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Open Access

Peer-reviewed

Research Article

Whole exome sequencing identifies KIF26B, LIFR and LAMC1 mutations in familial vesicoureteral reflux

  • Zsuzsa I. Bartik,

    Roles Conceptualization, Formal analysis, Investigation, Writing – original draft

    Affiliations Department of Paediatric Surgery, Paediatric Uronephrologic Centre, Queen Silvia Children’s Hospital, Göteborg, Sweden, Institute of Clinical Sciences, Sahlgrenska Academy, University of Gothenburg, Gothenburg, Sweden

  • Ulla Sillén,

    Roles Conceptualization, Formal analysis, Funding acquisition, Investigation, Writing – review & editing

    Affiliations Department of Paediatric Surgery, Paediatric Uronephrologic Centre, Queen Silvia Children’s Hospital, Göteborg, Sweden, Institute of Clinical Sciences, Sahlgrenska Academy, University of Gothenburg, Gothenburg, Sweden

  • Anna Djos,

    Roles Formal analysis, Writing – review & editing

    Affiliation Department of Laboratory Medicine, Institute of Biomedicine, Sahlgrenska Academy, University of Gothenburg, Gothenburg, Sweden

  • Anna Lindholm,

    Roles Investigation, Writing – review & editing

    Affiliation Department of Paediatrics, County Hospital Ryhov, Jönköping, Sweden

  • Susanne Fransson

    Roles Conceptualization, Formal analysis, Methodology, Writing – review & editing

    susanne.fransson@clingen.gu.se

    Affiliation Department of Laboratory Medicine, Institute of Biomedicine, Sahlgrenska Academy, University of Gothenburg, Gothenburg, Sweden

Abstract

Vesicoureteral reflux (VUR) is a common urological problem in children and its hereditary nature is well recognised. However, despite decades of research, the aetiological factors are poorly understood and the genetic background has been elucidated in only a minority of cases. To explore the molecular aetiology of primary hereditary VUR, we performed whole-exome sequencing in 13 large families with at least three affected cases. A large proportion of our study cohort had congenital renal hypodysplasia in addition to VUR. This high-throughput screening revealed 23 deleterious heterozygous variants in 19 candidate genes associated with VUR or nephrogenesis. Sanger sequencing and segregation analysis in the entire families confirmed the following findings in three genes in three families: frameshift LAMC1 variant and missense variants of KIF26B and LIFR genes. Rare variants were also found in SALL1, ROBO2 and UPK3A. These gene variants were present in individual cases but did not segregate with disease in families. In all, we demonstrate a likely causal gene variant in 23% of the families. Whole-exome sequencing technology in combination with a segregation study of the whole family is a useful tool when it comes to understanding pathogenesis and improving molecular diagnostics of this highly heterogeneous malformation.

Citation: Bartik ZI, Sillén U, Djos A, Lindholm A, Fransson S (2022) Whole exome sequencing identifies KIF26B, LIFR and LAMC1 mutations in familial vesicoureteral reflux. PLoS ONE 17(11): e0277524. https://doi.org/10.1371/journal.pone.0277524

Editor: Suresh Yenugu, University of Hyderabad, INDIA

Received: February 8, 2022; Accepted: October 31, 2022; Published: November 23, 2022

Copyright: © 2022 Bartik et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Data Availability: The genetic datasets from patients associated with this paper are not available for public sharing due to protection from complete disclosure of genome data according consent. All other relevant data are within the paper and its Supporting information files.

Funding: The study was financed by grants from the Swedish state under the agreement between the Swedish government and county councils, the ALF agreement (US: ALFGBG-830501) URL: https://www.researchweb.org/is/alfgbg. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Primary vesicoureteral reflux (VUR) is a congenital urinary tract defect that occurs in approximately 1 to 2% of young children [1]. High-grade VUR in infants is often associated with congenital generalised kidney damage, renal hypodysplasia, whereas the commonly seen acquired focal scarring is caused by ascending urinary tract infections (UTI) [2]. The morbidity seen in children with VUR is often related to recurrent UTI, with the risk of progressive kidney damage. There is an initial difference in gender prevalence in VUR in infants. Initially it affects mainly boys but there is a decline in the male-to-female ratio over time, with similar occurrences in boys and girls by the age of two [3].

Familial clustering of VUR is well recognised, indicating a strong genetic contribution to the pathogenesis. The risk that offspring will have reflux has been reported to be as high as 66%, while it is 27 to 51% for siblings [47]. The high frequency of VUR in relatives favours an autosomal dominant inheritance pattern with reduced penetrance [812], although some authors favour a possible recessive [13] or X-linked model [14]. Despite the apparent Mendelian inheritance pattern seen in many families, only a few causal genes such as EYA1, PAX2, RET, ROBO2 and SALL1 have been identified so far [12, 1517]. However, a large number of additional candidate genes have been suggested as contributing to VUR aetiology and these mainly includes genes functioning in pathways involved in the development of the kidney, ureter and ureterovesical junction (UVJ). The two major embryological structures are the ureteric bud (UB), a budding on the metanephric duct, and the metanephric mesenchyme (MM) which is invaded by the UB and initiate branching [18]. The UVJ, ureter, renal pelvis and collecting ducts have been shown to originate from UB epithelial cells, whereas the epithelium in the nephrons (tubuli and glomeruli) originates from MM through mesenchymal-epithelial transition (MET) [19]. Interference in the interaction between the UB and the MM can result in both renal parenchymal dysgenesis and urinary tract malformation. To emphasise this association, the term CAKUT (congenital anomalies of the kidney and urinary tract) was coined [20]. Embryological work in mice has shown that many genes are involved in these developmental processes, including Eya1, Pax2, Agtr2, Bmp4, Gdnf, Ret, Wnt11, Foxc1, Sall1, Robo2, Slit2, Gata3, Fgfr2, Upk2, Upk3 and Six1 [1921]. Nevertheless, the entire repertoire of relevant genes is still unknown. The experimental models also suggest that a mutation affecting a single gene may result in different phenotypes, while mutations of different genes can result in the same disease [21].

