Abstract
A number of inherited renal diseases present with renal cysts and often lead to end-stage renal disease. With recent advances in genetics, increasing number of genes and mutations have been associated with cystic renal diseases. Although genetic testing can provide a definite diagnosis, it is often reserved for equivocal cases or for ongoing investigational research. Therefore, imaging findings are essential in the routine diagnosis, follow-up, and detection of complications in patients with inherited cystic renal diseases. In this article, the most recent classification, genetic analysis, clinical presentations, and imaging findings of inherited cystic renal diseases will be discussed.
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Cystic renal diseases are heterogeneous in origin and pathogenesis, with renal cysts arising from the nephrons and collecting tubules. Abnormal cilium signaling in tubular epithelial cells is thought responsible for cyst formation in many inherited cystic renal diseases. Primary cilia are found on the surface of tubular epithelial cells and function as antennae sensing mechanical, osmotic and chemical stimuli, and signal through many pathways. These pathways control cell proliferation and differentiation, oriented cell division, and planar cell polarity, and are ultimately responsible for maintaining the normal tubular structure [1]. Disruption of these signaling pathways leads to ectatic or cystic nephrons and collecting ducts and cyst development [2].
Inherited cystic renal diseases include autosomal-dominant polycystic kidney disease (ADPKD), due to PKD1 and PKD2 mutations, and autosomal recessive polycystic kidney disease (ARPKD), due to PKHD1 mutations. Related diseases are autosomal-dominant tubulointerstitial kidney disease (ADTKD), which is a new terminology that includes various rare genetic diseases now classified by the gene involved (please refer to III. Autosomal-dominant tubulointerstitial kidney disease) (Table 1). Glomerulocystic kidney disease (GCKD), a genetically and phenotypically heterogeneous entity, often presents with renal cysts. Medullary sponge kidney (MSK), which is normally considered sporadic but may have an inherited component, can be associated with medullary cysts. Autosomal-dominant polycystic liver disease (ADPLD), a distinct genetic disorder with multiple hepatic cysts but no or few renal cysts, caused by mutations to the PRKCSH, SEC63, or LRP5 genes, may be confused with ADPKD. Some hereditary tumor syndromes, including tuberous sclerosis complex (TSC) and von Hippel–Lindau disease (VHL), are associated with an increased risk for renal cysts and benign or metastatic tumors. In this article, all of these inherited cystic renal diseases will be described with the responsible genes and proteins, as well as clinical and radiological presentations (summarized in Table 1).
In evaluating inherited cystic renal diseases, the radiologic findings, including the distribution and morphology of the renal cysts and other organ involvement, are essential for the diagnosis. The genetic testing can be valuable when the diagnosis is equivocal or a definite diagnosis is needed, but as with all testing is not informative in every case.
Autosomal-dominant polycystic disease (ADPKD)
Clinical and genetic description
ADPKD is the most common inherited renal disease with an estimated prevalence of 1 in 1000 live births and is inherited as an autosomal-dominant trait. Approximately 90 % of cases have a family history, but in 5–10 % of families, a de novo mutation is suspected. It is commonly associated with end-stage renal disease (ESRD) and accounts for ~5 % of ESRD population in the United States and ~10 % in the European Union. Although ADPKD is most commonly diagnosed in 4th and 5th decades of life, imaging studies can detect the disease in the majority of affected children [3].
Two genes have been identified: PKD1 gene is responsible in 85 % of cases and located on the short arm of chromosome 16 (16p13.3), and PKD2 gene comprises up to 15 % of cases and is located on the long arm of chromosome 4 (4q21.2). It is uncertain whether there is further genetic heterogeneity accounting for a small proportion of cases. Polycystin 1 (PC1) and 2 (PC2) are the proteins encoded by PKD1 and PKD2, respectively. PC1 is located predominantly in the primary cilia and plasma membrane, whereas PC2 is located predominantly in the endoplasmic reticulum (ER) as well as the primary cilia (Fig. 1) [4]. PC2 functions as a calcium channel and PC1 may regulate that channel.
Patients with PKD1 mutations have earlier onset of symptoms and earlier age of ESRD than those with PKD2 mutations. Patients with PKD1 and PKD2 mutations typically present clinically in their 30′s and 50′s, respectively, and reach ESRD in their 50’s and 70’s, respectively (Fig. 2). PKD2 patients develop fewer cysts but have a similar renal growth rate compared to PKD1 cases [5]. The prevalence and age of diagnosis of hypertension are lower and hematuria is less common in PKD2 [6]. Recently described allelic effects indicate that PKD1 patients with mutations predicted to truncate PC1 have more severe disease than non-truncating cases [7].
