Introduction
Nephronophthisis-related ciliopathies (NPHP-RC) are autosomal recessive disorders characterized by kidney corticomedullary cysts and extrarenal symptoms and are the most common genetic cause of kidney failure in children and young adults [
1‐
3]. NPHP-RC can present as isolated nephropathy or as a syndrome [
4]. The incidence of extrarenal involvement in patients with NPHP-RC ranges from 10 to 50%, and the most commonly involved sites are the liver, eyes, bones, and central nervous system (CNS) [
5‐
8]. Currently, variants of around 90 genes have been identified as causes of NPHP-RC [
9,
10].
Most patients with NPHP-RC progress to kidney failure before the age of 30 years [
8,
11]. Typically, patients with juvenile nephronophthisis initially present with polydipsia, polyuria, secondary enuresis, growth retardation, and anemia. As such, diagnosis is usually delayed, and patients are diagnosed at a later disease stage [
12]. The development of next-generation gene sequencing technology (NGS) has resulted in genotyping of a larger number of patients with NPHP-RC, leading to studies of the relationship between genotype and phenotype [
7,
8,
13,
14].
In the aforementioned studies, most patients were in the chronic kidney disease (CKD) phase of the disease at the time of phenotype analysis, or only some patients had reached kidney failure during the follow-up period. As nephropathy progresses to the kidney failure stage, the involvement of extrarenal organs also progresses. Thus, the analysis of the phenotype of uremic patients is helpful for the perioperative management of kidney or other organ transplantation. For example, when there is liver involvement, the state of liver function plays a decisive role in perioperative management and the choice of transplantation strategy.
When patients with NPHP-RC reach kidney failure, kidney transplantation is the first-choice treatment [
15]. Some studies have shown that compared with the general pediatric kidney transplant population, the effect of kidney transplantation is better in recipients with NPHP-RC as the primary disease [
16]. Boichis syndrome is a unique NPHP-RC that is characterized by congenital NPHP and congenital hepatic fibrosis [
17]. Treatments for this disease include combined liver and kidney transplantation (CLKT), sequential liver and kidney transplantation, and isolated kidney transplantation [
18,
19]. In patients with Boichis syndrome, portal hypertension can lead to adverse events due to the rapid progression of hepatic fibrosis after kidney transplantation only [
20,
21]. Generally, the transplantation strategy is adopted mainly based on the degree of liver fibrosis. When the degree of liver fibrosis meets the conditions for liver transplantation, it is necessary to perform CLKT. However, there is no clear guidance on the optimal surgical strategy for patients with mild to moderate liver fibrosis (especially those with high-risk genotypes). CLKT can solve both liver fibrosis and kidney failure, yet the surgical risk is high. The surgical success rate of isolated kidney transplantation is high; however, it is uncertain when liver fibrosis progresses to the indication of liver transplantation. Thus, the purpose of this study was to examine the association between NPHP genotype and phenotype in children to provide references for clinicians when determining an appropriate transplantation strategy.
Methods
Study design and participants
The genotype and phenotype of children with NPHP-RC treated at our center from January 1, 2018, to March 31, 2021, were retrospectively reviewed. Inclusion criteria were a diagnosis of NPHP, received a kidney transplant or CLKT, received whole exome sequencing (WES) or nephropathy gene panel testing and were found to have a pathogenic gene mutation associated with NPHP, had complete medical records, and were ≤ 18 years of age. Diagnosis of NPHP was based on the clinical diagnostic criteria for NPHP proposed by Chaki et al. [
8]. Exclusion criteria were (1) WES or nephropathy gene panel was not performed; (2) NPHP-related pathogenic mutation was not present; and (3) the patient did not meet the clinical diagnostic criteria of NPHP-RC.
The study was approved by the Ethics Committee of the First Affiliated Hospital of Sun Yat-sen University (IIT-2021–892).
Data collection
Data extracted from the medical records included medical history, including age at presentation of NPHP-RC and age when kidney failure was reached. Laboratory data extracted included serum creatinine (Scr), blood urea nitrogen (BUN), albumin (ALB), globulin (GLB), alanine aminotransferase (ALT), aspartate aminotransferase (AST), and total bilirubin (TB) levels. All children underwent abdominal ultrasound. A liver biopsy was performed if abdominal ultrasound indicated liver fibrosis when the informed consent was available. All the children underwent chest, extremity, and pelvis X-rays. All children received visual acuity and visual field evaluation, slit lamp examination if necessary, and optical coherence tomography and electrophysiological examinations in cooperative patients suspected of having retinitis pigmentosa. Each child underwent an echocardiogram to check for structural defects in the heart. Head MRI examinations were performed in children with neurological abnormalities found by physical examination to detect cerebellar vermis hypoplasia and other structural brain abnormalities. All patients were followed up through outpatient clinic and telephone after kidney transplantation. Postoperative eGFR, graft survival, patient survival, rejection, and recurrence of primary disease were obtained by follow-up.
