Audrey Pawtowski

Spectrum of HNF1B mutations in a large cohort of patients who harbor renal diseases.

BACKGROUND AND OBJECTIVES Hepatocyte nuclear factor 1beta (HNF1beta) is a transcription factor that is critical for the development of kidney and pancreas. In humans, mutations in HNF1B lead to congenital anomalies of the kidney and urinary tract, pancreas atrophy, and maturity-onset diabetes of the young type 5 and genital malformations. DESIGN, SETTING, PARTICIPANTS, & MEASUREMENTS We report HNF1B screening in a cohort of 377 unrelated cases with various kidney phenotypes (hyperechogenic kidneys with size not more than +3 SD, multicystic kidney disease, renal agenesis, renal hypoplasia, cystic dysplasia, or hyperuricemic tubulointerstitial nephropathy not associated with UMOD mutation). RESULTS We found a heterozygous mutation in 75 (19.9%) index cases, consisting of a deletion of the whole gene in 42, deletion of one exon in one, and small mutations in 32. Eighteen mutations were novel. De novo mutations accounted for 66% of deletions and 40% of small mutations. In patients who carried HNF1B mutation and for whom we were able to study prenatal ultrasonography (56 probands), isolated hyperechogenic kidneys with normal or slightly enhanced size were the more frequent (34 of 56) phenotype before birth. Various other prenatal renal phenotypes were associated with HNF1B mutations, at a lesser frequency. Diabetes developed in four probands. Hyperuricemia and hypomagnesemia, although not systematically investigated, were frequently associated. CONCLUSIONS This large series showed that the severity of the renal disease associated with HNF1B mutations was extremely variable (from prenatal renal failure to normal renal function in adulthood) and was not correlated with the genotype.

Dominant Renin Gene Mutations Associated with Early-Onset Hyperuricemia, Anemia, and Chronic Kidney Failure

Through linkage analysis and candidate gene sequencing, we identified three unrelated families with the autosomal-dominant inheritance of early onset anemia, hypouricosuric hyperuricemia, progressive kidney failure, and mutations resulting either in the deletion (p.Leu16del) or the amino acid exchange (p.Leu16Arg) of a single leucine residue in the signal sequence of renin. Both mutations decrease signal sequence hydrophobicity and are predicted by bioinformatic analyses to damage targeting and cotranslational translocation of preprorenin into the endoplasmic reticulum (ER). Transfection and in vitro studies confirmed that both mutations affect ER translocation and processing of nascent preprorenin, resulting either in reduced (p.Leu16del) or abolished (p.Leu16Arg) prorenin and renin biosynthesis and secretion. Expression of renin and other components of the renin-angiotensin system was decreased accordingly in kidney biopsy specimens from affected individuals. Cells stably expressing the p.Leu16del protein showed activated ER stress, unfolded protein response, and reduced growth rate. It is likely that expression of the mutant proteins has a dominant toxic effect gradually reducing the viability of renin-expressing cells. This alters the intrarenal renin-angiotensin system and the juxtaglomerular apparatus functionality and leads to nephron dropout and progressive kidney failure. Our findings provide insight into the functionality of renin-angiotensin system and stress the importance of renin analysis in families and individuals with early onset hyperuricemia, anemia, and progressive kidney failure.

Genotype-phenotype correlations in non-Finnish congenital nephrotic syndrome.

