Modifier genes play a significant role in the phenotypic expression of PKD1

BACKGROUND: Polycystic kidney disease type 1 (PKD1) is characterized by extreme variation in the severity and progression of renal and extrarenal phenotypes. There are significant familial phenotype differences; but it is not clear if this is due to differences in PKD1 mutations, differences in genetic background, or both. METHODS: A total of 315 affected relatives (83 PKD1 families) without end-stage renal disease (ESRD) were evaluated for disease markers, including renal volume, creatinine clearance, proteinuria, liver cysts, and hypertension. Of these patients, 19% progressed to ESRD within 1 to 10 years after the initial examination. Nested analysis of variance was used to investigate interfamilial and intrafamilial differences in these phenotypes. Heritability analyses were used to estimate the effect of the genetic background on phenotypic variability. The age of onset of ESRD was also analyzed with an additional 389 family members from the same PKD1 families without clinical evaluation but with data on age of onset of ESRD (or age without ESRD). RESULTS: There were significant phenotype differences between patients with the same mutation and different genetic backgrounds. The phenotypic variation between patients with different mutations and different genetic backgrounds was not significantly greater than the variation between patients with the same mutation and different genetic backgrounds. However, when the 389 family members were included, both the mutation and modifier genes had significant effects on the age of onset of ESRD. Inherited differences in genetic background were estimated to account for 18% to 59% of the phenotypic variability in PKD1 disease markers in patients prior to ESRD and in the subsequent progression to ESRD (43% heritability) in the 315 patients who were clinically evaluated. CONCLUSION: Modifier loci in the genetic background are important factors in inter- and intrafamilial variability in the phenotypic expression of PKD1. The extreme intrafamilial phenotype differences are consistent with the hypothesis that one or a few modifier genes have a major effect on the progression and severity of PKD1.     

The position of the polycystic kidney disease 1 (PKD1) gene mutation correlates with the severity of renal disease

The severity of renal cystic disease in the major form of autosomal dominant polycystic kidney disease (PKD1) is highly variable. Clinical data was analyzed from 324 mutation-characterized PKD1 patients (80 families) to document factors associated with the renal outcome. The mean age to end-stage renal disease (ESRD) was 54 yr, with no significant difference between men and women and no association with the angiotensin-converting enzyme polymorphism. Considerable intrafamilial variability was observed, reflecting the influences of genetic modifiers and environmental factors. However, significant differences in outcome were also found among families, with rare examples of unusually late-onset PKD1. Possible phenotype/genotype correlations were evaluated by estimating the effects of covariants on the time to ESRD using proportional hazards models. In the total population, the location of the mutation (in relation to the median position; nucleotide 7812), but not the type, was associated with the age at onset of ESRD. Patients with mutations in the 5' region had significantly more severe disease than the 3' group; median time to ESRD was 53 and 56 yr, respectively (P = 0.025), with less than half the chance of adequate renal function at 60 yr (18.9% and 39.7%, respectively). This study has shown that the position of the PKD1 mutation is significantly associated with earlier ESRD and questions whether PKD1 mutations simply inactivate all products of the gene.     

Influence of ACE (I/D) and G460W polymorphism of alpha-adducin in autosomal dominant polycystic kidney disease.