In humans, different strategies have been used over the past few decades to elucidate the genetic background of primary nonsyndromic VUR. These include gene expression studies [22], association-, linkage- and exon-sequencing studies of candidate genes [2327], genome-wide linkage and association studies [1, 9, 13, 2833] and array-based comparative genomic hybridisation [34]. In recent years, next-generation sequencing has revolutionised genomic research. Whole-exome sequencing (WES) provides rapid detection of DNA variants within the coding part of the genome and an opportunity to arrive at a molecular diagnosis with a single test. These recent studies using WES analysis detected various variants in candidate genes in 3.2% to 17.6% of patients with CAKUT, including VUR [3540]. The variety of candidate genes and possible loci that have been suggested in these previous studies implies that VUR is a genetically heterogeneous disease with mutations in different genes, each accounting for a proportion of cases [13]. However, WES, has limited capacity to detect structural variants, smaller copy number changes or aberrations in regulatory regions, meaning that additional causative genetic alterations could be missed. Once we have discovered the genetic background of VUR, mutation analyses of blood samples or buccal smears may replace voiding cystourethrogram (VCUG) as a screening method for relatives of VUR patients. Furthermore, these analyses will hopefully identify patients at risk by distinguishing severe cases that require prompt treatment and frequent follow-up from those where the disease is relatively benign and may resolve spontaneously. In the present study, our aim was to identify likely disease-causing gene variants in familial primary nonsyndromic VUR, focusing on patients with the infantile form of high-grade reflux and with congenital kidney hypodysplasia as we hypothesise that congenital cases are more likely to have a genetic component than cases with kidney damage due to multiple UTI. Thirteen large families with three or more affected cases were analysed by WES, focusing on genes previously established as having links to VUR as well as other candidate genes associated with embryological development of the kidney. The questions were whether one candidate gene causes the disease in all or some of the families or, if this is not the case, whether members of a family all share the same variant of a candidate gene.

Materials and methods

Patients and families

Thirteen families with three or more members with primary VUR were recruited at Queen Silvia Children’s Hospital (a tertiary referral centre) in Gothenburg, Sweden. All recruited families were from the south-western region and of Swedish ancestry. The families were contacted and given verbal and written information about the study. Before entering the study, all subjects and/or their parents signed an informed consent for genetic screening. Individuals older than 18 years of age signed the consent themselves. For minors written consent was obtained from both guardians. The Regional Ethical Review Board in Gothenburg approved the study (Dnr 589–05). All methods were carried out in accordance with relevant guidelines and regulations including the Declaration of Helsinki.

Blood samples or buccal swab specimens were collected by standard procedures. For the individuals in the families selected for WES, blood sampling was mandatory. Seven of these families had already participated in our previous study of hereditary VUR [27]. The selection process for the study, with initial cases and with subsequent inclusion and exclusion criteria, is presented in Fig 1.

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Fig 1. Data selection process for the study.

https://doi.org/10.1371/journal.pone.0277524.g001

Clinical data was obtained from medical records, VUR grade from voiding cystourethrograms (VCUG), permanent kidney damage from scintigraphy with Tc-99m dimercaptosuccinic acid (DMSA) or Tc-99m mercaptoacetyltriglycine (MAG3) and total kidney function from glomerular filtration rate (GFR) measurements or by estimations following the Schwartz formula [41, 42]. In the case of bilateral VUR, the patient was classified according to the more severely affected side in terms both of VUR grade and kidney damage. Focal kidney damage was defined as one or more areas with reduced uptake or indentation of the kidney outline caused by postnatally acquired kidney scarring [2]. Generalised damage was defined as a small kidney with reduced tracer uptake or a diffuse parenchymal anomaly, referred to as congenital renal hypodysplasia [43, 44]. A GFR of < 80% (<2SD) of expected GFR was considered subnormal. GFR reference values in children under two years of age were calculated using Winberg’s algorithm [45]. For older children a rate of 110 ml/min/m2 was used.

To clarify the relationship and analyse the pattern of inheritance, pedigrees were constructed for each family (Fig 2). Additional members of families with a history strongly suggesting VUR but with no radiological test results, were classified as probable cases. Patients with secondary VUR, e.g., patients with neurogenic bladder or posterior urethral valves, were excluded from the study.

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Fig 2. Pedigrees of included families.

Pedigrees describe the 13 participating families with three or more vesicoureteral reflux cases. A family identifier is indicated above each respective pedigree with case-specific identifiers given under each individual. Squares males, circles females, rhombuses sex unknown, black symbols indicate diagnosis confirmed by voiding cystourethrography, grey symbols indicate strong history of VUR but no available radiological investigations, arrows index cases.

https://doi.org/10.1371/journal.pone.0277524.g002

Whole-exome sequencing

The most severely affected family member, meaning a member with confirmed generalised kidney damage (renal hypodysplasia), was chosen for WES. When this was not possible, the selection criterion used was high-grade VUR. In three families, WES was carried out on an additional individual. What the three additional study subjects had in common was that they were the most distantly-related, affected relatives of the proband in their respective pedigree (aunt, uncle and cousin).

