Clinical characteristics.

The 17q12 recurrent deletion syndrome is characterized by variable combinations of the three following findings: structural or functional abnormalities of the kidney and urinary tract, maturity-onset diabetes of the young type 5 (MODY5), and neurodevelopmental or neuropsychiatric disorders (e.g., developmental delay, intellectual disability, autism spectrum disorder, schizophrenia, anxiety, and bipolar disorder). Using a method of data analysis that avoids ascertainment bias, the authors determined that multicystic kidneys and other structural and functional kidney anomalies occur in 85% to 90% of affected individuals, MODY5 in approximately 40%, and some degree of developmental delay or learning disability in approximately 50%. MODY5 is most often diagnosed before age 25 years (range: age 10-50 years).

Diagnosis/testing.

The diagnosis is established in a proband by detection of the 1.4-megabase (Mb) heterozygous recurrent deletion at chromosome 17q12 by chromosomal microarray testing or other genomic methods.

Management.

Treatment of manifestations: Treatment of kidney anomalies, neurodevelopmental and neuropsychiatric disorders, MODY5, genital tract abnormalities, liver abnormalities, eye abnormalities, congenital heart defects, seizures and sensorineural hearing loss should follow standard practice.

Surveillance: Kidneys and urinary tract: In the absence of known structural abnormalities, kidney and bladder ultrasound examination 12 months after establishing the diagnosis, then every 2-3 years in childhood/adolescence, then every 3-5 years in adulthood; presence of an abnormality may warrant more frequent monitoring. Annual monitoring of kidney function in individuals with abnormalities detected on kidney ultrasound examination; more frequent monitoring may be advised in those taking potentially nephrotoxic medications and/or known to have impaired kidney function. Routine monitoring of neurodevelopment through early childhood; full neuropsychological evaluation for children who experience difficulty with school. HbA1C annually to monitor for MODY5; self-monitoring by individuals and their families for clinical signs and symptoms of diabetes mellitus, such as polydipsia and polyuria. Consider reevaluation for uterine and vaginal abnormalities related to müllerian duct aplasia in pubertal females with primary amenorrhea. Consider annual hepatic function panel (or comprehensive metabolic panel), GGT, and lipid panel. Annual ophthalmologic evaluation during early childhood. Monitor those with seizures as clinically indicated. Hearing screening throughout childhood.

Agents/circumstances to avoid: Because kidney transplantation increases the risk for post-transplant diabetes mellitus, an immunosuppressive regimen that avoids tacrolimus and mammalian target of rapamycin (mTOR) inhibitors and reduces corticosteroid exposure may benefit those without preexisting diabetes mellitus. Nephrotoxic and hepatotoxic drugs should be avoided by individuals with kidney or liver abnormalities. For individuals with mental health conditions such as autism, schizophrenia, or bipolar disorder, careful consideration of antipsychotic agents that may lead to weight gain is recommended, as this potential increase has been associated with metabolic syndrome and the later development of diabetes mellitus, for which people with 17q12 deletions are at baseline increased risk. Likewise, the use of mood stabilizers that affect kidney function in the long term, such as lithium, should be carefully considered in the setting of potential underlying anatomic and functional abnormalities in people with 17q12 deletions.

Evaluation of relatives at risk: If one of the proband's parents has the 17q12 recurrent deletion, it is appropriate to test older and younger sibs of the proband and other relatives at risk in order to identify those who would benefit from close assessment/monitoring for evidence of genitourinary structural or functional defects, MODY5, and developmental delays / intellectual disability.

Genetic counseling.

The 17q12 recurrent deletion is inherited in an autosomal dominant manner, with approximately 75% of deletions occurring de novo and approximately 25% inherited from a parent. If the 17q12 recurrent deletion identified in the proband is not found in one of the parents, the risk to sibs is presumed to be lower than 1% (but slightly greater than that of the general population because of the theoretic possibility of parental germline mosaicism for the deletion). Offspring of an individual with the 17q12 recurrent deletion have a 50% chance of inheriting the deletion. Prenatal testing and preimplantation genetic testing using genomic testing that will detect the 17q12 recurrent deletion are possible.

Suggestive Findings

17q12 recurrent deletion syndrome should be suspected in individuals with any of the following clinical and laboratory findings.

