Novel NBAS mutations and fever-related recurrent acute liver failure in Chinese children: a retrospective study

The probands were Chinese children evaluated for RALF from 2012 to 2015 by JSW, to whose clinic instances of pediatric liver disease from throughout China are referred (1096 new pediatric liver-disease patients seen during these 4y). Their parents and siblings also took part.

Participation required informed consent (for children, informed parental consent) under a protocol approved by Children’s Hospital and Jinshan Hospital of Fudan University according to the ethical guidelines of the 1975 Declaration of Helsinki. RALF of indeterminate etiology was defined as present when a child had >1 episode of liver injury, including at least 1 episode of ALF (Pediatric Acute Liver Failure Study Group criteria) [3]. That is, no child had evidence of chronic liver disease; all children had biochemical evidence of acute liver injury; all children had hepatic-based coagulopathy, with a prothrombin time (PTT) ≥15 s or an international normalized ratio (INR) >1.5 not corrected by vitamin K in the presence of hepatic encephalopathy, or a PTT ≥20s or an INR >2.0 regardless of the presence or absence of clinical hepatic encephalopathy; and all other causes possibly responsible for liver crises were excluded through comprehensive evaluation. Liver biopsy was performed when coagulopathy permitted.

Five unrelated boys with RALF of indeterminate etiology were enrolled in this study, including 4 of Han and 1 of Miao ancestry. The major clinical features of these probands are shown in Table 1. All parents were non-consanguine, except those of patient 4. Patient 1, initially diagnosed with liver crisis aged 6mo 18d, is the product of a 4th pregnancy (ectopic pregnancy, surgically treated; 2 induced abortions) complicated by intrahepatic cholestasis manifest as pruritus that halted after delivery. The parents are otherwise well. Patient 2, initially diagnosed in liver crisis aged 7mo 21d, is the product of a 1st pregnancy. A younger brother is well. Their mother has a 3y history of hyperthyroidism. Their father is healthy. Patient 3, initially diagnosed in ALF aged 6mo 1d, is the product of a 3rd pregnancy. A sister and brother died in fever-related liver crisis aged respectively 4mo and 8mo. Material from them suitable for genetic analysis was unavailable. Patient 4, initially diagnosed in ALF aged 6y 10mo, is the product of a 5th pregnancy (2 induced abortions, 2 live births). One sister has moyamoya disease; the other is healthy. Their parents are consanguineous. Patient 5, initially diagnosed in ALF aged 2y 2mo, is the product of a first and only pregnancy. The parents are healthy. All patients were normally grown, without dysmorphism. Patients 1–3 always had febrile illnesses before liver crises or episodes of ALF. Patient 5, with one episode of liver crisis without a febrile illness, had febrile illnesses before 3 liver crises and before one episode of ALF. No febrile illness preceded liver crisis or ALF in patient 4.

All 5 patients underwent percutaneous core needle liver biopsy. In patient 1, biopsy was conducted during resolution of the 4th episode of ALF (5y 11mo). Alanine transaminase (ALT) and aspartate aminotransferase (AST) values (“transaminases”) 1d before liver biopsy were abnormal (ALT/AST = 1091/307 IU/L; 0–40 expected for each). Patient 2 underwent liver biopsy 2mo after his 2nd liver crisis (2y 3mo); transaminases 2d before biopsy were normal (ALT/AST = 27/12). Patient 3 underwent liver biopsy during resolution of his 1st episode of ALF (6mo 13d). Transaminases were abnormal 4d before biopsy (ALT/AST = 200/24) and were normal 3d after biopsy (ALT/AST = 30/27). In patient 4, whose biopsy occurred during resolution of ALF (9y 1mo), ALT and AST 2d after liver biopsy were 43 and 22. Patient 5 underwent biopsy during resolution of his 5th liver crisis (3y 10mo). Transaminases 1d before liver biopsy were abnormal (ALT/AST = 84/48).

Peripheral blood samples were obtained from the probands, their parents, and their siblings. Genomic DNA was extracted routinely from peripheral blood leukocytes. Sequencing was conducted at Genesky Biotechnologies, Shanghai.

Exomes (probands; sister of patient 4) were captured using an Agilent SureSelect Human All Exon v5 kit (Agilent Technologies, Wokingham, UK). Sequencing (150 bp paired-end reads) was performed using the Illumina hiseq2500 platform following the manufacturer’s instructions (Illumina, CA). Read alignment was performed with Burrows-Wheeler Aligner (http://​bio-bwa.​sourceforge.​net/) and Picard (https://​broadinstitute.​github.​io/​picard/​). Varscan (http://​varscan.​sourceforge.​net/) and GATK (https://​software.​broadinstitute.​org/​gatk/​best-practices/​) were used for variants calling. Total sequencing depth was 100X. Mean coverage of the exome ranged from 35X to 50X, with >92% of the exome covered at least 2X and >80% covered at >10X. Sequencing statistics are shown in Additional file 1.