Marked intrafamilial and interfamilial phenotypic variability is seen in patients with ADPKD, which is not only partly related to the gene and mutation involved, but also associated with genetic background and environmental modifiers (dietary factors like salt intake and possibly hydration, smoking, etc.).
As the TSC2 gene locus is adjacent to PKD1 in 16p13.3, deletions affecting both genes may cause the TSC2/PKD1 contiguous gene syndrome. The affected patients (usually children) have severe cystic renal disease and angiomyolipomas in the kidney (Fig. 3) as well as skin, CNS, and other lesions characteristic of TSC.
Patients may present with hypertension (almost universally by the time of ESRD), flank or back pain (60 %), hematuria, proteinuria, and later ESRD. Decreased urinary concentration and reduced blood flow can be seen in early stage of the disease. Hypertension may be related to vascular functions of PC1 and PC2 as well as ischemic changes related to stretching and deformation of the renal vasculature with associated activation of the renin-angiotensin system [8]. Pain may be associated with hemorrhage, infection, or stone formation. Hemorrhage is very common with renal cysts and typically demonstrates T1 hyperintensity on MRI. Sometimes a hemorrhagic cyst can rupture into the renal sinus or perinephric space (Fig. 4). Hematuria may be related to cyst hemorrhage, infection, cystitis, or stones and is generally associated with a poor renal outcome. Renal stones are seen in ~20 % of cases, with the most common stone composition being uric acid and calcium oxalate [9]. Not infrequently these stones are difficult to differentiate from cyst wall calcifications. Dual energy CT can be helpful in differentiating uric acid from non-uric acid stones (Fig. 5).
Radiological description
In ADPKD, the bilateral kidneys are enlarged with multiple cysts. The renal cysts are typically bilateral and diffuse; however, a small number of patients (2–9 %) show atypical distributions including unilateral, segmental, asymmetric, and lopsided involvement (Fig. 6) [10]. Very rarely, when renovascular disease or urinary tract obstruction is superimposed, marked atrophy of the parenchyma may result in a small polycystic kidney (Table 2) [10]. It has been speculated but not proven that unilateral or markedly asymmetric polycystic kidneys are due to genetic mosaicism.
The consortium of imaging studies of polycystic kidney disease (CRISP) followed 241 patients with ADPKD with yearly MRI for three years and found that total and cyst volume increase exponentially in the affected patients [11]. The study also demonstrated that renal and cyst enlargement precedes and predicts the decline of renal function and that the kidney volume is the strongest predictor of renal functional decline (the larger the renal volume, the greater the loss of renal function). In addition, CRISP found that a decrease in renal blood flow preceded and was an independent predictor of the decline in glomerular filtration rate (GFR) [12].
The diagnosis of ADPKD is most often determined by imaging studies including US, CT, and MRI. US is most commonly used as an initial screening method in individuals with a positive family history. As patients with PKD2 mutation and non-truncating PKD1 mutations typically show less severe disease, the diagnostic criteria for PKD1 truncating mutations perform suboptimally for patients with in the other mutation groups. Revised criteria for at-risk individuals of unknown genotype (PKD1 or PKD2) include at least three (unilateral or bilateral) renal cysts for individuals of 15–39-year old, two or more cysts in each kidney for individuals of 40–59-year old, and four or more cysts in each kidney for individuals of 60-year old or older [13]. These criteria have been reported to have 100 % positive predictive values [13]. In contrast, fewer than two cysts in at-risk individuals of 40-year old or older is sufficient to exclude ADPKD with reported negative predictive value of 100 % [13]. CT and MRI are more sensitive in depicting renal cysts and can be helpful in equivocal cases. A recent study has shown that finding of fewer than five renal cysts by magnetic resonance imaging (MRI) is sufficient for disease exclusion [14]. Genetic testing can be performed when imaging findings are equivocal or a definitive diagnosis is needed. Using direct sequencing, mutation detection can be made in 85–95 % cases [5, 15].
Cyst infection is more common in females than males and often caused by Enterobacteriaceae. Contrast-enhanced CT or MRI demonstrates a fluid–fluid level, cyst wall thickening and enhancement, heterogeneous or increased density, or an air bubble. When findings are equivocal, these lesions can be further evaluated with 67Ga or 111In-labeled leukocyte scans or 18F-fluorodeoxyglucose (FDG) PET/CT (Fig. 7) [16]. The radiotracers of the leukocyte scans are excreted through the liver and spleen and may possibly obscure hepatic lesions, whereas FDG is excreted through the kidneys on PET/CT and may obscure renal lesions. For confirmation and treatment, US- or CT-guided cyst aspiration can be performed.