Genomic DNA was isolated from blood lymphocytes and subjected to WES (GATC, Constance, Germany) on Illumina instrumentation (Illumina, San Diego, CA) after DNA enrichment using Agilent SureSelect human All exon v6 (Agilent technologies, Santa Clara, CA) reaching an average coverage of 70X (range 46-114X). Coverage and mapping metrics are presented in S1 Table. Read trimming, mapping, and variant calling were performed using CLC Biomedical Genomics Workbench software (Qiagen, Aarhus, Denmark) (S1 File) with consecutive variant filtering using Qiagen QCI interpret translational tool (Qiagen). Only high-quality called variants with a variant allele frequency above 0.15 and a total read coverage of at least ten were considered for further analysis. Variants with a minor allele frequency above 0.01 in either SweGen dataset (https://swegen-exac.nbis.se), 1000 genomes, Exome Aggregation Consortium (ExAC), Cambridge, MA (http://exac.broadinstitute.org), Genome Aggregation Database (gnomAD) http://gnomad.broadinstitute.org or NHLBI Exome Sequencing Project (http://evs.gs.washington.edu/EVS/) were discarded, as well as all synonymous variants or variants in non-coding regions, except those affecting canonical splice sites. Remaining variants were assessed manually through the Integrative Genomics Viewer (IGV) [46]. PolyPhen 2, SIFT and CADD were used to predict the functional relevance of called single nucleotide variants (SNV)s. Possible relevance to the biological disease context was assessed using QCI interpret translational (Qiagen). The filtering process and remaining variants after each step are visualized in Fig 3. All genomic positions were given according to the human reference genome GRCh37/hg19.

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Fig 3. Filtering of called variants.

Systematic filtering of single nucleotide variants called from CLC workbench with number of variants remaining after each step and criteria for retaining variant as indicated.

https://doi.org/10.1371/journal.pone.0277524.g003

Variant classification and prioritisation

The remaining potential rare causal gene variants were further filtered in an extensive literature search. This literature review focused on: 1) gene function and associated phenotype, 2) gene-associated animal models, 3) tissue expression of the encoded protein, 4) association with already known VUR genes and 5) location of the variant with respect to functional protein domains. Genes participating in Ureteric Bud/Metanephric Mesenchyme development were regarded as highly relevant. Genes associated with syndromes were included if a connection to kidney development or VUR was stated. Syndromes with other CAKUT phenotypes were excluded.

Our different strategies for prioritising the findings were: 1) screening for variants of genes previously associated with VUR and kidney development, 2) screening for common variants in different families and 3) screening for common variants within the family in the three applicable cases.

Sanger sequencing

Sanger sequencing was used to verify significant WES findings in subjects, as well as for segregation analysis of all healthy and sick relatives where samples were available. DNA was extracted using a Maxwell 16 Buccal Swab LEV DNA Purification Kit (Promega, Madison, WI) for samples collected with Isohelix buccal swabs, while Qiagen DNeasy Blood & Tissue Kit (Qiagen, Aarhus, Denmark) was used for blood. ExonPrimer (https://ihg.helmholtz-muenchen.de/ihg/ExonPrimer.html) was used to design primers. Primer sequences and other PCR details are available upon request. Sanger sequencing was performed by GATC Biotech (Constance, Germany) and analysed using the SnapGene software (GSL Biotech, Chicago, IL).

Results

Clinical characteristics

A total of 41 patients from 13 different families with VUR were included (20 males, 21 females), of whom 16 were subjects for WES. There were two nuclear families and 11 extended families. The relationship between the affected individuals and the pattern of inheritance is shown in Fig 2 and S2 Table.

Demographics and phenotypic details of the study subjects are outlined in Table 1. The whole-exome sequenced study subjects were more commonly male (62%), with a higher grade of reflux (69% grade IV-V in the sequenced cohort vs. 49% in the whole group), with more generalised kidney damage (81% vs. 53%) and frequently subnormal total kidney function (25% vs. 13%). Only five cases showed additional malformations of the urinary tract, such as bilateral duplex kidney (1), bladder diverticula (3) and unilateral megaureter (1). In addition, three cases with extrarenal manifestations had syndromic features but did not have a known diagnosis (S3 Table).

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Table 1. Demographic data, VUR grades, kidney abnormalities and function for the whole-exome sequenced group and for the whole study group.

https://doi.org/10.1371/journal.pone.0277524.t001

Candidate variants in VUR/nephrogenesis genes

We performed WES on 16 individuals from 13 families with hereditary VUR and after multistep variant filtering and prioritisation, as described in Materials and Methods, 40 heterozygous candidate variants in 32 genes previously associated with VUR or nephrogenesis were retained (S4 Table). They included variants in genes previously associated with diseases showing autosomal recessive inheritance such as FREM2, ROR2 and FRAS1 although none of them were homozygous or compound heterozygous.

To further elucidate whether additional members within the same family had inherited the same variant, WES was performed on a second affected member in three families (see Material and methods). In one family (Fam. 32) with severe VUR and renal hypodysplasia, two DNA variants in possible causal genes (LIFR, CLDN3) were detected in both patients while in the second family (Fam. 17), a novel KIF26B variant was shared by the two family members who had been investigated (Table 2, Fig 2). The third family (Fam. 82) did not share any variant in kidney-associated genes, in spite of their astonishingly similar phenotype with explicit generalised kidney damage.

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Table 2. Results of Sanger sequencing used for segregation analysis in 13 families with hereditary VUR.

https://doi.org/10.1371/journal.pone.0277524.t002

A segregation analysis was performed on all candidate variants (except the genes with autosomal recessive inheritance lacking biallelic alterations, as judged from WES) in all relatives with available DNA samples. Sanger sequencing showed variants segregating with disease in three different families (Table 3, Fig 4). This was in three nephrogenesis-related genes (KIF26B, LAMC1 and LIFR) in which autosomal dominant inheritance had previously been reported. Despite being highly interesting in regard to VUR aetiology, the remaining variants which were analysed did not segregate with the phenotype in all the families concerned (Table 2, S4 Table).

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Fig 4. Variant identification and segregation analysis.