BACKGROUND: The deleterious effect of the DD genotype of ACE in autosomal dominant polycystic kidney disease (ADPKD) remains controversial. Small sample size, population admixture and lack of consideration of parameters modulating the effects of ACE genotype, such as gender or alpha-adducin (ADD) genotype, might explain the discrepancy. METHODS: We investigated the effect of ACE (I/D) polymorphism on the age at end-stage renal disease (ESRD) in a homogeneous population of 191 ADPKD patients, according to gender and genotype for the G460W polymorphism of ADD. Cumulative renal survival was assessed in 276 patients from the same families. RESULTS: Though no effect was detected in the whole population, analysis of the male subset (n = 97) showed that patients harbouring the DD genotype of ACE had a 5-year lower mean age at ESRD than DI + II patients [47.8 +/- 1.8 (n = 31) vs 52.8 +/- 1.1 (n = 66), respectively] (P = 0.02). Furthermore, cumulative renal survival was lower in the corresponding pedigrees [47 +/- 1 years, 95% confidence interval (CI) 45-49, vs 51 +/- 1 years, 95% CI 48-54]. The G460W polymorphism of ADD had no effect on the age at ESRD and cumulative renal survival, either alone or in combination with the ACE (I/D) polymorphism. CONCLUSIONS: In this large series of ADPKD patients, we found no effect of the ACE (I/D) polymorphism on the age at ESRD, either alone or in combination with the G460W polymorphism of ADD. However, a deleterious effect of the DD genotype of ACE on renal disease progression was observed in ADPKD males.     

Family history of end-stage renal disease among hemodialyzed patients in Poland

BACKGROUND: In previous reports of end-stage renal disease (ESRD) patients, family history of ESRD was associated with race, younger age, higher education levels and ESRD etiology. This study aimed to analyze how often Polish caucasian dialysis patients reported relatives with ESRD, and to evaluate which risk factors are associated with family history of ESRD. METHODS: 4808 ESRD patients provided data about renal disease etiology, diabetes and hypertensive status of first- and second-degree relatives, socioeconomic status and education level. RESULTS: Reported ESRD etiologies were: chronic glomerular disease, 19.4 %; diabetic nephropathy, 11.3%; interstitial nephritris, 11.2%; hypertension, 7.8%; polycystic kidney disease (PKD), 7.1%; other or no response, 40.0%. Positive ESRD family history was reported by 745 patients (15.5%); positive history of diabetes, 932 (19.4%); hypertension, 1904 (39%). Positive ESRD family history according to kidney disease etiology was: PKD, 53.1%; glomerulonephritis, 12%; diabetic nephropathy, 11.9%; hypertension, 11.8%; interstitial nephritis, 10.8%. PKD as ESRD etiology (odds ratio (OR) 8.06, 95% confidence interval (CI) 6.35-10.23, p < 0.0001), positive family history of diabetes (OR 1.64, 95% CI 1.34-1.99, p < 0.0001) and positive history of hypertension (OR 1.64, 95% CI 1.39-1.95, p < 0.0001), were independently associated with positive ESRD history. Patients with later ESRD onset had a less frequent positive ESRD family history: for ESRD < 45 yrs, 16% (OR 1.0); 45-64 yrs, 14.4% (OR 0.83, 95% CI 0.70-0.99); > or = 65 yrs, 9.2 % (OR 0.5, 95% CI 0.35-0.72). CONCLUSIONS: Results of our study strongly support the contention that familial predisposition contributes to ESRD development.     

Epidermal growth factor receptor polymorphism and autosomal dominant polycystic kidney disease

BACKGROUND: The clinical variability in the rate of progression of autosomal dominant polycystic kidney disease (ADPKD) has been attributed to genetic heterogeneity, though environmental factors and modifying genes very likely play an important role as well. We examined the association between clinical outcome, defined by age at onset of end-stage renal disease (ESRD) in 46 ADPKD patients, and a polymorphism in the epidermal growth factor receptor (EGFR) gene, a candidate modifying gene. EGFR is a key element in renal tubular proliferation. METHODS: This study comprised 46 unrelated patients with ADPKD and ESRD, and 58 healthy controls. The patients had prevalently PKD 1 mutations. The EGFR microsatellite polymorphism was genotyped according to Gebhardt et al (11). RESULTS: The allele frequencies of the EGFR polymorphism were different in the ADPKD sample and the control population (G2=17.19; P=0.009). In particular, the frequencies of the 122 and 118bp length alleles had a different distribution (P=0.010 and P=0.047 respectively). Patients with the 122bp length polymorphism had ESRD at an earlier age,but this finding was not statistically significant. CONCLUSIONS: These findings suggest an association between the EGFR microsatellite polymorphism and ADPKD. However, it is difficult to establish which alleles are protective and which harmful. A larger, multicenter study may help clarify these results and is also required to replicate our preliminary finding of an association between ADPKD and the EGFR polymorphism.     