The incidence of renal cell carcinoma (RCC) generally does not appear higher than the general population [17], although some patient series did find a higher incidence in ADPKD [18]. Earlier age at presentation, frequent constitutional symptoms, and higher rates of sarcomatoid, bilateral, multicentric, and metastatic tumors have been reported [17]. In ADPKD patients, the solid appearance, contrast enhancement, heavy calcifications, restricted diffusion on MRI, tumor thrombosis, and lymphadenopathy can be helpful for the diagnosis of the rare cases of RCC (Fig. 8). The diagnosis, however, is often difficult due to innumerable renal cysts and associated anatomic distortion.
Cysts in other organs are commonly seen, most frequently in the liver. The hepatic cysts are seen in more than 90 % of cases in later stage. ADPLD can occur as a distinct genetic disorder, which presents with liver cysts without or with few renal cysts, with three genes (PRKCSH, SEC63, or LRP5) implicated. Hepatic cysts are more common and more severe in females, especially with a history of multiple pregnancy or prolonged use of oral contraceptives, likely related to an estrogen effect. Cysts are seen in other organs including the pancreas (5 %), arachnoid membrane (8 %), and seminal vesicles (40 %) (Fig. 9) [2]. Ovarian cysts are not associated with ADPKD.
Vascular complications associated with ADPKD include intracranial aneurysm (ICA), dolichoectasia, thoracic aortic and cervicocephalic artery dissection, and coronary artery aneurysm. Intracranial aneurysm occurs in 4–8 % of asymptomatic ADPKD patients, but the incidence is higher with a family history of nonruptured (10 % risk) or ruptured ICA (20 % risk) [19]. Rupture occurs in half of the patients with an ICA during their lifetime and causes significant mortality and morbidity. In ADPKD patients, ICA commonly involves the anterior circulation as in the general population and is often multiple. ICA rupture occurs at an earlier age than in the general population (39 vs. 51 years) [2]. Screening for ICA is indicated in an asymptomatic ADPKD patient with a family history of ICA, high-risk occupations and when needed for reassurance. Screening is also indicated in patients with a previous history of subarachnoid hemorrhage because they are at higher risk for de novo aneurysms. Screening is commonly done by MR angiography (which does not require contrast enhancement) or CT angiography (which requires contrast enhancement).
Mitral valvular prolapse, aortic root dilatation and valve insufficiency, colonic diverticulosis and diverticulitis, and bronchiectasis are more prevalent in ADPKD patients than in the general population.
CT or MRI can be used for renal volume measurement, depiction of other organ involvement, and diagnosis of complications such as hemorrhage, infection, stone formation, and associated malignancy. Renal volume measurement can be performed by simply multiplying three perpendicular measurements using an ellipsoid formula (π/6 × A × B × C) (Fig. 10A, B), or using planimetry (Fig. 10C) or stereology (Fig. 10D). Volumetric analysis of the renal cyst and renal volume is an important tool in evaluating cyst growth and predicting the renal functional changes.
Treatment is mainly focused on lowering morbidity and mortality from the complications of the disease, and includes control of hypertension and pain, antimicrobial therapy for infected cyst, stone removal or dissolution, cyst aspiration without or with sclerosis, cyst fenestration, nephrectomy, partial hepatectomy or segmentectomy, dialysis, and renal transplant. A few drugs have been shown to be of value for treatment of polycystic disease in animal models and/or clinical trials, including vasopressin V2 receptor antagonists such as tolvaptan and somatostatin analogs such as octreotide and lanreotide.
Autosomal recessive polycystic kidney disease (ARPKD)
Clinical and genetic description
ARPKD is inherited as an autosomal recessive trait and occurs with an incidence of 1 in 20,000. Siblings of an affected individual have a 25 % chance of being affected, whereas the carrier parents are unaffected. The PKHD1 gene is located on the short arm of chromosome 6 (6p21.1), and the protein product called fibrocystin or polyductin is a membrane-associated protein located in the primary cilia [19]. In ARPKD nephrogenesis is normal, but the collecting ducts grow excessively. Pathologically diffuse fusiform dilatation of the collecting ducts is characteristic of the classical, early presentation of the disease. In the patients who survive infancy, the kidneys become increasingly fibrotic over time with a relative reduction in volume and development of macroscopic cysts.
ARPKD affects both the kidneys and liver. Although clinical presentation of ARPKD is variable, severely affected patients are often identified in utero or at birth. Poor fetal renal output results in oligohydramnios and may be associated with pulmonary hypoplasia. Thirty percent of affected newborn die within the first week [20]. Less severely affected patients survive to later life. Severe renal damage with mild liver damage is often seen in the fetus and newborn, whereas more severe liver damage with milder renal damage is seen in later life. Hypertension is seen approximately 65–75 % of affected children [20], and chronic renal insufficiency and ESRD occur frequently.
