Nadja Bogdanova

Comparison of phenotypes of polycystic kidney disease types 1 and 2

BACKGROUND Although autosomal dominant polycystic kidney disease type 2 (PKD2) is known to have a milder clinical phenotype than PKD1, neither disorder has been compared with an unaffected control population in terms of survival. We report the findings of a multicentre survey that aimed to define more precisely the survival and clinical expression of PKD1 and PKD2. METHODS Clinical data from 333 people with PKD1 (31 families) were compared with data from 291 people with PKD2 (31 families) and 398 geographically matched controls. Survival analysis was used to compare age-at-event data. Differences in the prevalence of complications were assessed by logistic regression. FINDINGS Median age at death or onset of end-stage renal disease was 53.0 years (95% CI 51.2-54.8) in individuals with PKD1, 69.1 years (66.9-71.3) in those with PKD2, and 78.0 years (73.8-82.2) in controls. Women with PKD2 had a significantly longer median survival than men (71.0 [67.4-74.8] vs 67.3 [64.9-69.7] years), but no sex influence was apparent in PKD1. Age at presentation with kidney failure was later in PKD2 than in PKD1 (median age 74.0 [67.2-80.8] vs 54.3 [52.7-55.9] years). PKD2 patients were less likely to have hypertension (odds ratio 0.25 [95% CI 0.15-0.42]), a history of urinary-tract infection (0.50 [0.31-0.83]), or haematuria (0.59 [0.35-0.98]). INTERPRETATION Although PKD2 is clinically milder than PKD1, it has a deleterious impact on overall life expectancy and cannot be regarded as a benign disorder.

Genotype-Renal Function Correlation in Type 2 Autosomal Dominant Polycystic Kidney Disease

Autosomal dominant polycystic kidney disease (ADPKD) is a common Mendelian disorder that affects approximately 1 in 1000 live births. Mutations of two genes, PKD1 and PKD2, account for the disease in approximately 80 to 85% and 10 to 15% of the cases, respectively. Significant interfamilial and intrafamilial renal disease variability in ADPKD has been well documented. Locus heterogeneity is a major determinant for interfamilial disease variability (i.e., patients from PKD1-linked families have a significantly earlier onset of ESRD compared with patients from PKD2-linked families). More recently, two studies have suggested that allelic heterogeneity might influence renal disease severity. The current study examined the genotype-renal function correlation in 461 affected individuals from 71 ADPKD families with known PKD2 mutations. Fifty different mutations were identified in these families, spanning between exon 1 and 14 of PKD2. Most (94%) of these mutations were predicted to be inactivating. The renal outcomes of these patients, including the age of onset of end-stage renal disease (ESRD) and chronic renal failure (CRF; defined as creatinine clearance < or = 50 ml/min, calculated using the Cockroft and Gault formula), were analyzed. Of all the affected individuals clinically assessed, 117 (25.4%) had ESRD, 47 (10.2%) died without ESRD, 65 (14.0%) had CRF, and 232 (50.3%) had neither CRF nor ESRD at the last follow-up. Female patients, compared with male patients, had a later mean age of onset of ESRD (76.0 [95% CI, 73.8 to 78.1] versus 68.1 [95% CI, 66.0 to 70.2] yr) and CRF (72.5 [95% CI, 70.1 to 74.9] versus 63.7 [95% CI, 61.4 to 66.0] yr). Linear regression and renal survival analyses revealed that the location of PKD2 mutations did not influence the age of onset of ESRD. However, patients with splice site mutations appeared to have milder renal disease compared with patients with other mutation types (P < 0.04 by log rank test; adjusted for the gender effect). Considerable renal disease variability was also found among affected individuals with the same PKD2 mutations. This variability can confound the determination of allelic effects and supports the notion that additional genetic and/or environmental factors may modulate the renal disease severity in ADPKD.

A spectrum of mutations in the second gene for autosomal dominant polycystic kidney disease (PKD2).

Recently the second gene for autosomal dominant polycystic kidney disease (ADPKD), located on chromosome 4q21-q22, has been cloned and characterized. The gene encodes an integral membrane protein, polycystin-2, that shows amino acid similarity to the PKD1 gene product and to the family of voltage-activated calcium (and sodium) channels. We have systematically screened the gene for mutations by single-strand conformation-polymorphism analysis in 35 families with the second type of ADPKD and have identified 20 mutations. So far, most mutations found seem to be unique and occur throughout the gene, without any evidence of clustering. In addition to small deletions, insertions, and substitutions leading to premature translation stops, one amino acid substitution and five possible splice-site mutations have been found. These findings suggest that the first step toward cyst formation in PKD2 patients is the loss of one functional copy of polycystin-2.