PKD2 mutations in a Czech population with autosomal dominant polycystic kidney disease.

BACKGROUND: Autosomal dominant polycystic kidney disease (ADPKD) is genetically heterogeneous and caused by mutations in at least three different loci. Based on linkage analysis, mutations in the PKD2 gene are responsible for approximately 15% of the cases. PKD2-linked ADPKD is supposed to be a milder form of the disease, its mean age of end-stage renal failure (ESRF) approximately 20 years later than PKD1. METHODS: We screened all coding sequences of the PKD2 gene in 115 Czech patients. From dialysis centres in the Czech Republic and from the Department of Nephrology of the General Hospital in Prague, we selected 52 patients (29 males, 23 females), who reached ESRF after the age of 63, and 10 patients (three males, seven females) who were not on renal replacement therapy at that age. The age of 63 was used as the cut-off because it is between the recently published ages of onset of ESRF for PKD1 and PKD2. From PKD families we also selected 53 patients (26 males, 27 females) who could be linked to either the PKD1 or PKD2 genes by linkage analysis. An affected member from each family was analysed by heteroduplex analysis (HA) for all 15 coding regions. Samples exhibiting shifted bands on gels were sequenced. RESULTS: We detected 22 mutations (six new mutations)-14 mutations in 62 patients (23%) with mild clinical manifestations, eight in 53 families (15%) with possible linkage to both PKD genes. As the detection rate of HA is approximately 70-80%, we estimate the prevalence of PKD2 cases in the Czech ADPKD population to be 18-20%. We identified nonsense mutations in eight patients (36.5%), frameshifting mutations in 12 patients (54.5%) and missense mutations in two patients (9%). CONCLUSION: In this study in the Czech population we identified 22 mutations (six of which were new mutations). The prevalence of PKD2 cases was 18-20% and the mean age of ESRF was 68.3 years. An at-least weak hot spot in exon 1 of the PKD2 gene was found.     

The PROPKD Score: A New Algorithm to Predict Renal Survival in Autosomal Dominant Polycystic Kidney Disease

The course of autosomal dominant polycystic kidney disease (ADPKD) varies among individuals, with some reaching ESRD before 40 years of age and others never requiring RRT. In this study, we developed a prognostic model to predict renal outcomes in patients with ADPKD on the basis of genetic and clinical data. We conducted a cross-sectional study of 1341 patients from the Genkyst cohort and evaluated the influence of clinical and genetic factors on renal survival. Multivariate survival analysis identified four variables that were significantly associated with age at ESRD onset, and a scoring system from 0 to 9 was developed as follows: being male: 1 point; hypertension before 35 years of age: 2 points; first urologic event before 35 years of age: 2 points; PKD2 mutation: 0 points; nontruncating PKD1 mutation: 2 points; and truncating PKD1 mutation: 4 points. Three risk categories were subsequently defined as low risk (0–3 points), intermediate risk (4–6 points), and high risk (7–9 points) of progression to ESRD, with corresponding median ages for ESRD onset of 70.6, 56.9, and 49 years, respectively. Whereas a score ≤3 eliminates evolution to ESRD before 60 years of age with a negative predictive value of 81.4%, a score >6 forecasts ESRD onset before 60 years of age with a positive predictive value of 90.9%. This new prognostic score accurately predicts renal outcomes in patients with ADPKD and may enable the personalization of therapeutic management of ADPKD.     

Anticipation of end stage renal disease in patients with autosomal dominant polycystic kidney disease in successive generations.