Candidate variants detected by WES visualized in IGV with genomic position as indicated (left panels). Electropherograms from Sanger sequencing over corresponding positions show that the variants in KIF26B (fam. 17), LIFR (fam. 32) and LAMC1 (fam. 76) segregate with disease in respective families.

https://doi.org/10.1371/journal.pone.0277524.g004

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Table 3. Three possibly pathogenic variants identified in nephrogenesis-related genes in three families with hereditary VUR.

https://doi.org/10.1371/journal.pone.0277524.t003

Predicted deleterious or truncating variants that did not show consistent co-occurrence with a VUR phenotype included predicted deleterious, missense variants in the known VUR genes, SALL1 (Fam. 19), ROBO2 (Fam. 76), and UPK3A (Fam. 82). These were inherited from healthy fathers in the families while splice site variants in UPK2 (Fam. 17) and DSTYK (Fam. 83) were present in some but not all affected family members (Table 2). Variants in GREB1L and CLDN3 segregated with disease in Family 76 and Family 32 respectively. However, both variants were also detected in other families in the study cohort: the GREB1L was also detected in the youngest individual in Family 83, but was not seen in other affected relatives while the CLDN3 variant was also present in homozygous form in the unaffected father in Family 30.

One MMP9 variant was detected in affected individuals in Families 46 and 82, although only segregating in Family 46, where one unaffected family member (individual 366) was homozygous for the variant. Similarly, a variant in CHD7 was detected in two families (Fam. 19 and Fam. 32), but it segregated only in Family 19. None of the study subjects carrying this CHD7 allele showed the syndromic phenotype described in the literature on this gene, indicating that this variant is most likely benign.

Signalling pathways in the embryological development of the kidney

The three genes with potential pathogenic variants in families with VUR and kidney damage participate in different signalling pathways that are crucial for the development of the lower urinary tract and kidney. They include mitogen-activated protein kinase (MAPK) (genes: KIF26B, LIFR), Wnt (genes: KIF26B, LAMC1, LIFR), phosphoinositide 3-kinase (PI3K)/AKT (genes: LAMC1, LIFR, KIF26B) and Janus kinase/signal transducers and activators of transcription (JAK/STAT) (gene: LIFR). A simplified diagram of the interactions between the genes (including our initially most promising candidate genes) is shown in S2 File. Due to the interdependence between developmental pathways, mutations in different genes can result in similar phenotypes.

Discussion

A cohort consisting of 13 large families, which originated from the west coast of Sweden and three or more of whose members had primary VUR, was investigated by WES, focusing on genes with known pathogenicity in VUR. Additional candidate genes not previously reported in patients with VUR or other CAKUT (such as CLDN3, KCP, LAMC1, POSTN and WNT3A) but where experimental models demonstrated expression and/or effect on UB outgrowth and tubular growth [4750], were also included. Among these, 40 heterozygous novel or rare variants were detected in 32 different genes affecting kidney development (S4 Table). The segregation with the disease phenotype within families was ascertained by Sanger sequencing, validating three different variants affecting LAMC1, KIF26B, and LIFR as possible causes of VUR in three of the 13 families (Fig 4).

Among the new candidate genes, an extremely rare frameshift variant in LAMC1 (Laminin Subunit Gamma 1) was found to segregate with VUR in Family 76. In an early study of laminins in kidney development, no phenotypic effect on the kidney was observed in mice with a heterozygous Lamc1 mutation whereas homozygous mice died, having ectopic ureters and an absence of kidneys [51]. Lamc1 was found to regulate branching morphogenesis where inactivation of Lamc1 in the UB resulted in small kidneys or absence of kidneys, and ureters with empty bladders [52]. Although it is not clear if heterozygous mutations in LAMC1 could affect the kidney phenotype in humans, it is believed that there is a laminin concentration threshold above which UB penetration is enabled, determining the development of renal hypodysplasia or kidney agenesis [52]. In line with this, deleterious heterozygous variants in LAMC1 have been reported in rare cases in two previous studies of CAKUT in patients with ureteropelvic junction obstruction or duplex collecting system [16, 40].

The two missense variants, both predicted to be damaging, were detected in KIF26B (Kinesin Family Member 26B) in Families 17 and 77 respectively. However, only the novel variant KIF26BS123L segregated with phenotype in individual members of the family who were tested. KIF26B regulates the adhesion of mesenchymal cells in contact with ureteric buds and it is thus essential for the UB invasion of MM and UB branching [53]. Variants in KIF26B have been previously described in patients with renal hypodysplasia [54], renal coloboma syndrome [55] and multicystic dysplastic kidney [16]. The third heterozygous missense variant segregating with high-grade VUR and unilateral renal hypodysplasia was identified in LIFR (Leukemia Inhibitory Factor Receptor) in Family 32. LIFR encodes a receptor in the MM that promotes MET when bound to its ligand, LIF, secreted by the UB [56, 57]. Kosfeld et al. recently demonstrated heterozygous LIFR variants in 3.3% of CAKUT patients and similar anomalies in Lifr-deficient mice [38].

From this, a probable cause of the malformation is identified in 23% of the families in this cohort. Recent sequencing studies presented pathogenic/likely pathogenic gene variants in a smaller fraction of cases (3.2 to 17.6%) [15, 16, 37, 58]. One explanation is that their studies were on mainly non-hereditary cases with a primary focus on CAKUT rather than the VUR/renal hypodysplasia complex. Our families all had three or more individuals with the disease phenotype, in this case VUR. However, despite compelling support for a strong hereditary component, the lack of causative variants in the majority of the families and individuals in our and other studies indicates a more complex VUR aetiology. VUR appears to be a complex polygenic disorder, where a combination of risk alleles as well as environmental factors results in the disease phenotype. Kidney and ureteric development are delicate processes for which tempospatial precision is instrumental and they also involve a considerable network of proteins (partly presented in S2 File). This contributes to great heterogeneity among genes and gene variants, which could cause disease where dysfunctional. In line with this, we detect rare, damaging variants that do not segregate fully with disease within the family. These include variants in GREB1L, UPK2, DSTYK and SLIT3, all genes which have previously been associated with impaired ureteric and kidney development. GREB1L, for which a missense variant was detected in affected members of Family 76 and Family 83, encodes a cofactor in the retinoic acid mediated signalling that regulates RET expression in the UB [59]. Heterozygous knockout of Greb1l in mice causes a decrease in ureteric bud branching while the heterozygous GREB1L mutation is common in patients with renal hypodysplasia and kidney agenesis [39, 5961]. In Family 17, which also displayed a KIF26B variant, the siblings and mother, but not the cousin or the aunt, had a very rare heterozygous UPK2 splice site variant (S3 Table, Fig 2). Nicolaou et al. identified a different UPK2 splice site variant in a patient with a duplex collecting system [16]. A splice site loss in DSTYK was seen in the child and mother but not the grandmother in Family 83. The same variant was identified in a large Italian family with CAKUT (where some cases had VUR) and among an additional 311 unrelated patients with CAKUT, where 2.3% displayed different DSTYK variants [62]. However, the pathogenicity could be disputed as a study presented the detected splice variant in a patient with suspected branchio-oto-renal syndrome but with a normal kidney ultrasound but also in 10/425 in-house controls [58], i.e. much higher than available population datasets (MAF SweGen = 0.0005, gnomAD = 0.0003).