Patients who survive the neonatal period often live to adulthood. Adeva et al. found in their study of 65 patients with ARPKD that approximately one-third of the patients presented at less than 1 year of life (n = 22), one-third at 1–20 years (n = 23), and the other one-third greater than 20 years (n = 20), and that 20-year survival after the diagnosis was 36, 80, and 88 %, in each group, respectively [21]. Hepatic manifestations include congenital hepatic fibrosis and Caroli syndrome associated with portal hypertension or ascending cholangitis.
Radiological description
The diagnosis is often made by a combination of a negative family history and radiologic findings, commonly using fetal or neonatal US or MRI (Figs. 11, 12). The typical neonatal presentation of the disease on US is bilateral enlargement, diffusely increased echogenicity and loss of corticomedullary differentiation (Fig. 11). This is likely attributed to increased acoustic interfaces produced by innumerable 1–2 mm collecting duct cysts. Although the characteristic imaging findings are suggestive of the diagnosis, the imaging findings are not specific and early-onset ADPKD or other cystic renal diseases should also be considered. Typically the kidneys in ARPKD patients are more echogenic than the liver and contain cysts smaller than 1 cm, whereas the ADPKD kidneys are less echogenic than the liver and renal cysts are larger than 1 cm [22]. Unlike the kidneys in ADPKD, the ARPKD kidneys often show a uniform sponge-like appearance with much smaller cysts related to dilated collecting ducts and retain a reniform shape (Fig. 12). With increasing age, the kidneys become smaller and macroscopic cysts may appear. As interstitial fibrosis progresses, US may demonstrate increased echogenicity and an irregular renal contour [21]. Nephrocalcinosis and/or small medullary stones are common and MSK can be seen [21]. In children or young adults, the imaging findings of hepatic fibrosis with evidence of portal hypertension (splenomegaly, varices, and ascites) and nonobstructive saccular dilatation of the intrahepatic ducts (Caroli syndrome) can be seen along with renal cystic abnormalities (predominantly collecting duct ectasia typically extending to the cortex) (Fig. 13). Molecular diagnostics by mutation screening for the PKHD1 gene can confirm the diagnosis and enable preimplantation and prenatal genetic screening in future pregnancies.
Treatment depends on the patient’s presentation. In early life, artificial ventilation or resuscitation may be needed, and other treatment includes unilateral or bilateral nephrectomies, hypertension or infection control, splenectomy, dialysis, and renal transplant.
Autosomal-dominant tubulointerstitial kidney disease (ADTKD) (also called medullary cystic kidney disease [MCKD])
Clinical and genetic description
The Kidney Disease: Improving Global Outcomes (KDIGO) proposed a new terminology for this group of diseases, autosomal-dominant tubulointerstitial kidney disease (ADTKD), which refers to nonglomerular autosomal-dominant kidney diseases characterized by progressive tubulointerstitial fibrosis and progression to ESRD. The previously called MCKD1 is now called as ADTKD-MUC1 and the previously called MCKD2 is now called as ADTKD-UMOD [23]. It also includes the previously called ‘familial juvenile hyperuricemic nephropathy type 2 (FJHN2)’ and ‘maturity-onset diabetes mellitus of the young type 5 (MODY5)’/‘renal cyst and diabetes syndrome (RCAD)’ [23], which are now called ADTKD-REN and ADTKD HNF1B, respectively, depending on the disease gene involved. ADTKD-MUC1 (MCKD1) has a defect in MUC1 gene that is located on chromosome 1q21 that encodes mucin-1, whereas ADTKD-UMOD (MCKD2) has a defect in the UMOD gene that is on chromosome 16p12 and encodes uromodulin/Tamm-Horsfall mucoprotein.
The clinical and laboratory findings as well as histological findings of ADTKD are largely nonspecific. Presentation in childhood is frequent in ADTKD-REN and ADTKD-HNF1B, but rare in ADTKD-UMOD. ADTKD-MUC1 often shows late-onset ESRD and never occurs in childhood. ADTKD-UMOD may present with early gout and hyperuricemia, and ADTKD-REN may express mild hypotension, hyperuricemia, and hyperkalemia.
Radiological description
Renal cysts are not pathognomonic in these entities and the medulla appears not to be a specific location for the occasionally observed cysts (Fig. 14) [23].