Autosomal dominant polycystic kidney disease is a disorder, which is inherited in 50% of offspring, irrelevant the sex and it has a variable clinical expressivity. Initially it was noticed that the clinical expression was interfamilial, but some studies found out that it was different. The aim of this study was to evaluate the age of onset of end-stage renal disease (ESRD) in affected parents in comparison with their offspring in successive generations. We studied 60 families of patients with autosomal dominant polycystic kidney disease (ADPKD). The diagnosis was done by echo criteria and we included only the patients for whom we knew precisely the onset of ESRD (affected parent and offspring), the sex of the parent who suffered from the disease, and offspring. We found out that the ESRD in ADPKD appears at the same age in affected parents and offspring (49,3 +/- 7,9 Vs 51,8 +/- 9,2, p = NS) irrelevant of the sex of the offspring. Patients with paternal inheritance (n = 38) were diagnosed to have ESRD earlier than their affected parents (47,9 +/- 8,3 Vs 52,2 +/- 9,2 p < 0,05), but patients with maternal inheritance had no difference (n = 22) (51,9 +/- 6,8 Vs 51,2 +/- 9,4, p = NS). In all the patients (60 couples) the survival rate was the same between affected parents and offspring (p = NS, Kaplan-Meier test), but significant differences were noticed between offspring with paternal inheritance in comparison with their parents (p < 0,05). In conclusion, we have detected that the onset of ESRD between patients with ADPKD in successive generations: a) Occurs in offspring as in their ancestors, b) anticipation was observed in 55% of couples, c) the sex of offspring does not have any relation with the renal death and d) the ESRD in patients with paternal inheritance occurs earlier in offspring than in their ancestors but not with maternal.     

Progressive loss of renal function is an age-dependent heritable trait in type 1 autosomal dominant polycystic kidney disease

Significant intrafamilial phenotypic variability is well documented in autosomal dominant polycystic kidney disease (ADPKD) and suggests a modifier effect. In this study, variance components analysis was performed to estimate the contribution of genetic factors for within-family renal disease variability in 406 patients from 66 type 1 ADPKD families. Overall, 39% of the study patients had ESRD at their last follow-up, and their renal survival did not differ by gender (P = 0.35, log-rank test). Because their frequency plot of creatinine clearance (Ccr) assumed a bimodal distribution with a marked kurtosis that was not improved by transformations, the study cohort was decomposed into two separate groups (non-ESRD [n = 247] and ESRD [n = 159]) in which the Ccr plots were normally distributed. The heritability (h(2)) of Ccr and age at ESRD (age(ESRD)) and the genetic correlations between these measures and their covariates were estimated. In patients without ESRD, a significant heritability was found for Ccr (h(2) = 0.42; P = 0.0015) after adjusting for age (P = 0.0001), systolic BP (P = 0.0006), and treatment with angiotensin-converting enzyme inhibitor/angiotensin receptor blocker (P = 0.00001). Birth year, gender, BMI, diastolic and mean BP, and pack-years of cigarette smoking did not significantly influence the heritability of this trait. In patients with ESRD, age(ESRD) provides a better measure than Ccr, which was very narrowly distributed. A significant heritability was found for age(ESRD) (h(2) = 0.78; P = 0.00009) in these latter patients. None of the above covariates influenced the heritability of this trait. It is concluded that a significant modifier gene effect influences the progression of renal disease in type 1 ADPKD.     

Lower progression rate of end-stage renal disease in patients with peripheral arterial disease using statins or Angiotensin-converting enzyme inhibitors