Incompletely Penetrant PKD1 Alleles Mimic the Renal Manifestations of ARPKD

Autosomal dominant polycystic kidney disease (ADPKD), caused by mutation in PKD1 or PKD2, is usually an adult-onset disorder but can rarely manifest as a neonatal disease within a family characterized by otherwise typical ADPKD. Coinheritance of a hypomorphic PKD1 allele in trans with an inactivating PKD1 allele is one mechanism that can cause early onset ADPKD. Here, we describe two pedigrees without a history of cystic kidney disease that each contain two patients with onset of massive PKD in utero. The presentations were typical of autosomal recessive PKD (ARPKD) but they were not linked to the known ARPKD gene, PKHD1. Mutation analysis of the ADPKD genes provided strong evidence that both families inherited, in trans, two incompletely penetrant PKD1 alleles. These patients illustrate that PKD1 mutations can manifest as a phenocopy of ARPKD with respect to renal involvement and highlight the perils of linkage-based diagnostics in ARPKD without positive PKHD1 mutation data. Furthermore, the phenotypic overlap between ARPKD and these patients resulting from incomplete penetrant PKD1 alleles support a common pathogenesis for these diseases.

Genetic Variation of DKK3 May Modify Renal Disease Severity in ADPKD

Significant variation in the course of autosomal dominant polycystic kidney disease ( ADPKD) within families suggests the presence of effect modifiers. Recent studies of the variation within families harboring PKD1 mutations indicate that genetic background may account for 32 to 42% of the variance in estimated GFR (eGFR) before ESRD and 43 to 78% of the variance in age at ESRD onset, but the genetic modifiers are unknown. Here, we conducted a high-throughput single-nucleotide polymorphism (SNP) genotyping association study of 173 biological candidate genes in 794 white patients from 227 families with PKD1. We analyzed two primary outcomes: (1) eGFR and (2) time to ESRD (renal survival). For both outcomes, we used multidimensional scaling to correct for population structure and generalized estimating equations to account for the relatedness among individuals within the same family. We found suggestive associations between each of 12 SNPs and at least one of the renal outcomes. We genotyped these SNPs in a second set of 472 white patients from 229 families with PKD1 and performed a joint analysis on both cohorts. Three SNPs continued to show suggestive/significant association with eGFR at the Dickkopf 3 (DKK3) gene locus; no SNPs significantly associated with renal survival. DKK3 antagonizes Wnt/beta-catenin signaling, which may modulate renal cyst growth. Pending replication, our study suggests that genetic variation of DKK3 may modify severity of ADPKD resulting from PKD1 mutations.

Evidence of a third ADPKD locus is not supported by re-analysis of designated PKD3 families

Mutations to PKD1 and PKD2 are associated with autosomal dominant polycystic kidney disease (ADPKD). The absence of apparent PKD1/PKD2 linkage in five published European or North American families with ADPKD suggested a third locus, designated PKD3. Here we re-evaluated these families by updating clinical information, re-sampling where possible, and mutation screening for PKD1/PKD2. In the French-Canadian family we identified PKD1: p.D3782_V3783insD, with misdiagnoses in two individuals and sample contamination explaining the lack of linkage. In the Portuguese family, PKD1: p.G3818A segregated with the disease in 10 individuals in three generations with likely misdiagnosis in one individual, sample contamination, and use of distant microsatellite markers explaining the linkage discrepancy. The mutation, PKD2: c.213delC, was found in the Bulgarian family, with linkage failure attributed to false positive diagnoses in two individuals. An affected son but not the mother, in the Italian family had the nonsense mutation, PKD1: p.R4228X, which appeared de novo in the son; with simple cysts probably explaining the mother’s phenotype. No likely mutation was found in the Spanish family, but the phenotype was atypical with kidney atrophy in one case. Thus, re-analysis does not support the existence of a PKD3 in ADPKD. False positive diagnoses by ultrasound in all resolved families shows the value of mutation screening, but not linkage, to understand families with discrepant data.

Gene Expression Patterns in Relation to the Clinical Phenotype in Klinefelter Syndrome

CONTEXT Klinefelter syndrome (KS) is the most common chromosome disorder in men (47,XXY), exhibiting a phenotype with marked variation and increased morbidity. The pathophysiological link between the supernumerary X chromosome and the clinical phenotype remains unknown. OBJECTIVE To elucidate whether differential gene expression patterns can be detected in KS patients and whether these are related to inherent clinical features. DESIGN, SETTING, PARTICIPANTS EXAKT (Epigenetics, X-chromosomal Features and Clinical Applications in Klinefelter Syndrome Trial) is a Münster-based prospective project involving 132 Klinefelter men and their parents. A range of cardiovascular, inflammatory, and metabolic factors, in comparison to age-matched male (n = 50)/female controls (n = 50) and in relation to genetic features, is assessed. MAIN OUTCOMES AND MEASURES Our predefined hypothesis was that differential gene expression patterns in blood cells exist in KS patients vs male controls and are related to the clinical phenotype. RESULTS Differential expression of 36 X-chromosomal and autosomal genes put KS patients into a unique genetic setting vs male and female controls. The KS cohort exhibited increased insulin resistance, enhanced inflammatory and procoagulatory status, higher waist circumference, dyslipidemia, and a markedly shorter 12-lead electrocardiogram QTc interval (partly located within the pathological range) vs male controls (all P < .001). Clinical dyshomeostasis was associated with expression patterns of dysregulated genes (all P < .01). Parental origin of the supernumerary X chromosome was a confounder regarding insulin resistance and cardiac phenotype (P < .05). Results are considered preliminary because gene expression was measured in blood cells. CONCLUSIONS The supernumerary X chromosome contributes to a number of pathologies in KS. The pattern of gene expression is altered in KS, and the degree of differential gene expression is associated with the clinical phenotype.

