500–650 bp from the proband and 3000 bp and 500–650 bp from his mother (Figure 1A). The PCR products in the proband were subjected to direct sequencing from both directions on the autosequencer. We identified a 2423 base deletion in PHKA2 [NC_000023.11(NM_000292.3):c.2226+9_2360+360del] encompassing 134 nucleotides of exon 21 and a breakpoint with imperfect 8- to 9-bp and perfect 3- to 4-bp similar nucleotide sequences near the junction (Figure 1B). This 2.4-kb deletion has not been reported previously in patients with GSD IXa and was not found in the following databases: gnomAD SVs v4 (https://gnomad.broadinstitute.org/), 8.3KJPN-SV, and JSV1 databases (https://jmorp.megabank.tohoku.ac.jp/); however, one study reported a patient with the deletion of exon 21 in PHKA2 detected by multiple ligation-dependent probe amplification.2 No other pathogenic alterations were identified. Complementary DNA analysis in the proband revealed the skipping of exon 21, indicating that the deletion introduced a premature stop codon, p.Pro789Serfs*21 (Figure 1C). We speculate that this variant would trigger nonsense-mediated mRNA decay, based on a previous study using hepatocyte-like cells generated from the dermal fibroblast cell line of a male patient with PHKA2 c.2597+5G>T, showing (i) the variant resulted in an aberrant splicing of PHKA2 and the incorporation of a 27 bp into exon 23 with the immediate presence of a stop codon, (ii) PHKA2 mRNA was down-regulated 7- to 11-fold, and (iii) mutant PHKA2 protein expression was absent.3

A previous study suggested that Alu-mediated recombination causes a 10-kb deletion of several exons in PHKA2.4 To our knowledge, other mechanisms causing PHKA2 microdeletions are unknown. In some diseases, microhomology at the junctions is considered to cause microdeletions through DNA rearrangement.5, 6 Notably, in Duchenne and Becker muscular dystrophies, exon deletions within DMD occur possibly via microhomology of 2–5 bp at the junctions.6 We speculate that microhomology, “gta” or “agta,” may have played an important role in DNA rearrangement in our patient. Meanwhile, the presence of imperfect direct repeats at mtDNA deletion breakpoints raised the possibility that our patient's imperfect 8- to 9-bp sequence may also contribute to the pathogenicity.7, 8

In summary, we identified a novel 2.4-kb deletion in the PHKA2 gene in a patient with GSD IXa. This case implies that DNA rearrangement via perfect and/or imperfect sequences may cause PHKA2 microdeletion.

This study was supported by Novo Nordisk Pharma Ltd. and JCR Pharmaceuticals Co., Ltd.

The authors declare no conflicts of interest.

This study has been approved by the ethical committee at Keio University School of Medicine (20170130). We obtained written informed consent from legal guardians.