Clinical findings

• Kidney abnormalities
  • Congenital abnormalities of the kidney and urinary tract (CAKUT), including the following:
    • Abnormalities on prenatal imaging including hyperechogenicity or poor corticomedullary differentiation
    • Abnormalities of kidney parenchyma including hypoplasia, dysplasia, multicystic dysplastic kidney (MCDK), or agenesis
    • Fusion anomalies (e.g., horseshoe kidney)
    • Collecting system abnormalities, including duplicated collecting systems, ureteropelvic junction obstruction, isolated hydronephrosis, or hydroureter
  • Tubulointerstitial disease, characterized by reduced urine concentrating ability with bland urinary sediment, absent-to-minimal albuminuria/proteinuria, hyperuricemia, hypomagnesemia, hypokalemia, and tubulointerstitial fibrosis on kidney histology. In some cases, hypomagnesemia is the initial and predominant symptom of kidney disease [van der Made et al 2015].
• Maturity-onset diabetes of the young (MODY), a type of monogenic diabetes resulting from beta-cell dysfunction
• Neurodevelopmental or neuropsychiatric disorders (e.g., developmental delay, intellectual disability, autism spectrum disorder, schizophrenia, anxiety, and bipolar disorder)
• Müllerian aplasia / Mayer-Rokitansky-Küster-Hauser syndrome in females

Note: The combination of kidney or urogenital anomalies with MODY has been referred to as renal cysts and diabetes (RCAD) syndrome.

Laboratory findings. The 17q12 recurrent deletion syndrome should be suspected in individuals with a deletion of HNF1B identified on gene-targeted deletion/duplication analysis (i.e., testing that detects deletion of HNF1B, but cannot reliably detect the diagnostic recurrent 17q12 deletion), as virtually all whole-gene deletions have been found to be the 17q12 recurrent deletion [Laffargue et al 2015].

Note that identification of an intragenic HNF1B pathogenic variant on sequence analysis establishes the diagnosis of an HNF1B-related disorder (see Genetically Related Disorders) and excludes the diagnosis of the 17q12 recurrent deletion syndrome.

Establishing the Diagnosis

The diagnosis of the 17q12 recurrent deletion syndrome is established in a proband by detection of the 1.4-Mb heterozygous recurrent deletion at chromosome 17q12 (see Table 1 and Molecular Genetics).

For this GeneReview, the 17q12 recurrent deletion is defined as the presence of a recurrent 1.4-Mb deletion at the approximate position of 36458167-37854616 in the reference genome (NCBI Build GRCh38/hg38).

ISCN nomenclature for this deletion is: seq[GRCh37] del(17)(q12) chr17:g. 36,458,167-37,854,616del. Note: Since this deletion is recurrent and mediated by segmental duplications, the unique genetic sequence that is deleted is the same in all individuals with the syndrome; however, the reported size of the deletion may: (1) be larger if adjacent segmental duplications are included in the size and (2) vary based on the design of the microarray used to detect it.

For information on the 15 known genes in the 17q12 region see Molecular Genetics.

Genomic testing methods that determine the copy number of sequences can include chromosomal microarray (CMA), exome sequencing with CNV calling, genome sequencing, or targeted deletion analysis. Note: The 17q12 recurrent deletion cannot be identified by routine analysis of G-banded chromosomes or other conventional cytogenetic banding techniques.

CMA using oligonucleotide or SNP arrays can detect the recurrent deletion in a proband. The ability to size the deletion depends on the type of microarray used and the density of probes in the 17q12 region.

Note: (1) Most individuals with the 17q12 recurrent deletion are identified by CMA performed in the context of evaluation for developmental delay, intellectual disability, or autism spectrum disorder. (2) Prior to 2007, many CMA platforms did not include coverage for this region and thus may not have detected this deletion.

Exome and genome sequencing analyses are next-generation sequencing technologies that generate DNA sequence either for all coding regions (exome) or the entire genome. Copy number variant-calling algorithms need to be utilized to detect the 17q12 recurrent deletion.

Targeted deletion analysis. FISH analysis, quantitative PCR (qPCR), multiplex ligation-dependent probe amplification (MLPA), or other targeted quantitative methods may be used to test relatives of a proband who is known to have the 17q12 recurrent deletion. Virtually all whole-gene deletions of HNF1B identified by gene-targeted deletion/duplication analysis have been shown to include the entire 17q12 recurrent deletion region [Laffargue et al 2015], which can be confirmed using CMA.

Note: (1) Targeted deletion testing is not appropriate for an individual in whom the 17q12 recurrent deletion was not detected by CMA designed to target this region. (2) It is not possible to size the deletion routinely by use of targeted methods.

Evaluating at-risk relatives. FISH, qPCR, or other quantitative methods of targeted deletion analysis can be used to identify the 17q12 recurrent deletion in at-risk relatives of the proband. Testing of parental samples is important in determining recurrence risk (see Genetic Counseling).

Clinical Description

The 17q12 recurrent deletion syndrome is characterized by variable combinations of the following three most common findings: kidney abnormalities including congenital abnormalities of the kidney and urinary tract (CAKUT) and tubulointerstitial disease, maturity-onset diabetes of the young (MODY), and neurodevelopmental/neuropsychiatric disorders (e.g., developmental delay, intellectual disability, autism spectrum disorder, schizophrenia, anxiety, and bipolar disorder).