Pathogenic or likely pathogenic variants in EYA1, HNF1B, RET and PAX2 have been identified in several extensive genetic screenings of CAKUT with VUR [15, 16, 58]. However, no alterations of these genes were detected in our cohort. Instead, novel or rare variants in KIF26B, LAMC1 and LIFR, genes associated with kidney development, were shown to segregate with disease in three out of 13 families with hereditary VUR. The LAMC1 frameshift is likely to result in a variant causing a loss of function, while functional predictions for KIF26B and LIFR indicate damaging as well as activating effects on protein. Whereas constraint scores calculated by Lek et al. [63] indicates that both KIF26B and LAMC1 are sensitive to mutations and thereby support pathogenicity, this score also indicates that LIFR is relatively insensitive (S4 Table). Ultimately, the degree of pathogenicity of these variants requires further functional studies of their impact on embryonic development.

One of the methodological limitations of the study is that genetic testing was not performed on all study subjects diagnosed with the disease. The study was performed partly under financial constraints. Therefore, the most severely affected sibling and, when available, an affected second-degree relative were tested, producing maximum information per test. In addition, blood samples were not available or were not available in substantial amounts from all family members. Although most people were positive to the study when they received the invitation to participate, we had recruitment problems when they were asked to donate blood samples. Using buccal smear kits sent home by post minimized the inconvenience for children and their families, and increased the willingness to participate. However, in clinical settings this method yielded DNA of suboptimal quantity and quality, insufficient for whole-exome sequencing. Finally, as VUR is a non-visible malformation in asymptomatic individuals and is sometimes spontaneously and naturally resolved during childhood, reflux is a difficult abnormality to study in terms of inheritance. VCUG is the gold standard method of detecting VUR. However, it is a highly invasive investigation, which limits its use in asymptomatic relatives, and it was not available for older family members prior to the 1960s.

In summary, the diversity of our findings together with previous studies supports the hypothesis that primary VUR from the perspective of genetics is a very heterogeneous disease, making the genetic study of familial VUR challenging. The paucity of recurrent genes with protein-changing variants could also indicate alterations in regulatory elements affecting key genes during the embryonic development of the urinary tract.

Supporting information

S1 File. Workflow overview and specific settings for bioinformatical handling of sequence data in CLC genomic workbench.

https://doi.org/10.1371/journal.pone.0277524.s001

(PDF)

S2 File. Gene interactions and corresponding pathways in kidney development.

A simplified diagram of the interactions between kidney genes with novel or rare variants detected by WES in this study. These genes, with mainly damaging, but some tolerated mutations, participate in different signalling pathways that are crucial for the development of the lower urinary tract and kidney. Arrow, activation; continuous line, direct effect; interrupted line indirect effect, ------I inhibition. Brief explanation of gene interactions with inclusion of selected references.

https://doi.org/10.1371/journal.pone.0277524.s002

(PDF)

S1 Table. Coverage and mapping metrics.

https://doi.org/10.1371/journal.pone.0277524.s003

(XLSX)

S2 Table. Thirteen families with hereditary VUR; relationship between 13 index cases and 28 affected relatives.

https://doi.org/10.1371/journal.pone.0277524.s004

(XLSX)

S3 Table. Additional malformations of the urinary tract (UT) and other organ systems.

https://doi.org/10.1371/journal.pone.0277524.s005

(XLSX)

S4 Table. Intitial candidate variants after sequencing of 13 families with primary VUR.

https://doi.org/10.1371/journal.pone.0277524.s006

(XLSX)