Patients with peripheral arterial disease (PAD) are at increased risk for ESRD and cardiovascular events. The primary objective was to assess the association between ankle-brachial index (ABI) values and renal outcome. The secondary objective was to evaluate whether statins and angiotensin-converting enzyme inhibitors (ACEI) are associated with improved renal and cardiovascular outcome in patients with PAD. In a prospective observational cohort study of 1940 consecutive patients with PAD, ABI was measured and chronic statin and ACEI therapy was noted at baseline. Serial creatinine concentrations were obtained at baseline, 6 mo, and every year after enrollment. End points were ESRD, all-cause mortality, and cardiac events during a median follow-up period of 8 yr. Baseline estimated GFR <60 ml/min per 1.73 m(2) was assessed in 27% of patients. ESRD, all-cause mortality, and cardiac events occurred in 10, 46, and 31% of patients, respectively. In multivariate analysis, a lower baseline ABI was significantly associated with a higher progression rate of ESRD (hazard ratio [HR] per 0.10 decrease 1.34; 95% confidence interval [CI] 1.21 to 1.49). Chronic use of statins and ACEI were significantly associated with lower ESRD (HR 0.41 [95% CI 0.28 to 0.63] and 0.74 [95% CI 0.54 to 0.98], respectively), mortality (HR 0.66; [95% CI 0.55 to 0.82] and 0.84 [95% CI 78 to 0.95], respectively), and cardiac events (HR 0.71 [95% CI 0.56 to 0.91] and 0.81 [95% CI 0.68 to 0.96], respectively). In patients with PAD, low ABI values independently predict the onset of ESRD. Less progression toward ESRD and improved cardiovascular outcome was observed among patients who were on long-term statins and ACEI.     

Genotype-phenotype correlations in autosomal dominant and autosomal recessive polycystic kidney disease

The phenotypes that are associated with the common forms of polycystic kidney disease (PKD)--autosomal dominant (ADPKD) and autosomal recessive (ARPKD)--are highly variable in penetrance. This is in terms of severity of renal disease, which can range from neonatal death to adequate function into old age, characteristics of the liver disease, and other extrarenal manifestations in ADPKD. Influences of the germline mutation are at the genic and allelic levels, but intrafamilial variability indicates that genetic background and environmental factors are also key. In ADPKD, the gene involved, PKD1 or PKD2, is a major factor, with ESRD occurring 20 yr later in PKD2. Mutation position may also be significant, especially in terms of the likelihood of vascular events, with 5' mutations most detrimental. Variance component analysis in ADPKD populations indicates that genetic modifiers are important, but few such factors (beyond co-inheritance of a TSC2 mutation) have been identified. Hormonal influences, especially associated with more severe liver disease in female individuals, indicate a role for nongenetic factors. In ARPKD, the combination of mutations is critical to the phenotypic outcome. Patients with two truncating mutations have a lethal phenotype, whereas the presence of at least one missense change can be compatible with life, indicating that many missense changes are hypomorphic alleles that generate partially functional protein. Clues from animal models and other forms of PKD highlight potential modifiers. The information that is now available on both genes is of considerable prognostic value with the prospects from the ongoing genetic revolution that additional risk factors will be revealed.     

ANTICIPATION OF END STAGE RENAL DISEASE IN PATIENTS WITH AUTOSOMAL DOMINANT POLYCYSTIC KIDNEY DISEASE IN SUCCESSIVE GENERATIONS

Autosomal dominant polycystic kidney disease is a disorder, which is inherited in 50% of offspring, irrelevant the sex and it has a variable clinical expressivity. Initially it was noticed that the clinical expression was interfamilial, but some studies found out that it was different. The aim of this study was to evaluate the age of onset of end-stage renal disease (ESRD) in affected parents in comparison with their offspring in successive generations. We studied 60 families of patients with autosomal dominant polycystic kidney disease (ADPKD). The diagnosis was done by echo criteria and we included only the patients for whom we knew precisely the onset of ESRD (affected parent and offspring), the sex of the parent who suffered from the disease, and offspring. We found out that the ESRD in ADPKD appears at the same age in affected parents and offspring (49,3 ± 7,9 Vs 51,8 ± 9,2, p = NS) irrelevant of the sex of the offspring. Patients with paternal inheritance (n = 38) were diagnosed to have ESRD earlier than their affected parents (47,9 ± 8,3 Vs 52,2 ± 9,2 p < 0,05), but patients with maternal inheritance had no difference (n = 22) (51,9 ± 6,8 Vs 51,2 ± 9,4, p = NS). In all the patients (60 couples) the survival rate was the same between affected parents and offspring (p = NS, Kaplan-Meier test), but significant differences were noticed between offspring with paternal inheritance in comparison with their parents (p < 0,05). In conclusion, we have detected that the onset of ESRD between patients with ADPKD in successive generations: a) Occurs in offspring as in their ancestors, b) anticipation was observed in 55% of couples, c) the sex of offspring does not have any relation with the renal death and d) the ESRD in patients with paternal inheritance occurs earlier in offspring than in their ancestors but not with maternal.     