Paternal and maternal carriage of the annexin A5 M2 haplotype are equal risk factors for recurrent pregnancy loss: a pilot study

OBJECTIVE To study the possible contribution of paternal, in addition to maternal, carriage of M2/ANXA5 as a risk factor for recurrent pregnancy loss (RPL). DESIGN Case-control study. SETTING Academic research center. PATIENT(S) Couples presenting themselves to the Fertility Center, Ludwig-Maximilians-University Munich with two or more consecutive, unexplained miscarriages were selected for this study. Fertile female controls were from the same center and also from the resource of the Institute of Human Genetics, Westfalian Wilhelms-University Muenster. Population controls were drafted from the PopGen biobank, University Clinic Schleswig-Holstein Kiel. INTERVENTION(S) None. MAIN OUTCOME MEASURE(S) Incidence of M2 carriage was estimated in patient and control groups, odds ratios were calculated, and RPL risk was evaluated. RESULT(S) In comparison with female fertile controls, the risk for repeated abortion in the RPL group, associated with M2 carriage, was between 1.7 and 3.8, and it was 2.3 compared with population controls. Because of the equal genetic incidence of M2, with an allelic frequency of 0.167 in the female and male partner RPL subgroups, the haplotype confers approximately the same relative risk to carriers of both sexes. CONCLUSION(S) Paternal M2 carriage seems to confer an equal risk for recurrent miscarriages as M2 carriage in RPL mothers. This finding points to a role of ANXA5 and the M2 haplotype in the fetus and/or the extraembryonic membranes for pregnancy pathology. Prognostic RPL algorithms might be improved by testing the male partner for M2 carriage, and this may guide adequate therapeutic decisions.

Long-term secondary prophylaxis in children, adolescents and young adults with von Willebrand disease

In patients with von Willebrand disease (VWD) replacement therapy with factor VIII/von Willebrand (VWF) concentrates is increasingly applied as prophylactic regimen. Since 2000, 82 consecutively enrolled patients with clinically relevant bleeding episodes (spontaneous, peri- or postoperative) were diagnosed with VWD [type 1: 42/82; type 2: 24/82; type 3: 13/82; acquired: 3/82]. In all patients, decision for initiating prophylaxis was based on a bleeding score > 2 prior to diagnosis, concomitant with recurrent bleeds associated with anaemia in patients with on-demand VWD therapy. We report results on secondary prophylactic VWF replacement therapy applied in 32 patients [children n=13; adolescents n=7; adults n=12] with VWD [type 1: 4; type 2: 15; type 3: 13], 15 of which were females, and nine of these at the reproductive period. Eight patients were treated with Humate P® or Wilate® (n=24). Median [min-max] dose [vWF:RCo] was 40 [20-47] IU/kg, 23 patients were given substitution therapy twice weekly, seven patients three times a week, and two children four times per week. Within a 12-month-period haemoglobin concentrations returned to normal values. Median duration of prophylaxis was three years. Recurrent bleeding episodes stopped in 31 of 32 patients, whereas inhibitors developed in one. Following a 12-month observation period the monthly bleeding frequency and the bleeding score was significantly reduced [3 vs. 0.07; 3 vs. 0: p< 0.001], compared to the pre-prophylaxis/pre-diagnostic values. The use of secondary prophylactic VWF replacement therapy is an effective tolerated treatment modality, highly beneficial for patients with VWD, who present with recurrent bleeding events during on-demand therapy.

Hereditary thrombophilic risk factors for recurrent pregnancy loss

This review summarizes current knowledge about the role of hereditary hypercoagulation factors predisposing to thrombophilia-associated recurrent fetal loss. Thrombophilias are a major cause of adverse pregnancy outcome, playing a role in the etiology of up to 40% of cases worldwide. Hereditary thrombophilic predispositions to recurrent pregnancy wastage include genetic lesions in blood coagulation factors II and V as well as natural anticoagulants antithrombin, protein C, and protein S. Furthermore, methylenetetrahydrofolate reductase gene variants conferring higher thrombophilia risk in combination with these mutations and the newly described annexin A5 gene M2 promoter allele are associated with repeated fetal loss. The review gives a concise description of the molecular defects arising from the genetic changes, of the role these factors play in the timing and definition of fetal loss, and risk estimates from available studies and meta-analysis. This knowledge is instrumental for a more precise assessment of individual risks for repeated fetal loss and should guide therapeutic strategies, where relevant. Since the average childbearing age increases in Western societies, the importance of a timely diagnosis of fetal loss predisposition is increasing.