References

  1. 1. Darlow JM, Dobson MG, Darlay R, Molony CM, Hunziker M, Green AJ, et al. A new genome scan for primary nonsyndromic vesicoureteric reflux emphasizes high genetic heterogeneity and shows linkage and association with various genes already implicated in urinary tract development. Mol Genet Genomic Med. 2014;2(1):7–29. Epub 2014/02/06. pmid:24498626.
  2. 2. Peters C, Rushton HG. Vesicoureteral reflux associated renal damage: congenital reflux nephropathy and acquired renal scarring. J Urol. 2010;184(1):265–73. Epub 2010/05/21. pmid:20483150.
  3. 3. Capozza N, Gulia C, Heidari Bateni Z, Zangari A, Gigli S, Briganti V, et al. Vesicoureteral reflux in infants: what do we know about the gender prevalence by age? Eur Rev Med Pharmacol Sci. 2017;21(23):5321–9. Epub 2017/12/16. pmid:29243800.
  4. 4. Noe HN, Wyatt RJ, Peeden JN Jr., Rivas ML. The transmission of vesicoureteral reflux from parent to child. J Urol. 1992;148(6):1869–71. Epub 1992/12/11. pmid:1433624.
  5. 5. Jerkins GR, Noe HN. Familial vesicoureteral reflux: a prospective study. J Urol. 1982;128(4):774–8. Epub 1982/10/01. pmid:7143601.
  6. 6. Wan J, Greenfield SP, Ng M, Zerin M, Ritchey ML, Bloom D. Sibling reflux: a dual center retrospective study. J Urol. 1996;156(2 Pt 2):677–9. Epub 1996/08/01. pmid:8683758.
  7. 7. Parekh DJ, Pope JCt, Adams MC, Brock JW 3rd. Outcome of sibling vesicoureteral reflux. J Urol. 2002;167(1):283–4. Epub 2001/12/18. pmid:11743340.
  8. 8. Chapman CJ, Bailey RR, Janus ED, Abbott GD, Lynn KL. Vesicoureteric reflux: segregation analysis. Am J Med Genet. 1985;20(4):577–84. Epub 1985/04/01. pmid:3993683.
  9. 9. Feather SA, Malcolm S, Woolf AS, Wright V, Blaydon D, Reid CJ, et al. Primary, nonsyndromic vesicoureteric reflux and its nephropathy is genetically heterogeneous, with a locus on chromosome 1. Am J Hum Genet. 2000;66(4):1420–5. Epub 2000/03/31. pmid:10739767.
  10. 10. Eccles MR, Jacobs GH. The genetics of primary vesico-ureteric reflux. Ann Acad Med Singapore. 2000;29(3):337–45. Epub 2000/09/08. pmid:10976387.
  11. 11. Sanna-Cherchi S, Reese A, Hensle T, Caridi G, Izzi C, Kim YY, et al. Familial vesicoureteral reflux: testing replication of linkage in seven new multigenerational kindreds. J Am Soc Nephrol. 2005;16(6):1781–7. Epub 2005/04/15. pmid:15829711.
  12. 12. Lu W, van Eerde AM, Fan X, Quintero-Rivera F, Kulkarni S, Ferguson H, et al. Disruption of ROBO2 is associated with urinary tract anomalies and confers risk of vesicoureteral reflux. Am J Hum Genet. 2007;80(4):616–32. Epub 2007/03/16. pmid:17357069.
  13. 13. Weng PL, Sanna-Cherchi S, Hensle T, Shapiro E, Werzberger A, Caridi G, et al. A recessive gene for primary vesicoureteral reflux maps to chromosome 12p11-q13. J Am Soc Nephrol. 2009;20(7):1633–40. Epub 2009/05/16. pmid:19443636.
  14. 14. Naseri M, Ghiggeri GM, Caridi G, Abbaszadegan MR. Five cases of severe vesico-ureteric reflux in a family with an X-linked compatible trait. Pediatr Nephrol. 2010;25(2):349–52. Epub 2009/08/26. pmid:19705159.
  15. 15. Hwang DY, Dworschak GC, Kohl S, Saisawat P, Vivante A, Hilger AC, et al. Mutations in 12 known dominant disease-causing genes clarify many congenital anomalies of the kidney and urinary tract. Kidney Int. 2014;85(6):1429–33. Epub 2014/01/17. pmid:24429398.
  16. 16. Nicolaou N, Pulit SL, Nijman IJ, Monroe GR, Feitz WF, Schreuder MF, et al. Prioritization and burden analysis of rare variants in 208 candidate genes suggest they do not play a major role in CAKUT. Kidney Int. 2016;89(2):476–86. Epub 2015/10/22. pmid:26489027.
  17. 17. Yang Y, Houle AM, Letendre J, Richter A. RET Gly691Ser mutation is associated with primary vesicoureteral reflux in the French-Canadian population from Quebec. Hum Mutat. 2008;29(5):695–702. Epub 2008/02/15. pmid:18273880.
  18. 18. Short KM, Smyth IM. Branching morphogenesis as a driver of renal development. Anat Rec (Hoboken). 2020;303(10):2578–87. Epub 2020/08/14. pmid:32790143.
  19. 19. Fillion ML, Watt CL, Gupta IR. Vesicoureteric reflux and reflux nephropathy: from mouse models to childhood disease. Pediatr Nephrol. 2014;29(4):757–66. Epub 2014/02/07. pmid:24500705.
  20. 20. Ichikawa I, Kuwayama F, Pope JCt, Stephens FD, Miyazaki Y. Paradigm shift from classic anatomic theories to contemporary cell biological views of CAKUT. Kidney Int. 2002;61(3):889–98. Epub 2002/02/19. pmid:11849443.
  21. 21. Murer L, Benetti E, Artifoni L. Embryology and genetics of primary vesico-ureteric reflux and associated renal dysplasia. Pediatr Nephrol. 2007;22(6):788–97. Epub 2007/01/12. pmid:17216254.
  22. 22. McMahon AP, Aronow BJ, Davidson DR, Davies JA, Gaido KW, Grimmond S, et al. GUDMAP: the genitourinary developmental molecular anatomy project. J Am Soc Nephrol. 2008;19(4):667–71. Epub 2008/02/22. pmid:18287559.
  23. 23. van Eerde AM, Duran K, van Riel E, de Kovel CG, Koeleman BP, Knoers NV, et al. Genes in the ureteric budding pathway: association study on vesico-ureteral reflux patients. PLoS One. 2012;7(4):e31327. Epub 2012/05/05. pmid:22558067.