Variable progression of autosomal dominant polycystic kidney disease: genetic and molecular counterparts

Autosomal dominant polycystic kidney disease (ADPKD) is characterized by a variable renal disease progression, which is observed both between (inter-familial variability) and within (intra-familial variability) affected families. Inter-familial variability is primarily due to genetic heterogeneity (PKD1 vs. PKD2), although an influence of the nature/type of mutation may also interfere (at least for PKD1). The major factor influencing intra-familial variability is probably the occurrence of a somatic mutation in the intact allele within epithelial tubular cells ("second hit"). Studies of variability in siblings and twins, as well as in animal models, suggest that modifier genes also influence renal disease progression in ADPKD, in addition to environmental or toxic factors. These modifier loci could affect cystogenesis and/or cyst progression, but also more general factors such as blood pressure regulation or endothelial function. Substantiating the role of modifier genes will require large familial studies but will probably offer new perspectives to slow renal disease progression in ADPKD.     

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/β-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.Autosomal dominant polycystic kidney disease ( ADPKD) is the most common monogenic kidney disease worldwide, affecting one in 500 to 1000 births.^1,2 It is characterized by focal development of renal cysts in an age-dependent manner. Typically, only a few renal cysts are clinically detectable during the first three decades of life; however, by the fifth decade, tens of thousands of renal cysts of different sizes can be found in most patients.³ Progressive cyst expansion with age leads to massive enlargement and distortion of the normal architecture of both kidneys and, ultimately, ESRD in most patients. ADPKD is also associated with an increased risk for cardiac valvular defects, colonic diverticulosis, hernias, and intracranial arterial aneurysms. Overall, ADPKD accounts for approximately 5% of ESRD in North America.²Mutations of PKD1 and PKD2 respectively account for approximately 85% and approximately 15% of linkage-characterized European families. Polycystin-1 (PC-1) and PC-2, the proteins encoded by PKD1 and PKD2, respectively, function as a macromolecular complex and regulate multiple signaling pathways to maintain the normal tubular structure and function.¹ Monoclonal expansion of individual epithelial cells that have undergone a somatic “second hit” mutation, resulting in biallelic inactivation of either PKD1 or PKD2, seems to provide a major mechanism for focal cyst initiation,⁴ possibly through the loss of polycystin-mediated mechanosensory function in the primary cilium.⁵ In addition, a large prospective, observational study indicated that renal cysts in ADPKD expand exponentially with increasing age, and patients with large polycystic kidneys are at higher risk for developing kidney failure⁶; however, the key factors that modulate renal disease progression in ADPKD remain incompletely understood.Renal disease severity in ADPKD is highly variable, with the age of onset of ESRD ranging from childhood to old age.^7–11 A strong genetic locus effect has been noted in ADPKD. Adjusted for age and gender, patients with PKD1 have larger kidneys and earlier onset at ESRD than patients with PKD2 (mean age at ESRD 53.4 versus 72.7 years, respectively).^8,9 By contrast, a weak allelic effect (based on the 5′ versus 3′ location of the germline mutations) on renal disease severity may be present for PKD1¹⁰ but not PKD2.¹¹ Marked intrafamilial variability in renal disease is well documented in ADPKD and suggests a strong modifier effect.^10–15 In an extreme example, large polycystic kidneys were present in utero in one of a pair of dizygotic twins affected with the same germline PKD1 mutation, whereas the kidneys of the co-twin remained normal at 5 years of age.¹² Several studies have quantified the role of genetic background in the phenotypic expression of ADPKD. In a comparison of monozygotic twins and siblings, greater variance in the age of onset of ESRD in the siblings supported a role for genetic modifiers.¹³ Two other studies of intrafamilial disease variability in PKD1 have estimated that genetic factors may account for 32 to 42% of the variance of creatinine clearance before ESRD and 43 to 78% of the variance in age at ESRD.^14,15 The magnitude of the modifier gene effect from these studies suggests that mapping such factors is feasible. Here, we report the results of an association study of modifier genes for PKD1 renal disease severity.     