Abstract Image

一名患有糖原贮积病 IXa 型的男孩体内存在新型 2.4-kb PHKA2 缺失。
糖原贮积病 IXa 型(GSD IXa)是由 PHKA2 编码的磷酸化酶激酶α亚基缺陷引起的,具有 X 连锁遗传性。临床表现包括空腹低血糖、肝肿大和生长发育障碍。迄今为止,很少有断点被发现,导致微缺失的机制也不甚明了。我们报告了一名患有 GSD IXa 且 PHKA2 存在新型微缺失的儿童患者。他出生时的身长和体重分别为 48.4 厘米(-0.29 SD)和 2.81 千克(-0.42 SD)。他在 15 个月大时发现身材矮小;18 个月大时,他无法独自站立,怀疑他有运动发育迟缓。23 个月时,他被转到本院,身长和体重分别为 79.0 厘米(-2.2 标度)和 10.5 千克(-0.82 标度)。他可以在辅助下行走,并能说有意义的话。体格检查显示他的外观像洋娃娃,腹部膨胀,肝脏肿大。实验室检查结果如下:白细胞 8800/μL(中性粒细胞 1584/μL);天门冬氨酸氨基转移酶 899 U/L;丙氨酸氨基转移酶 554 U/L;肌酸激酶 60 U/L;碱性磷酸酶 966 U/L(年龄匹配参考值 395-1339);γ-谷氨酰转肽酶 374 U/L(参考值 6.5-60.0);肌酐 0.13 mg/dL;尿酸 7.0 mg/dL。空腹胰高血糖素负荷试验显示血糖为 42 毫克/分升(负荷前)和 64 毫克/分升(负荷后 60 分钟)。餐后两小时胰高血糖素负荷试验显示葡萄糖为 131 毫克/分升(负荷前)和 191 毫克/分升(负荷后 30 分钟)。口服葡萄糖耐量试验显示基础乳酸和丙酮酸水平分别为 7.0 和 0.61 毫克/分升,峰值乳酸和丙酮酸水平分别为 32.2 毫克/分升(负荷后 90 分钟)和 3.03 毫克/分升(负荷后 30 分钟)。计算机断层扫描显示肝脏肿大,密度较高。红细胞磷酸化酶激酶分析显示为 0.3 nmoL/min/gHb,而两名健康人分别为 9.1 nmoL/min/gHb 和 10.1 nmoL/min/gHb。因此,我们诊断他患有 GSD IXa。在征得其父母的知情同意后,我们从该患者及其母亲的外周血样本中提取了基因组 DNA。我们尝试扩增 proband 的 PHKA2 (NM_000292.3)的所有外显子和外显子的侧翼内含子,但没有获得第 20 和 21 号外显子的聚合酶链反应(PCR)产物。我们设计了几种新的正向引物,分别位于外显子 19 和 20 的内含子,以及位于外显子 22 的反向引物。使用这些引物,我们对患者或其母亲的 DNA 进行了聚合酶链反应,得到的产物大小为:患者为 500-650 bp,其母亲为 3000 bp,患者为 500-650 bp(图 1A)。我们用自动测序仪从两个方向对该患者的 PCR 产物进行了直接测序。我们在 PHKA2 中发现了一个 2423 个碱基的缺失[NC_000023.11(NM_000292.3):c.2226+9_2360+360del],包括外显子 21 的 134 个核苷酸和一个断点,断点附近有不完全的 8 到 9 个 bp 和完全的 3 到 4 个 bp 的相似核苷酸序列(图 1B)。这一2.4kb的缺失以前在GSD IXa患者中从未报道过,在以下数据库中也未发现:gnomAD SVs v4 (https://gnomad.broadinstitute.org/)、8.3KJPN-SV和JSV1数据库(https://jmorp.megabank.tohoku.ac.jp/);然而,一项研究报道了一名通过多重连接依赖性探针扩增检测到PHKA2外显子21缺失的患者2 。该患者的互补 DNA 分析显示其第 21 号外显子被跳过,表明该缺失引入了一个过早的终止密码子,即 p.Pro789Serfs*21(图 1C)。我们推测这一变异会引发无义介导的 mRNA 衰减,这是基于之前的一项研究,该研究使用了一名男性 PHKA2 c.2597 +5G&gt;T 患者的真皮成纤维细胞系产生的肝细胞样细胞。+5G&gt;T,结果表明:(i) 该变异导致 PHKA2 的剪接异常,在第 23 号外显子中加入 27 bp,并立即出现终止密码子;(ii) PHKA2 mRNA 下调 7 至 11 倍;(iii) 突变的 PHKA2 蛋白表达缺失。先前的一项研究表明,Alu 介导的重组导致 PHKA2 的几个外显子缺失 10kb。5, 6 值得注意的是,在杜氏和贝克型肌营养不良症中,DMD 的外显子缺失可能是通过连接处 2-5 bp 的微结构发生的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Congenital Anomalies
Congenital Anomalies PEDIATRICS-
自引率
0.00%
发文量
49
审稿时长
>12 weeks
期刊介绍: Congenital Anomalies is the official English language journal of the Japanese Teratology Society, and publishes original articles in laboratory as well as clinical research in all areas of abnormal development and related fields, from all over the world. Although contributions by members of the teratology societies affiliated with The International Federation of Teratology Societies are given priority, contributions from non-members are welcomed.
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