  24. 24. Bertoli-Avella AM, Conte ML, Punzo F, de Graaf BM, Lama G, La Manna A, et al. ROBO2 gene variants are associated with familial vesicoureteral reflux. J Am Soc Nephrol. 2008;19(4):825–31. Epub 2008/02/01. pmid:18235093.
  25. 25. Elahi S, Homstad A, Vaidya H, Stout J, Hall G, Wu G, et al. Rare variants in tenascin genes in a cohort of children with primary vesicoureteric reflux. Pediatr Nephrol. 2015. Epub 2015/09/27. pmid:26408188.
  26. 26. Gbadegesin RA, Brophy PD, Adeyemo A, Hall G, Gupta IR, Hains D, et al. TNXB mutations can cause vesicoureteral reflux. J Am Soc Nephrol. 2013;24(8):1313–22. Epub 2013/04/27. pmid:23620400.
  27. 27. Zu S, Bartik Z, Zhao S, Sillen U, Nordenskjold A. Mutations in the ROBO2 and SLIT2 genes are rare causes of familial vesico-ureteral reflux. Pediatr Nephrol. 2009;24(8):1501–8. Epub 2009/04/08. pmid:19350278.
  28. 28. Kelly H, Molony CM, Darlow JM, Pirker ME, Yoneda A, Green AJ, et al. A genome-wide scan for genes involved in primary vesicoureteric reflux. J Med Genet. 2007;44(11):710–7. Epub 2007/07/31. pmid:17660461.
  29. 29. Sanna-Cherchi S, Caridi G, Weng PL, Dagnino M, Seri M, Konka A, et al. Localization of a gene for nonsyndromic renal hypodysplasia to chromosome 1p32-33. Am J Hum Genet. 2007;80(3):539–49. Epub 2007/02/03. pmid:17273976.
  30. 30. Conte ML, Bertoli-Avella AM, de Graaf BM, Punzo F, Lama G, La Manna A, et al. A genome search for primary vesicoureteral reflux shows further evidence for genetic heterogeneity. Pediatr Nephrol. 2008;23(4):587–95. Epub 2008/01/17. pmid:18197425.
  31. 31. Briggs CE, Guo CY, Schoettler C, Rosoklija I, Silva A, Bauer SB, et al. A genome scan in affected sib-pairs with familial vesicoureteral reflux identifies a locus on chromosome 5. Eur J Hum Genet. 2010;18(2):245–50. Epub 2009/08/20. pmid:19690587.
  32. 32. Cordell HJ, Darlay R, Charoen P, Stewart A, Gullett AM, Lambert HJ, et al. Whole-genome linkage and association scan in primary, nonsyndromic vesicoureteric reflux. J Am Soc Nephrol. 2010;21(1):113–23. Epub 2009/12/05. pmid:19959718.
  33. 33. Marchini GS, Onal B, Guo CY, Rowe CK, Kunkel L, Bauer SB, et al. Genome gender diversity in affected sib-pairs with familial vesico-ureteric reflux identified by single nucleotide polymorphism linkage analysis. BJU Int. 2012;109(11):1709–14. Epub 2011/10/11. pmid:21981614.
  34. 34. Weber S, Landwehr C, Renkert M, Hoischen A, Wuhl E, Denecke J, et al. Mapping candidate regions and genes for congenital anomalies of the kidneys and urinary tract (CAKUT) by array-based comparative genomic hybridization. Nephrol Dial Transplant. 2011;26(1):136–43. Epub 2010/07/08. pmid:20605837.
  35. 35. Kosfeld A, Kreuzer M, Daniel C, Brand F, Schafer AK, Chadt A, et al. Whole-exome sequencing identifies mutations of TBC1D1 encoding a Rab-GTPase-activating protein in patients with congenital anomalies of the kidneys and urinary tract (CAKUT). Hum Genet. 2016;135(1):69–87. Epub 2015/11/18. pmid:26572137.
  36. 36. Vivante A, Hwang DY, Kohl S, Chen J, Shril S, Schulz J, et al. Exome Sequencing Discerns Syndromes in Patients from Consanguineous Families with Congenital Anomalies of the Kidneys and Urinary Tract. J Am Soc Nephrol. 2017;28(1):69–75. Epub 2016/05/07. pmid:27151922.
  37. 37. Bekheirnia MR, Bekheirnia N, Bainbridge MN, Gu S, Coban Akdemir ZH, Gambin T, et al. Whole-exome sequencing in the molecular diagnosis of individuals with congenital anomalies of the kidney and urinary tract and identification of a new causative gene. Genet Med. 2017;19(4):412–20. Epub 2016/09/23. pmid:27657687.
  38. 38. Kosfeld A, Brand F, Weiss AC, Kreuzer M, Goerk M, Martens H, et al. Mutations in the leukemia inhibitory factor receptor (LIFR) gene and Lifr deficiency cause urinary tract malformations. Hum Mol Genet. 2017;26(9):1716–31. Epub 2017/03/24. pmid:28334964.
  39. 39. Sanna-Cherchi S, Khan K, Westland R, Krithivasan P, Fievet L, Rasouly HM, et al. Exome-wide Association Study Identifies GREB1L Mutations in Congenital Kidney Malformations. Am J Hum Genet. 2017;101(5):789–802. Epub 2017/11/04. pmid:29100090.
  40. 40. van der Ven AT, Connaughton DM, Ityel H, Mann N, Nakayama M, Chen J, et al. Whole-Exome Sequencing Identifies Causative Mutations in Families with Congenital Anomalies of the Kidney and Urinary Tract. J Am Soc Nephrol. 2018;29(9):2348–61. Epub 2018/08/26. pmid:30143558.
  41. 41. Lebowitz RL, Olbing H, Parkkulainen KV, Smellie JM, Tamminen-Mobius TE. International system of radiographic grading of vesicoureteric reflux. International Reflux Study in Children. Pediatr Radiol. 1985;15(2):105–9. Epub 1985/01/01. pmid:3975102.
  42. 42. Schwartz GJ, Brion LP, Spitzer A. The use of plasma creatinine concentration for estimating glomerular filtration rate in infants, children, and adolescents. Pediatr Clin North Am. 1987;34(3):571–90. Epub 1987/06/01. pmid:3588043.