Mutations in NPHS1, which encodes nephrin, are the main causes of congenital nephrotic syndrome (CNS) in Finnish patients, whereas mutations in NPHS2, which encodes podocin, are typically responsible for childhood-onset steroid-resistant nephrotic syndrome in European populations. Genotype-phenotype correlations are not well understood in non-Finnish patients. We evaluated the clinical presentation, kidney histology, and disease progression in non-Finnish CNS cases by mutational screening in 107 families (117 cases) by sequencing the entire coding regions of NPHS1, NPHS2, PLCE1, WT1, LAMB2, PDSS2, COQ2, and NEPH1. We found that CNS describes a heterogeneous group of disorders in non-Finnish populations. We identified nephrin and podocin mutations in most families and only rarely found mutations in genes implicated in other hereditary forms of NS. In approximately 20% of cases, we could not identify the underlying genetic cause. Consistent with the major role of nephrin at the slit diaphragm, NPHS1 mutations associated with an earlier onset of disease and worse renal outcomes than NPHS2 mutations. Milder cases resulting from mutant NPHS1 had either two mutations in the cytoplasmic tail or two missense mutations in the extracellular domain, including at least one that preserved structure and function. In addition, we extend the spectrum of known NPHS1 mutations by describing long NPHS1 deletions. In summary, these data demonstrate that CNS is not a distinct clinical entity in non-Finnish populations but rather a clinically and genetically heterogeneous group of disorders.

Mutations of NPHP2 and NPHP3 in infantile nephronophthisis

Nephronophthisis is an autosomal recessive chronic tubulointerstitial disease that progresses to end-stage renal disease (ESRD) in about 10% of cases during infancy. Mutations in the INVS (NPHP2) gene were found in a few patients with infantile nephronophthisis. Mutations of NPHP3, known to be associated with adolescent nephronophthisis, were found in two patients with early-onset ESRD. Here we screened 43 families with infantile nephronophthisis (ESRD less than 5 years of age) for NPHP2 and NPHP3 mutations and determined genotype-phenotype correlations. In this cohort there were 16 families with NPHP2 mutations and NPHP3 mutations in seven. Three patients carried only one heterozygous mutation in NPHP3. ESRD arose during the first 2 years of life in 16 of 18 patients with mutations in NPHP2, but in only two patients with mutations in NPHP3. Renal morphology, characterized by hyper-echogenic kidneys on ultrasound and tubular lesions with interstitial fibrosis on histology, was similar in the two patient groups. The kidney sizes were highly diverse and ultrasound-visualized cysts were present in a minority of cases. Extra-renal anomalies were found in 80% of the entire cohort including hepatic involvement (50%), cardiac valve or septal defects (20%) and recurrent bronchial infections (18%). We show that NPHP3 mutations in both infantile and adolescent nephronophthisis point to a common pathophysiological mechanism despite their different clinical presentations.

Phenotype and Outcome in Hereditary Tubulointerstitial Nephritis Secondary to UMOD Mutations

BACKGROUND UMOD mutations cause familial juvenile hyperuricemic nephropathy (FJHN) and medullary cystic kidney disease (MCKD), although these phenotypes are nonspecific. DESIGN, SETTING, PARTICIPANTS, & MEASUREMENTS We reviewed cases of UMOD mutations diagnosed in the genetic laboratories of Necker Hospital (Paris, France) and of Université Catholique de Louvain (Brussels, Belgium). We also analyzed patients with MCKD/FJHN but no UMOD mutation. To determine thresholds for hyperuricemia and uric-acid excretion fraction (UAEF) according to GFR, these parameters were analyzed in 1097 patients with various renal diseases and renal function levels. RESULTS Thirty-seven distinct UMOD mutations were found in 109 patients from 45 families, all in exon 4 or 5 except for three novel mutations in exon 8. Median renal survival was 54 years. The type of mutation had a modest effect on renal survival, and intrafamilial variability was high. Detailed data available in 70 patients showed renal cysts in 24 (34.3%) of nonspecific localization in most patients. Uricemia was >75th percentile in 31 (71.4%) of 42 patients not under dialysis or allopurinol therapy. UAEF (n = 27) was <75th percentile in 70.4%. Among 136 probands with MCKD/FJHN phenotype, UMOD mutation was found in 24 (17.8%). Phenotype was not accurately predictive of UMOD mutation. Six probands had HNF1B mutations. CONCLUSIONS Hyperuricemia disproportionate to renal function represents the hallmark of renal disease caused by UMOD mutation. Renal survival is highly variable in patients with UMOD mutation. Our data also add novel insights into the interpretation of uricemia and UAEF in patients with chronic kidney diseases.