ADTKD-HNF1B is caused by mutation of HNF1B gene and produces maturity-onset diabetes mellitus of the young type 5 (MODY5), which is also called renal cyst and diabetes syndrome (RCAD). This is inherited as an autosomal-dominant trait; however, as 50 % of mutations occur de novo, a family history is often absent. The HNF1B protein, HNF-1β, regulates tissue-specific gene expression in the kidney, liver, pancreas, and other epithelial organs [24]. Mutations to this gene often result in renal malformations including: renal cystic abnormalities including renal cysts, oligomeganephronia, familial juvenile hyperuricemic nephropathy, renal agenesis/hypoplasia, multicystic dysplastic kidney, and rarely renal failure. Other features include pancreatic hypoplasia, urinary tract dilatation, genital tract malformation (vaginal aplasia, rudimentary uterus, bicornuate uterus, cryptorchidism, epididymal cysts, and atresia of the vas deferens), abnormal liver function, and hypomagnesemia. The diagnosis is suggested in patients with MODY and renal malformation (41 % likelihood of HNF1B mutation) [25] (Fig. 15). A scoring system using multiple parameters for the diagnosis has been proposed [26].
Nephronophthisis (NPHP)
NPHP is a common genetic inherited disease causing ESRD in children and adolescents and is inherited as autosomal recessive trait. NPHP is genetically heterogeneous with mutations in at least 19 distinct genes identified but mutations in these genes account for only about one-half of the cases. The NPHP gene products are expressed in the primary cilia or centrosomes. The most common molecular cause of NPHP is deletion or mutation of the NPHP1 gene, accounting for approximately 20 % of NPHP cases. The NPHP phenotype can be classified into three clinical forms, infantile, juvenile, and adolescent by the onset of ESRD (mean age of 1, 13, and 19 years, respectively) [20]. In the most common juvenile form, patients present with progressive tubular atrophy, small tubular cysts, and interstitial fibrosis leading to ESRD. The kidneys are characterized by hyperechogenicity and loss of corticomedullary differentiation on US and by a variable number of small cysts in the corticomedullary junction or medulla, best demonstrated by MRI but not always visible, and become progressively atrophic over time. The infantile form of NPHP combines features of NPHP with features of polycystic kidney disease (e.g., enlarged cystic kidneys).
NPHP can also be a feature of other-related autosomal recessive ciliopathies where it is associated with retinitis pigmentosa (Senior-Loken syndrome), cerebellar vermis aplasia, nystagmus and coloboma (Joubert syndrome), ocular motor apraxia (Cogan syndrome), liver fibrosis (Boichis syndrome), cone-shaped phalangeal epiphyses (Mainzer-Saldino syndrome), and short ribs (Jeune syndrome) [27]. Other syndromes included within the spectrum of NPHP-related ciliopathies include the perinatal lethal Meckel-Gruber syndrome (occipital encephalocele, polydactyly, microphthalmia, and liver fibrosis) and Bardet-Biedl syndrome (obesity, retinitis pigmentosa, polydactyly, and hypogenitalism).
Glomerulocystic kidney disease (GCKD)
Clinical and genetic description
GCKD are a heterogeneous group of diseases characterized by glomerular cysts that are often sporadic but occasionally familial (some reports suggest autosomal-dominant inheritance). Typically it occurs in children and young adult. Pathologically it is defined by a dilated Bowman space, greater than two times normal, and greater than 5 % of glomeruli involved. GCKD may be associated with other hereditary diseases such as early-onset ADPKD, late-onset ARPKD, ADTKD-UMOD, ADTKD-HNF1B, ADTKD-REN, TSC, or NPHP, or may be secondary to renal dysplasia, or ischemic GCKD.
Radiological description
The kidneys are slightly larger or normal in size. Imaging findings are variable in the fetus and neonate. In adults, multiple small renal cysts can be seen predominantly in the cortex, best seen on MRI (Fig. 16). Most patients progress to ESRD.
Medullary sponge kidney (MSK)
Clinical and genetic description
MSK is a benign condition characterized by tubular dilatation of the collecting ducts and cyst formation confined to the papillary portion of the medulla. It is associated with a high risk of developing urinary calcium stones. MSK is usually nonhereditary disease but autosomal-dominant inheritance in several families has been reported [28]. Most cases are asymptomatic but may be associated with microscopic or gross hematuria, stone formation, or infection. Incomplete distal renal tubular acidosis and/or hypercalciuria have been reported in up to 30–40 % of cases.
Radiological description
The kidneys are usually normal or slightly enlarged in size and the lesions are often bilateral (70 %). The dilated collecting ducts demonstrate typical paintbrush linear striations on excretory urography or CT urography, and may show clustered cysts in the papillary regions (Fig. 17). The affected patients usually have a good prognosis with normal life expectancy.
Renal cysts in hereditary tumor-related syndromes
Tuberous sclerosis complex (TSC)
Clinical and genetic description
TSC is an autosomal-dominant disease with an incidence of 1 in 6000. Two genes, TSC1 and TSC2, were identified on the chromosome 9q34 and 16p13 and encode for hamartin and tuberin, respectively. The disease is often sporadic with high rates of spontaneous mutation (65–75 %), particularly with TSC2. Disease caused by TSC1 mutation is often less severe than that by TSC2 mutation. The hamartin-tuberin complex antagonizes an insulin signaling pathway that plays an important role in regulating cell size and number, and organ size. Mutations in tuberin or hamartin prevent the formation of the tuberin-hamartin complexes and activate mTOR [2].