  43. 43. Sheu JN, Wu KH, Chen SM, Tsai JD, Chao YH, Lue KH. Acute 99mTc DMSA scan predicts dilating vesicoureteral reflux in young children with a first febrile urinary tract infection: a population-based cohort study. Clin Nucl Med. 2013;38(3):163–8. Epub 2013/01/29. pmid:23354031.
  44. 44. Wennerstrom M, Hansson S, Jodal U, Stokland E. Primary and acquired renal scarring in boys and girls with urinary tract infection. J Pediatr. 2000;136(1):30–4. Epub 2000/01/15. pmid:10636970.
  45. 45. The Winberg J. 24-hour true endogenous creatinine clearance in infants and children without renal disease. Acta Paediatr. 1959;48:443–52. Epub 1959/09/01. pmid:13845172.
  46. 46. Robinson JT, Thorvaldsdottir H, Winckler W, Guttman M, Lander ES, Getz G, et al. Integrative genomics viewer. Nat Biotechnol. 2011;29(1):24–6. Epub 2011/01/12. pmid:21221095.
  47. 47. Haddad N, El Andalousi J, Khairallah H, Yu M, Ryan AK, Gupta IR. The tight junction protein claudin-3 shows conserved expression in the nephric duct and ureteric bud and promotes tubulogenesis in vitro. Am J Physiol Renal Physiol. 2011;301(5):F1057–65. Epub 2011/07/22. pmid:21775479.
  48. 48. Soofi A, Zhang P, Dressler GR. Kielin/chordin-like protein attenuates both acute and chronic renal injury. J Am Soc Nephrol. 2013;24(6):897–905. Epub 2013/03/30. pmid:23539757.
  49. 49. Hwang JH, Yang SH, Kim YC, Kim JH, An JN, Moon KC, et al. Experimental Inhibition of Periostin Attenuates Kidney Fibrosis. Am J Nephrol. 2017;46(6):501–17. Epub 2017/12/22. pmid:29268247.
  50. 50. Matsumoto S, Fujii S, Sato A, Ibuka S, Kagawa Y, Ishii M, et al. A combination of Wnt and growth factor signaling induces Arl4c expression to form epithelial tubular structures. Embo j. 2014;33(7):702–18. Epub 2014/02/25. pmid:24562386.
  51. 51. Willem M, Miosge N, Halfter W, Smyth N, Jannetti I, Burghart E, et al. Specific ablation of the nidogen-binding site in the laminin gamma1 chain interferes with kidney and lung development. Development. 2002;129(11):2711–22. Epub 2002/05/17. pmid:12015298.
  52. 52. Yang DH, McKee KK, Chen ZL, Mernaugh G, Strickland S, Zent R, et al. Renal collecting system growth and function depend upon embryonic gamma1 laminin expression. Development. 2011;138(20):4535–44. Epub 2011/09/10. pmid:21903675.
  53. 53. Uchiyama Y, Sakaguchi M, Terabayashi T, Inenaga T, Inoue S, Kobayashi C, et al. Kif26b, a kinesin family gene, regulates adhesion of the embryonic kidney mesenchyme. Proc Natl Acad Sci U S A. 2010;107(20):9240–5. Epub 2010/05/05. pmid:20439720.
  54. 54. Sanna-Cherchi S, Kiryluk K, Burgess KE, Bodria M, Sampson MG, Hadley D, et al. Copy-number disorders are a common cause of congenital kidney malformations. Am J Hum Genet. 2012;91(6):987–97. Epub 2012/11/20. pmid:23159250.
  55. 55. Okumura T, Furuichi K, Higashide T, Sakurai M, Hashimoto S, Shinozaki Y, et al. Association of PAX2 and Other Gene Mutations with the Clinical Manifestations of Renal Coloboma Syndrome. PLoS One. 2015;10(11):e0142843. Epub 2015/11/17. pmid:26571382.
  56. 56. Barasch J, Yang J, Ware CB, Taga T, Yoshida K, Erdjument-Bromage H, et al. Mesenchymal to epithelial conversion in rat metanephros is induced by LIF. Cell. 1999;99(4):377–86. Epub 1999/11/26. pmid:10571180.
  57. 57. Plisov SY, Yoshino K, Dove LF, Higinbotham KG, Rubin JS, Perantoni AO. TGF beta 2, LIF and FGF2 cooperate to induce nephrogenesis. Development. 2001;128(7):1045–57. Epub 2001/03/14. pmid:11245570.
  58. 58. Heidet L, Moriniere V, Henry C, De Tomasi L, Reilly ML, Humbert C, et al. Targeted Exome Sequencing Identifies PBX1 as Involved in Monogenic Congenital Anomalies of the Kidney and Urinary Tract. J Am Soc Nephrol. 2017;28(10):2901–14. Epub 2017/06/02. pmid:28566479.
  59. 59. Brophy PD, Rasmussen M, Parida M, Bonde G, Darbro BW, Hong X, et al. A Gene Implicated in Activation of Retinoic Acid Receptor Targets Is a Novel Renal Agenesis Gene in Humans. Genetics. 2017;207(1):215–28. Epub 2017/07/26. pmid:28739660.
  60. 60. De Tomasi L, David P, Humbert C, Silbermann F, Arrondel C, Tores F, et al. Mutations in GREB1L Cause Bilateral Kidney Agenesis in Humans and Mice. Am J Hum Genet. 2017;101(5):803–14. Epub 2017/11/04. pmid:29100091.
  61. 61. Rasmussen M, Sunde L, Nielsen ML, Ramsing M, Petersen A, Hjortshoj TD, et al. Targeted Gene Sequencing and Whole-Exome Sequencing in Autopsied Fetuses with Prenatally Diagnosed Kidney Anomalies. Clin Genet. 2017. Epub 2017/12/02. pmid:29194579.
  62. 62. Sanna-Cherchi S, Sampogna RV, Papeta N, Burgess KE, Nees SN, Perry BJ, et al. Mutations in DSTYK and dominant urinary tract malformations. N Engl J Med. 2013;369(7):621–9. Epub 2013/07/19. pmid:23862974.
  63. 63. Lek M, Karczewski KJ, Minikel EV, Samocha KE, Banks E, Fennell T, et al. Analysis of protein-coding genetic variation in 60,706 humans. Nature. 2016;536(7616):285–91. Epub 2016/08/19. pmid:27535533.