Detailed variant filtering strategies for each patient are outlined in Additional file 2. Variants occurring with allele frequency ≥ 1% in the Thousand Genomes Project (http://​www.​1000genomes.​org/​home) and NHLBI Exome Sequencing Project (http://​evs.​gs.​washington.​edu/​EVS/​) databases or ≥4.5% in the Genesky in-house database were filtered out. Potential disease-causing mutations predicted by Polyphen-2 (http://​genetics.​bwh.​harvard.​edu/​pph2/​), SIFT (http://​sift.​jcvi.​org/), and MutationTaster [16] (http://​www.​mutationtaster.​org/) then were selected as suspected pathogenic variations. Suspected pathogenic variations in genes known to be associated with ALF (Additional file 3) and present in accord with inheritance modes identified candidate genes. Suspected pathogenic variations in genes not known to be associated with ALF but present in accord with recessive inheritance also identified candidate genes.

Polymerase chain reaction (PCR) amplification was carried out using primers specific for NBAS exons 8, 22, 31, 43, and 50 (Additional file 4). PCR conditions are available on request. The amplified products were sequenced using an ABI 3730xl DNA Analyzer (Applied Biosystems, Foster

City, CA) and analyzed using CodonCode Aligner software (http://​www.​codoncode.​com). NM_015909 was used as the NBAS reference sequence.

Five Chinese boys with RALF of undetermined etiology were identified from 2012 to 2015 among patients at our institutions. All underwent WES (patients 1–5), as did the healthy sister of patient 4. Filtering criteria yielded 9, 11, 13, 11, and 1 candidate genes in patients 1 through 5 respectively (Additional file 5). The only gene shared by 2 or more patients was NBAS. Two predictedly pathogenic variations of NBAS were detected in patient 1, patient 2, and patient 3, while no NBAS variant was detected in either patient 4 or patient 5. Sanger sequencing in parents proved compound heterozygosity in patients 1, 2, and 3 (Fig. 1).

Patient 1 harbored mutations c.3596G > A, p.C1199Y (missense) and c.6611_6612insCA, p.M2204Ifs*3 (frameshift); patient 2, mutations c.3596G > A, p.C1199Y (missense) and c.586C > T, p.Q196X (nonsense); and patient 3, c.2407G > A, p.E803K (missense) and c.5389 + 1G > T (splice-site). Two missense mutations (c.3596G > A, p. C1199Y [2 patients] and c.2407G > A, p. E803K), were both predicted to be pathogenic by Polyphen-2, SIFT, and MutationTaster [16] analyses. Patients 1 and 2 each harboured the c.3596G > A mutation. The missense mutation c.2407G > A is described (6 heterozygous instances, Exome Aggregation Consortium (ExAc) Server [http://​exac.​broadinstitute.​org/]). The other 4 mutations are not recorded in public databases (Thousand Genomes Project; NHLBI Exome Sequencing Project; ExAc) or in the Genesky in-house database; we consider them novel.

Unlike the 2 patients without NBAS mutation, those harbouring NBAS mutations always had a febrile illness before a liver crisis or episode of ALF. Our 3 NBAS-disease patients clinically resembled one another: all suffered from a febrile illness, likely infective (viral / bacterial) before each episode of RALF (fever-related RALF), with markedly elevated ALT (77–9382 IU/L; normal 0–40) and AST (213–17,344 IU/L; normal 0–40) activities 24-72 h after elevation of body temperature, succeeded by severe coagulopathy (maximum INR = 6.89; normal 0.8–1.2) and mild to moderate jaundice that were ascribed to ALF. Hypoglycemia and hepatic encephalopathy were transiently observed in patients 1 and 3. Total bile acid concentrations in all 3 patients were increased (18.2–517.2 umol/L; normal 0–10). Serum alkaline phosphatase and γ-glutamyltranspeptidase activities were normal or only mildly increased, as were blood ammonia values. Ages during episodes of ALF and liver crises are shown in Additional file 6. The details of episodes of RALF in patient 3 are shown in Additional file 7. Similar details for patients 1 and 2 are not available, as they received care at several hospitals other than ours. Biomarkers of hepatobiliary injury completely recovered between liver crises. Not all episodes of fever led to hepatic crisis. All patients used antipyretics and hepatoprotectives (e.g., ademetionine 1, 4-butanedisulfonate; reduced glutathione). In patient 1, however, during his 7th episode of RALF (4th of ALF) biomarkers returned to normal without hepatoprotectives. The 3 NBAS-disease patients were free from facial dysmorphism and had no broken bones. No radiogrammes were exposed in patients 1 and 2; a left lower limb radiogram in patient 3 was assessed as normal. Formal cognitive evaluation and investigations for Pelger-Huët anomaly were not conducted in any patient. Motor development was normal for all 3. Lymphocyte panels and immunoglobulin values were unremarkable in patients 1 and 3; these were not evaluated in patient 2. Ophthalmoscopy found no abnormality in patient 3 and was not conducted in patients 1 and 2.

Light microscopy was undertaken in patients 1–5, with ultrastructural study in patients 1–4. Hepatocyte cytoplasm contained small vacuoles in patients 1 and 3, confirmed as steatosis by transmission electron microscopy. Patients 2 and 3 had centrilobular fibrosis that was worse in patient 3. In patient 4, the liver was unremarkable. Inflammation and minimal portal-tract fibrosis were seen in patient 5. Ultrastructural findings were non-specific, with questionably increased glycogen stores in patients 1–4, dilated endoplasmic reticulum (ER) and abnormal mitochondria in patient 2, dense mitochondrial matrix in patient 3, and swollen mitochondria, questionably decreased in number, in patient 4.