TSC is characterized by hamartomatous proliferative lesions in many organs, including the skin, brain, retina, heart, endocrine glands, GI tract, lung, and kidneys. The 2012 International Tuberous Sclerosis Complex Consensus Group published diagnostic criteria which include 11 major features and six minor features (Table 3). Definite diagnosis can be made using two major features or one major with more than two minor features, and possible diagnosis can be made using either one major or more than two minor features [29]. Mutation screening of the two disease genes can confirm or determine the diagnosis.
Approximately 50 % of TSC patients show cystic renal disease and 2 % have the TSC2/PKD1 contiguous gene syndrome. Renal involvement includes angiomyolipomas (70–80 %), cysts (47 %), oncocytomas, and clear cell RCCs (4 %). Angiomyolipomas are common in TSC (more frequent in TSC2), affect both genders (compared to female preponderance in general population), and are usually multiple and bilateral. Hemorrhage from angiomyolipoma is common, especially when the tumor reaches 4 cm in size. RCC in TSC is more common in female patients with a younger age, and often bilateral. It is usually clear cell type. Hypertension and renal failure may occur. Depending on the tumor size, nephron-sparing surgery, arterial embolization, ablation therapy, or bilateral nephrectomy can be performed. Clinical trials of mTOR inhibitors have been performed and found to be effective in managing tumor burden.
Radiological description
Diagnosis can be made using US, CT, or MRI by demonstrating fat within renal masses (Fig. 18). Non-fatty solid renal mass may represent fat-deficient angiomyolipoma, epithelioid angiomyolipoma, oncocytoma, or RCC.
von Hippel–Lindau syndrome (VHL)
Clinical and genetic description
VHL has an autosomal-dominant trait and occurs in 1 in 35,000. VHL is a tumor suppressor gene located on chromosome 3 (3p25-26). Inactivation of the VHL gene alleles causes uncontrolled cell growth, neoplastic transformation, and overexpression of VEGF in tumor cells and neoangiogenesis [30].
Cysts and benign and malignant tumors of various organs are seen, which include retinal hemangioma (50 %), endolymphatic sac tumors of the inner ear (10 %), cerebellar and spinal hemangioblastoma (21–72 %), pancreatic serous cystadenoma or neuroendocrine tumors, pheochromocytoma (7–20 %), clear cell RCC, epididymal, or broad ligament papillary cystadenoma.
Renal cysts (70 %) and pancreatic cysts (26 %) are common, whereas liver cysts are rare. RCC occurs in greater than 70 % during the lifetime and is the main cause of morbidity and mortality. RCCs occur early in life (mean age at 35 years) and are often multicentric and bilateral, with intracystic tumor nodules commonly seen.
VHL disease can be divided into type 1 (low risk for pheochromocytoma) and type 2 (high risk for pheochromocytoma) and type 2 disease is further divided into 2A (low risk for RCC), 2B (high risk for RCC), and 2C (pheochromocytoma only, no RCC or hemangioblastoma).
Radiological description
A diagnosis can be made by one characteristic tumor (hemangioblastoma, pheochromocytoma, or clear cell RCC) in the presence of a definitive family history, or two characteristic tumors (two or more CNS hemangioblastomas, or one hemangioblastoma and a visceral tumor) in the absence of a family history (Fig. 19). A molecular genetic diagnosis is helpful in evaluating VHL families, with the current mutation detection rate being almost 100 % [2].
Various imaging modalities including US, CT, MRI of the abdomen, MRI or CT of head and spine, PET or 131I-MIBG scans are utilized for screening, diagnosis, and follow-up of the patients. As numerous serial imaging studies are needed in these patients, avoidance of ionizing radiation whenever possible, and dose reduction when CT or radiography is needed, should be considered. Nephron-sparing surgery, ablation therapy, bilateral nephrectomy and transplantation, or medical treatment including mTOR inhibitors can be used for treatment.
Differential diagnoses and diagnostic algorithm
Various nonhereditary conditions can be associated with sporadic, acquired, or neoplastic cystic renal diseases, the most common are simple renal cysts. These are rare in children but the incidence increases with age.