Gene sequencing and data analysis
WES was performed using MyGenetics and Wuxi NextCODE. Genomic DNA was extracted from blood lymphocytes. Exon capture was performed using Agilent SureSelect Human all Exome V5 Kit, NimbleGen, or MyGenostics Gencap Capture techniques, and then NGS was performed on the Illumina HighSeq sequencing platform. At least 98% of the target sequences were sequenced at a 20 × reading depth.
After removing reads containing adaptor sequences and low-quality reads, clean data were mapped to the human reference genome assembly (NCBI build 37/hg19) using the Burrow–Wheeler Aligner (BWA). Single nucleotide polymorphisms (SNP) and small insertions and deletions (INDELs) were detected using a Genome Analysis Toolkit (GATK). Allele frequency was determined by annotating the variations using public databases (genomAD, Human Genome Mutation Database (HGMD), and the 1000 Genomes Project). Changes that represented synonymous and common variants (minor allele frequency > 1%) were discarded. SNP variant deleteriousness was predicted by SIFT, PolyPhen2, and MutationTaster. Mutation screening was prioritized based on known disease-causing genes and nephropathy-associated genes. Evidence of disease causality was assessed using ClinVar and HGMD, followed by a manual review of the cited primary literature. Copy number variation (CNV) analysis was performed using WES data, and then validated by PCR. Using the ALB gene as the internal reference gene, the copy number of exon 1–20 of NPHP1 was detected by fluorescence quantitative PCR with normal control samples and proband and family samples.
The nephropathy gene panel includes 162 genes causative or associated with nephropathy, as well as genes that may cause phenocopies in humans or related phenotypes in animal models (Supplementary Table
1). A custom NimbleGen SeqCap EZ Choice Library (NimbleGen; Roche, Madison, WI) was used to capture all exons and exon–intron boundaries (plus 50 base pairs at each end) of these genes for a final targeted region of 1.05 Mb.
Pathogenicity assessment was conducted by a team of nephrologists and molecular geneticists. According to American College of Medical Genetics (ACMG) guidelines, mutations in known pathogenic genes whose pathogenicity levels are “pathogenic,” “likely pathogenic,” and “variant of unknown significance (VUS)” are defined as diagnostic variants. For variants of unknown significance, we regarded it as a diagnostic variation only when other causes of chronic kidney failure were excluded and there was a high correlation between phenotype and variants. All diagnostic variants were confirmed by Sanger sequencing with segregation.
Statistical analysis
Continuous data were expressed as mean ± standard deviation or median and interquartile range (IQR), and categorical data as count (percentage). Comparisons of patients with and without NPHP1 mutations were performed using the t-test. Kidney survival analysis between children with NPHP1 mutations and those with non-NPHP1 mutations was performed by Kaplan–Meier analysis. The level of statistical significance was defined as p < 0.05. GraphPad Prism 8 statistical software was used for all statistical analyses.
Discussion
In this study, we reviewed genotype and phenotype variations in children with NPHP, analyzed characteristics associated with NPHP1 and non-NPHP1 mutations with a focus on NPHP3 pathogenic mutations, and summarized the treatment of patients with Boichis syndrome. We found that isolated kidney transplantation is feasible for patients with Boichis syndrome with mild to moderate liver fibrosis, while cholestasis can occur postoperatively and be treated symptomatically. Follow-up results after transplantation were acceptable.
Studies have shown that
NPHP1 is the most common gene to harbor pathogenic mutations [
7,
22], and our results are consistent with those of the prior studies. Children with
NPHP1 pathogenic mutations reached kidney failure at a later age than those with non-
NPHP1 mutations. Additionally, most patients with
NPHP1 mutations exhibited isolated nephropathy and less extrarenal involvement. This suggests that pathogenic
NPHP1 mutations result in less severe phenotypes than other mutations. All patients in this cohort with
NPHP1 mutations showed isolated nephropathy, and patients with
NPHP1 mutations reported in the past had a probability of isolated nephropathy ranging from 76.5 to 90% [
7,
8]. Although there were some differences, they all reflected the fact that
NPHP1 mutations rarely show extrarenal phenotypes.
While the frequency of non-
NPHP1 mutations was less than that of
NPHP1 mutations, non-
NPHP1 pathogenic mutations were associated with an earlier age of disease presentation and an earlier age of reaching kidney failure, as well as more common extrarenal involvement of the liver, eyes, and bones. In fact, in some cases, children have already progressed to kidney failure when they are first seen by a physician due to disease symptoms. Thus, differences between the age of disease presentation and age at reaching kidney failure in this study may not accurately reflect the inherent progression rate of NPHP. Of particular note, we found that
NPHP3 mutations are associated with a high frequency of liver involvement and other severe conditions. Previous studies have also observed that
NPHP3 mutations are associated with liver abnormalities [
23].