Mutational analysis of the PLCE1 gene in steroid resistant nephrotic syndrome

Background Mutations in the PLCE1 gene encoding phospholipase C epsilon 1 (PLCɛ1) have been recently described in patients with early onset nephrotic syndrome (NS) and diffuse mesangial sclerosis (DMS). In addition, two cases of PLCE1 mutations associated with focal segmental glomerulosclerosis (FSGS) and later NS onset have been reported. Method In order to better assess the spectrum of phenotypes associated with PLCE1 mutations, mutational analysis was performed in a worldwide cohort of 139 patients (95 familial cases belonging to 68 families and 44 sporadic cases) with steroid resistant NS presenting at a median age of 23.0 months (range 0–373). Results Homozygous or compound heterozygous mutations were identified in 33% (8/24) of DMS cases. PLCE1 mutations were found in 8% (6/78) of FSGS cases without NPHS2 mutations. Nine were novel mutations. No clear genotype–phenotype correlation was observed, with either truncating or missense mutations detected in both DMS and FSGS, and leading to a similar renal evolution. Surprisingly, three unaffected and unrelated individuals were also found to carry the homozygous mutations identified in their respective families. Conclusion PLCE1 is a major gene of DMS and is mutated in a non-negligible proportion of FSGS cases without NPHS2 mutations. Although additional variants in 19 candidate genes (16 other PLC genes, BRAF,IQGAP1 and NPHS1) were not identified, it is speculated that other modifier genes or environmental factors may play a role in the renal phenotype variability observed in individuals bearing PLCE1 mutations. This observation needs to be considered in the genetic counselling offered to patients.

Spectrum of mutations in the renin-angiotensin system genes in autosomal recessive renal tubular dysgenesis

Autosomal recessive renal tubular dysgenesis (RTD) is a severe disorder of renal tubular development characterized by early onset and persistent fetal anuria leading to oligohydramnios and the Potter sequence, associated with skull ossification defects. Early death occurs in most cases from anuria, pulmonary hypoplasia, and refractory arterial hypotension. The disease is linked to mutations in the genes encoding several components of the renin–angiotensin system (RAS): AGT (angiotensinogen), REN (renin), ACE (angiotensin‐converting enzyme), and AGTR1 (angiotensin II receptor type 1). Here, we review the series of 54 distinct mutations identified in 48 unrelated families. Most of them are novel and ACE mutations are the most frequent, observed in two‐thirds of families (64.6%). The severity of the clinical course was similar whatever the mutated gene, which underlines the importance of a functional RAS in the maintenance of blood pressure and renal blood flow during the life of a human fetus. Renal hypoperfusion, whether genetic or secondary to a variety of diseases, precludes the normal development/ differentiation of proximal tubules. The identification of the disease on the basis of precise clinical and histological analyses and the characterization of the genetic defects allow genetic counseling and early prenatal diagnosis. Hum Mutat 33:316–326, 2012.

Mutations des gènes du SRA et anomalies du développement rénal

Autosomal recessive renal tubular dysgenesis (RTD) is a clinical disorder observed in fetuses, characterized by absence or poor development of proximal tubules and early onset and persistent oligohydramnios leading to the Potter sequence, associated with skull ossification defect. The disease is uniformly severe resulting in low blood pressure and perinatal death in most cases or in chronic renal disease in the few surviving patients. Based on the phenotype and the finding of striking changes in renal renin expression (absent or massive), we hypothesized and demonstrated that genetic defects in the renin-angiotensin system (RAS) components are the underlying causes of the disease. At the present time, molecular screening has been performed in 46 families (F) and homozygous or compound heterozygous mutations have been detected in 41. They affect the genes encoding renine (9F), angiotensinogen (3F), AT1 receptor (3F) and angiotensin converting enzyme (26F). These findings highlight the importance of the RAS during human kidney development. Moreover, the identification of the disease based on precise histological and immunohistological analysis, and the research of the genetic defect, now allow genetic counseling and early prenatal diagnosis.