When cysts are bilateral and multiple, differentiation from hereditary disease may be difficult. In this case, the distribution of renal cysts can be helpful (Fig. 20). If they are diffusely distributed in both kidneys, ADPKD, ARPKD, acquired cystic renal disease, and lithium nephrotoxicity should be considered. Presence or absence of family history, renal enlargement, and associated liver disease can be helpful for further differentiation (Fig. 20). If the renal cysts are seen predominantly in the medullary regions, medullary cystic renal disease (ADTKD) and MSK should be considered, and if they are predominantly in the cortex, glomerulocystic disease can be considered. Acquired cystic renal disease can be seen in patients with ESRD, usually on dialysis. Typically small cystic lesions are seen in small atrophic kidneys (Fig. 21) and are associated with an increased risk for RCC. Lithium nephrotoxicity often presents with diabetes insipidus and on imaging innumerable tiny cysts are seen in both the cortex and medulla of normal- or small-sized kidneys (Fig. 22).
When the renal cysts are associated with solid or fatty masses, VHL and TSC should be considered, and when there are associated with extrarenal manifestation including diabetes, GU, facial, or CNS anomalies, RCAD (ADTKD-HNF1B) or oro-facial-digital syndrome can be considered (Fig. 21).
When the renal cysts are unilateral or asymmetric, the differential diagnoses may include multicystic dysplastic kidney, and benign and malignant cystic renal tumors including multilocular cystic nephroma and cystic RCC as well as atypical ADPKD and localized cystic disease. Localized cystic disease of the kidney refers to non-familial, non-progressive cystic renal disease, which involves the kidney partly, segmentally, or unilaterally [31]. It is often difficult to differentiate from atypical ADPKD or cystic neoplasm. Family history and genetic testing can be helpful in differentiating from atypical ADPKD.
Conclusion
Various genetic diseases are associated with renal cysts. Imaging is essential in the diagnosis, follow-up, and depiction of complications of inherited cystic renal disease. The renal size, location and distribution of renal cysts, and associated extrarenal disease are important to obtain a differential diagnosis.
References
Phillips CA-KM (2013) Renal Cystic diseases. In: Lager DJAN (ed) Practical renal pathology. Philadelphia: Elsevier Saunders, pp 15–46
Torres VEGJ (2012) Cystic diseases of the kidney. In: Taal MWCG, Marsden PA, Skorecki K, Yu ASL, Brenner BM (eds) Brenner and rector’s the kidney, 9th edn. Philadelphia: Elsevier Saunders, pp 1626–1667
Bisceglia M, Galliani CA, Senger C, Stallone C, Sessa A (2006) Renal cystic diseases: a review. Adv Anat Pathol 13(1):26–56. doi:10.1097/01.pap.0000201831.77472.d3
Torres VE, Harris PC (2009) Autosomal dominant polycystic kidney disease: the last 3 years. Kidney Int 76(2):149–168. doi:10.1038/ki.2009.128
Harris PC, Bae KT, Rossetti S, et al. (2006) Cyst number but not the rate of cystic growth is associated with the mutated gene in autosomal dominant polycystic kidney disease. J Am Soc Nephrol 17(11):3013–3019. doi:10.1681/ASN.2006080835
Hateboer N, v Dijk MA, Bogdanova N, et al. (1999) Comparison of phenotypes of polycystic kidney disease types 1 and 2. Lancet 353(9147):103–107
Cornec-Le Gall E, Audrezet MP, Chen JM, et al. (2013) Type of PKD1 mutation influences renal outcome in ADPKD. J Am Soc Nephrol 24(6):1006–1013. doi:10.1681/ASN.2012070650
Gabow PA, Johnson AM, Kaehny WD, et al. (1990) Risk factors for the development of hepatic cysts in autosomal dominant polycystic kidney disease. Hepatology 11(6):1033–1037
Torres VE, Erickson SB, Smith LH, et al. (1988) The association of nephrolithiasis and autosomal dominant polycystic kidney disease. Am J Kidney Dis 11(4):318–325
Irazabal MV, Rangel LJ, Bergstralh EJ, et al. (2015) Imaging classification of autosomal dominant polycystic kidney disease: a simple model for selecting patients for clinical trials. J Am Soc Nephrol 26(1):160–172. doi:10.1681/ASN.2013101138
Grantham JJ, Torres VE, Chapman AB, et al. (2006) Volume progression in polycystic kidney disease. N Engl J Med 354(20):2122–2130. doi:10.1056/NEJMoa054341