Comprehensive PKD1 and PKD2 Mutation Analysis in Prenatal Autosomal Dominant Polycystic Kidney Disease

Prenatal forms of autosomal dominant polycystic kidney disease (ADPKD) are rare but can be recurrent in some families, suggesting a common genetic modifying background. Few patients have been reported carrying, in addition to the familial mutation, variation(s) in polycystic kidney disease 1 (PKD1) or HNF1 homeobox B (HNF1B), inherited from the unaffected parent, or biallelic polycystic kidney and hepatic disease 1 (PKHD1) mutations. To assess the frequency of additional variations in PKD1, PKD2, HNF1B, and PKHD1 associated with the familial PKD mutation in early ADPKD, these four genes were screened in 42 patients with early ADPKD in 41 families. Two patients were associated with de novo PKD1 mutations. Forty patients occurred in 39 families with known ADPKD and were associated with PKD1 mutation in 36 families and with PKD2 mutation in two families (no mutation identified in one family). Additional PKD variation(s) (inherited from the unaffected parent when tested) were identified in 15 of 42 patients (37.2%), whereas these variations were observed in 25 of 174 (14.4%, P=0.001) patients with adult ADPKD. No HNF1B variations or PKHD1 biallelic mutations were identified. These results suggest that, at least in some patients, the severity of the cystic disease is inversely correlated with the level of polycystin 1 function.     

Autosomal dominant polycystic kidney disease with minimal clinical expression unlinked to the PKD1 locus

Autosomal dominant polycystic kidney disease (ADPKD) is causedby mutations at the PKD1 locus in most families. This locushas been assigned to the short arm of chromosome 16 by linkageanalysis. It has been estimated that approximately 5% of familieshave a disease that does not map to this locus and most of thesefamilies have clinical features indistinguishable from the diseasecaused by PKD1 mutations. We report a large three-generationCaucasian family from Northern Ireland with ADPKD in whom allaffected individuals (age range 22–68) were normotensiveand only the two eldest had mild renal impairment. Linkage wasexcluded between the disease and both the alpha-globin genecomplex and the microsatellite marker D16S283. This family confirmsthat phenotypic heterogeneity exists between unlinked familiesand that certain non-PKD1 mutations cause mild disease expression.Many such individuals may therefore remain undetected and theincidence of families with ADPKD who have non-PKDl mutationsmay be greater than previously estimated.     

Dyslipidaemia and the progression of renal disease in chronic renal failure patients.

BACKGROUND: Dyslipidaemia is common in patients with chronic renal failure (CRF), and there is increasing evidence to support the role of dyslipidaemia as a contributing factor in the progression of chronic renal disease. However, few prospective studies have been carried out which address the possible relationship between dyslipidaemia and the rate of progression of renal disease in patients with renal failure. METHODS: Between January 1985 and December 1997, we prospectively assessed the risk of CRF progression to dialysis in a cohort of 138 patients. Forty CRF patients reached end-stage renal disease (ESRD) and had to start supportive therapy during the follow-up period [group ESRD(+)]. The remaining 98 CRF patients served as controls [group ESRD(-)]. Potential clinical and laboratory risk factors for more rapid CRF decline to dialysis, including lipid abnormalities and baseline creatinine clearance were determined at the start of the follow-up period. RESULTS: Several significant differences were found in univariate analysis between the two groups of CRF, ESRD(+) and ESRD(-), namely a shorter follow-up period, a lower level of baseline creatinine clearance, a faster rate of creatinine clearance decline, a higher level of serum triglycerides, fibrinogen, total homocyst(e)ine and proteinuria, and a lower level of serum high-density lipoprotein in the ESRD(+) group than in the ESRD(-) group. However, by multivariate Cox analysis proteinuria [relative risk (95% confidence interval) 1.32 (1.16-1.50) for each g/day P = 0.001], baseline creatinine clearance [0.53 (0.40-0.70) for each 10 ml/min, P = 0.001] and chronic interstitial nephritis and hypertensive nephrosclerosis [0.38 (0.17-0.84) for presence, P = 0.005] were the only significant risk factors for CRF progression to dialysis. Hypertriglyceridaemia and male gender were selected in the final model, but were of borderline significance. CONCLUSIONS: These results suggest a limited role for dyslipidaemia in the progression of chronic renal disease to dialysis in CRF patients, in contrast with the powerful influence of proteinuria, baseline creatinine clearance and nephropathy type in predicting this progression.     