Chaki et al. found 13 patients with
NPHP3 mutations in a total of 440 patients with NPHP, and a study by Tang et al. in China reported 15 patients with
NPHP3 mutations in 60 patients with NPHP [
7,
8]. Chinese children with NPHP have a relatively high frequency of
NPHP3 mutations, which are characterized by rapid progression to kidney failure and liver involvement [
7,
23]. Interestingly, children with liver involvement and kidney failure at an earlier age carry mutations that significantly impact protein function, including splice site mutations, truncation mutations, and frameshift mutations. Children with missense mutations in our study did not have extrarenal involvement, and the disease progressed slowly. Previous studies also support the notion that missense mutations in
NPHP3 are associated with mild NPHP, while loss of function mutations may result in a more severe phenotype [
23,
24].
Otto et al. [
25] reported that Boichis syndrome could manifest in patients with
TMEM67 mutations. We did not find any
TMEM67 mutations in the 29 patients included in our analysis, but the proportion of patients with
NPHP3 mutations characterized by Boichis syndrome was high. Treatment of Boichis syndrome that has reached kidney failure is still a topic for discussion. While a number of centers have reported the experience of treating Boichis syndrome [
18,
20,
21], in general, the number of cases is small, and thus data regarding optimal management is insufficient. For children with Boichis syndrome, we chose the surgical management based on liver phenotype; one patient received CLKT and three kidney transplantation only. Overall, the postoperative follow-up results are satisfactory in all four patients.
Prior reports have suggested that portal hypertension is the direct or indirect cause of postoperative adverse events in patients with Boichis syndrome who received kidney transplantation alone [
20,
21]. The survival rate and long-term prognosis of CLKT have improved in recent years. In CLKT, the transplanted liver has an immunoprotective effect on the transplanted kidney [
26], and CLKT can avoid having to perform two separate major operations in a short time. Of our 29 patients, one patient (number 11) developed Boichis syndrome with portal hypertension, and thus we performed CLKT and follow-up results have been satisfactory. However, compared with single organ transplantation, CLKT is a more complicated procedure associated with greater surgical risk and trauma.
It is not necessary for all patients with Boichis syndrome to receive CLKT, so we performed isolated kidney transplantation in three patients with NPHP with mild or moderate liver fibrosis without portal hypertension and closely followed the recovery of liver function after the operation. We found that in the early postoperative period, these patients developed symptoms of cholestasis. Previous studies reported that NPHP3 loss-of-function mutations could cause rapid worsening of liver fibrosis, but they did not indicate the cause of the rapid worsening. Cholestasis can cause chronic inflammation of the liver, leading to steatosis, a reduction of hepatic cells, diffuse fibrosis, and proliferation of blood vessels inside and outside the liver, with the subsequent gradual development of cirrhosis. Therefore, the rapid worsening of liver function after kidney transplantation might be related to the emergence of cholestasis, and timely treatment of cholestasis could prevent the rapid progression of liver damage. We treated cholestasis with ursodeoxycholic acid and found that timely treatment stabilized liver function and prevented worsening of liver function with good results. Thus, isolated kidney transplantation is feasible for patients with mild and moderate liver fibrosis, but without portal hypertension. However, it is necessary to pay close attention to postoperative changes in liver function and provide prompt treatment.
Of the 184 patients in this cohort, four developed post-transplant thrombosis, of whom three were diagnosed with NPHP. The rate of renal vascular thrombois was higher in NPHP patients (3/29, 10.3%) than non-NPHP patients (1/155, 0.65%) (
p = 0.013). The mutated genes carried by patients with post-transplant embolism in our cohort were
WDR19,
NEK8, and
IQCB1. Doreille et al. reported that thrombotic microangiopathy (TMA) was found in young adult NPHP patients with
TTC21B and
WDR19 mutations [
14]. This information may suggest a potential association between the genotype of NPHP and post-transplant thrombosis. There were five patients with
TTC21B mutation and one patient was found to have TMA in the native kidney biopsy. However, no vascular thrombosis occurred in these five patients after transplantation. In addition, based on the findings during surgical exploration, we infer that vascular thrombosis initiated in the main renal vascular instead of microvascular circulation, and TMA was not reported in the pathological examination of removed allografts. Therefore, it is difficult to reasonably conclude that post-transplant thrombosis is related to these genes, while we believe this is a very noteworthy clinical phenomenon.
There are some shortcomings of this study that should be considered. The population studied in this cohort are all children with kidney failure, so the correlation between genotype and phenotype cannot be applied to children with NPHP before kidney failure. The postoperative follow-up time of children with Boichis syndrome was relatively short, with the longest 30 months, and the shortest only 18 months. Not all children with NPHP and liver involvement received a liver biopsy because of its invasive nature. Liver biopsy has not been performed to reassess liver fibrosis in patients with Boichis syndrome after isolated kidney transplantation, although the serum parameters of liver function maintain nearly normal.
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