Torres VE, King BF, Chapman AB, et al. (2007) Magnetic resonance measurements of renal blood flow and disease progression in autosomal dominant polycystic kidney disease. Clin J Am Soc Nephrol 2(1):112–120. doi:10.2215/CJN.00910306
Pei Y, Obaji J, Dupuis A, et al. (2009) Unified criteria for ultrasonographic diagnosis of ADPKD. J Am Soc Nephrol 20(1):205–212. doi:10.1681/ASN.2008050507
Pei Y, Hwang YH, Conklin J, et al. (2015) Imaging-based diagnosis of autosomal dominant polycystic kidney disease. J Am Soc Nephrol 26(3):746–753. doi:10.1681/ASN.2014030297
Tan YC, Blumenfeld J (1812) Rennert H (2011) Autosomal dominant polycystic kidney disease: genetics, mutations and microRNAs. Biochim Biophys Acta 10:1202–1212. doi:10.1016/j.bbadis.2011.03.002
Jouret F, Lhommel R, Devuyst O, et al. (2012) Diagnosis of cyst infection in patients with autosomal dominant polycystic kidney disease: attributes and limitations of the current modalities. Nephrol Dial Transplant 27(10):3746–3751. doi:10.1093/ndt/gfs352
Keith DS, Torres VE, King BF, Zincki H, Farrow GM (1994) Renal cell carcinoma in autosomal dominant polycystic kidney disease. J Am Soc Nephrol 4(9):1661–1669
Bernstein J, Evan AP, Gardner KD Jr (1987) Human cystic kidney diseases: epithelial hyperplasia in the pathogenesis of cysts and tumors. Pediatr Nephrol 1(3):393–396
Rizk DCA (2005) Polycystic and other cystic renal diseases. In: Greenberg ACA, Falk RJ, Coffman TM, Jennette JC (eds) Primer on kidney diseases. Philadelphia: Saunders, pp 356–362
Guay-Woodford LM, Desmond RA (2003) Autosomal recessive polycystic kidney disease: the clinical experience in North America. Pediatrics 111(5 Pt 1):1072–1080
Adeva M, El-Youssef M, Rossetti S, et al. (2006) Clinical and molecular characterization defines a broadened spectrum of autosomal recessive polycystic kidney disease (ARPKD). Medicine (Baltimore) 85(1):1–21. doi:10.1097/01.md.0000200165.90373.9a
Kaariainen H, Jaaskelainen J, Kivisaari L, Koskimies O, Norio R (1988) Dominant and recessive polycystic kidney disease in children: classification by intravenous pyelography, ultrasound, and computed tomography. Pediatr Radiol 18(1):45–50
Eckardt KU, Alper SL, Antignac C, et al. (2015) Autosomal dominant tubulointerstitial kidney disease: diagnosis, classification, and management–A KDIGO consensus report. Kidney Int 88(4):676–683. doi:10.1038/ki.2015.28
Igarashi P, Shao X, McNally BT, Hiesberger T (2005) Roles of HNF-1beta in kidney development and congenital cystic diseases. Kidney Int 68(5):1944–1947. doi:10.1111/j.1523-1755.2005.00625.x
Bockenhauer D, Jaureguiberry G (2015) HNF1B-associated clinical phenotypes: the kidney and beyond. Pediatr Nephrol . doi:10.1007/s00467-015-3142-2
Faguer S, Chassaing N, Bandin F, et al. (2014) The HNF1B score is a simple tool to select patients for HNF1B gene analysis. Kidney Int 86(5):1007–1015. doi:10.1038/ki.2014.202
Hildebrandt F, Attanasio M, Otto E (2009) Nephronophthisis: disease mechanisms of a ciliopathy. J Am Soc Nephrol 20(1):23–35. doi:10.1681/ASN.2008050456
Gambaro G, Feltrin GP, Lupo A, et al. (2006) Medullary sponge kidney (Lenarduzzi-Cacchi-Ricci disease): a Padua Medical School discovery in the 1930s. Kidney Int 69(4):663–670. doi:10.1038/sj.ki.5000035
Northrup H, Krueger DA (2013) Tuberous sclerosis complex diagnostic criteria update: recommendations of the 2012 Iinternational Tuberous Sclerosis Complex Consensus Conference. Pediatr Neurol 49(4):243–254. doi:10.1016/j.pediatrneurol.2013.08.001
Liapis HWP (2015) Cystic disease and developmental kidney defects. In: Jennette JCOJ, Silva FG, D’Agati VD (eds) Heptinstall’s pathology of the kidney. Philadelphia: Wolters Kluwer, pp 119–171
Ding Y, Chen L, Deng FM, et al. (2013) Localized cystic disease of the kidney: distinction from cystic neoplasms and hereditary polycystic diseases. Am J Surg Pathol 37(4):506–513. doi:10.1097/PAS.0b013e318271eff9
Torres VE, Harris PC, Pirson Y (2007) Autosomal dominant polycystic kidney disease. Lancet 369(9569):1287–1301. doi:10.1016/S0140-6736(07)60601-1
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Kim, B., King, B.F., Vrtiska, T.J. et al. Inherited renal cystic diseases. Abdom Radiol 41, 1035–1051 (2016). https://doi.org/10.1007/s00261-016-0754-3
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DOI: https://doi.org/10.1007/s00261-016-0754-3