Low birth weight is associated with earlier onset of end-stage renal disease in Danish patients with autosomal dominant polycystic kidney disease

Low-birth-weight individuals have a higher risk of hypertension and end-stage renal disease (ESRD). Here we investigated whether low birth weight was associated with earlier onset of ESRD in patients with autosomal dominant polycystic kidney disease (ADPKD). In collaboration with all Danish departments of nephrology, 307 of 357 patients with ADPKD and ESRD born and living in Denmark were recruited. We were able to analyze complete data of 284 patients obtained from both hospital medical files and midwife protocols in the Danish State Archives. Multivariable linear regression adjusted for birth weight, adult height, mean arterial pressure, gender, birth decade, and type of antihypertensive treatment showed that for every kilogram increase in birth weight, the age at onset of ESRD significantly increased by 1.7 years. Male gender and increased mean arterial pressure were both associated with earlier onset of ESRD. Patients treated with renin-angiotensin system blockade or calcium channel blockers during follow-up had significantly later onset of ESRD by 4.3 years and 2.1 years, respectively. Treatment with beta-blockade or a diuretic was not associated with the age at onset of ESRD. Thus, low birth weight may contribute to considerable phenotypic variability in the progression of renal disease between individuals with ADPKD.     

Progression of kidney disease varies between families with defects in the polycystic kidney disease type 1 gene in eastern Finland

OBJECTIVE: To characterize, for the first time, the phenotype and clinical course of autosomal dominant polycystic kidney disease (ADPKD) in Finnish patients. MATERIAL AND METHODS: All patients underwent an abdominal sonographic examination and most of those with ADPKD underwent magnetic resonance angiography of the head. Haplotype analysis was used to classify 20 ADPKD families into those with defects in either the polycystic kidney disease type 1 (PKD1) or polycystic kidney disease type 2 (PKD2) genes. Evaluation of the rate of progression of kidney disease in patients with ADPKD was based on creatinine values. RESULTS: Haplotype analysis showed that 16 families had defects in the PKD1 gene and one had defects in the PKD2 gene. Three families were excluded because of uninformative haplotypes. The final study population consisted of 79 unaffected family members, 109 patients with defects in the PKD1 gene and 10 with defects in the PKD2 gene. Higher prevalences of hepatic cysts (3% in healthy relatives, 60% in PKD1 patients and 90% in PKD2 patients; p < 0.001), subarachnoid hemorrhage or cerebral aneurysms (1%, 12% and 0%, respectively; p < 0.001), proteinuria (1%, 23% and 0%, respectively; p < 0.001) and hematuria (5%, 30% and 0%, respectively; p < 0.001) were found in PKD1 patients compared to the healthy relatives. PKD1 patients had a faster progression of kidney disease than PKD2 patients (p < 0.001). The progression of kidney disease varied substantially among the PKD1 families. CONCLUSION: The relative proportions of PKD1 and PKD2 patients and the phenotype of ADPKD were similar in our Finnish patients compared to previous studies in other populations. However, the progression of kidney disease differed substantially among PKD1 families, indicating a heterogeneic genetic background of PKD1 in Finnish patients.