More on Clinical Renal Genetics

Epidemiologic studies of rare diseases may produce surprising findings and raise ethical issues. This is illustrated in this study performed in 171,977 consecutive Taiwanese newborns (including 90,288 boys) from July 2006 through June 2008 by measuring dry blood spot and then leukocyte -galactosidase A ( -Gal A) activities and finally by detecting mutations in the GLA gene involved in Fabry disease. Schematically, two phenotypes of this disease are known: the classic form, with systemic involvement and very low -Gal activity in males; and the later-onset form ( 40 years of age), with some residual -Gal A activity, which is dominated by cardiac involvement. All 11 newborns who had 5% of normal mean -Gal A activity were boys who had GLA mutations. In the group of 66 newborns (64 boys and 2 girls) with -Gal A activities between 5% and 30%, 61 hemizygous boys and 2 heterozygous girls had GLA mutations. Among the group of 12 newborns (11 boys and 1 girl) with -Gal A 30%, only 1 boy had a previously reported mutation, identified in a family with later-onset renal disease. In total, 72 male and 2 female newborns had GLA mutations, an overall frequency of approximately 1 in 1250 boys and approximately 1 in 40,840 girls. Four boys were “predicted” to have the classic phenotype, a frequency of about 1 in 22,570 newborn boys. In contrast, the estimated frequency of the lateronset phenotype is approximately 1 in 1390 male newborns mutations. Three families provided information on other members of the kindreds, two with classic and one with later-onset phenotype. All three families had previously undiagnosed symptomatic family members, including one heterozygous female with ESRD and two males with renal involvement. This is undoubtedly the positive side of such studies. A second study was performed more recently in 110,027 Taiwanese newborns between January 2008 and January 2009 by using a similar protocol (plasma -Gal A activity was measured) (1). The results of this study confirmed those of the previous screening. A high prevalence of the cardiac variant Fabry mutation IVS4 919G3A, first discovered in Japanese patients, was found among newborns (approximately 1 in 1600 boys) in both studies. This splicing mutation was most common (82% of patients). The alternatively spliced transcript was normally present in small amount ( 5% of normal transcript) in most human tissues. However, the G3A transversion enhanced the percent expression of the alternatively spliced -Gal A variant and included a 57-nucleotide intronic sequence that caused a frameshift mutation, resulting in a truncated enzyme polypeptide that had no detectable enzyme activity. The clinical significance of this splicing mutation remains to be fully clarified. Of interest, Lin et al. (1) have investigated 9 grandfathers and 11 grandmothers carrying this mutation, as do their respective grandsons. Among the 9 maternal grandfathers, only 3 had hypertrophic cardiomyopathy, compared with none of the 11 grandmothers. These results should be compared with those reported in 2006 from Torino, Piedmont, Italy, by Spada et al. (2). They screened 37,000 consecutive newborns with similar methods and identified 12 infants with GLA mutations, including 11 who had molecular lesions that expressed residual activity consistent with the later-onset phenotype. The overall frequency of Fabry mutations was approximately 1 in 3100 Caucasian boys. Mutation analysis predicted that one of the newborns had the classic phenotype (1 in approximately 37,000), whereas 11 of the newborns were predicted to have the later-onset phenotype (1 in approximately 3400). The prevalence of the classic form is close to that found in previous estimations, whereas that of the later-onset phenotype seems to be higher than commonly thought. In Taiwan, the frequency was 2.5 times more frequent than in the Italian population. These studies raise many ethical and clinical issues. What can be said to the parents of neonates harboring a GLA mutation suggestive of a later-onset disease? The clinical consequences of some mutations, if any, cannot be predicted. The ethnic background should be taken into account. If clinical consequences can be expected, when to start evaluating the cardiac condition and when to consider enzyme replacement therapy, if necessary? What are the psychologic consequences of the screening on the mutation carrier and his/her family? The ethical issues raised by early detection and prediction of later-onset genetic Published online ahead of print. Publication date available at www.cjasn.org.