To calculate the frequency rates for these features reported in 17q12 recurrent deletion syndrome, the authors reviewed phenotypic information for 282 individuals on whom sufficiently detailed phenotypic information was reported in 42 studies (Table 2) using the following criteria:

• To minimize ascertainment bias, studies involving disease-specific cohorts were not included in the prevalence calculations of that particular phenotypic manifestation (e.g., kidney anomalies).
• Individuals with HNF1B pathogenic sequence variants were not included; however, individuals with whole-gene HNF1B deletions were included, as virtually all whole-gene deletions have been found to be the 17q12 recurrent deletion [Laffargue et al 2015].

Intrafamilial Variability

While the recurrent 17q12 deletion most often occurs de novo, there have been several reports of familial inheritance [Moreno-De-Luca et al 2010, George et al 2012, Quintero-Rivera et al 2014, Dotto et al 2019, Okorn et al 2019, Kołbuc et al 2020]. Although the size of the deletion did not differ between parents and children in these reports, significant variability in clinical presentation has been reported both between and within phenotype categories.

Penetrance

The 17q12 recurrent deletion is highly pathogenic and penetrant, but expressivity is variable.

Because population-based studies with evaluation of all individuals with a 17q12 recurrent deletion are lacking, the exact penetrance is unknown both for individual phenotypic categories (e.g., kidney anomalies, neurodevelopmental disorders, diabetes) and for the presence of any associated pathologic phenotype (e.g., kidney anomaly OR neurodevelopmental disorder OR diabetes).

However, high pathogenicity and penetrance is supported by several lines of evidence:

• High rate of structural kidney anomalies among individuals who were not ascertained as part of kidney disease cohorts (130/148; 88%) (Table 2)
• Preliminary evidence suggesting a high rate of neurodevelopmental and neuropsychiatric disorders among individuals who were not ascertained as part of NDD/NPD cohorts (3/4; 75%) [Martin et al 2020]
• Very low frequency of the deletion in control populations (e.g., none in ~48,000 controls in one study [Moreno-De-Luca et al 2010])
• High de novo ratio (percentage of cases that are de novo) [Kirov et al 2014]

These studies suggest that penetrance is virtually 100%, with missing data and variable expressivity accounting for the very rare presence of the 17q12 deletion in control populations.

Nomenclature

In 1997, heterozygous pathogenic variants in HNF1B were described as a cause of MODY in one family [Horikawa et al 1997]; shortly thereafter the same family was found to have kidney involvement [Iwasaki et al 1998]. In 2001, the combination of congenital anomalies of the kidney and urinary tract and MODY5 became known as "renal cysts and diabetes (RCAD) syndrome" [Bingham et al 2001].

Prevalence

The reported prevalence of the 17q12 recurrent deletion in large populations not selected on the basis of disease ranges from 0.002% (1:50,000) to 0.007% (1:14,000) – 0.002% in healthy European volunteers (UK Biobank; n = ~421K), 0.004% in a US health care system-based population (DiscovEHR; n = ~90K), and 0.007% in a large Icelandic control sample (deCODE; n = ~101K) [Martin et al 2020]. A higher prevalence estimate of 0.025% (1:4,000) was described in a population-based pregnancy cohort study of 12,252 mother-father-newborn trios [Smajlagić et al 2021].

Among individuals undergoing clinical postnatal chromosomal microarray analysis, the prevalence of the 17q12 recurrent deletion is much higher: approximately 0.1% (1:1000) [Moreno-De-Luca et al 2010, Rosenfeld et al 2013, Kirov et al 2014, Rasmussen et al 2016]. The main indications for clinical CMA in these studies were neurodevelopmental disorders (global developmental delay, intellectual disability, ASD) and congenital malformations.

It may be useful to consider the estimated prevalence of the 17q12 recurrent deletion in certain clinical populations:

• Congenital anomalies of the kidney. 1.9% (~1:53); when considering CAKUT more broadly, 0.8% (~1:123) have 17q12 deletion [Verbitsky et al 2019].
• Chronic kidney disease. 0.03%-2.2% (~1:3000 - 1:46) [Lata et al 2018, Connaughton et al 2019, Groopman et al 2019]
• Neurodevelopmental disorders. 0.09% (~1:1,150) [Kirov et al 2014]
• Schizophrenia. 0.036% (~1:2,800) [Kirov et al 2014]
• Müllerian aplasia. 3%-6% (~1:33 - 1:17) [Nik-Zainal et al 2011, Williams et al 2017]. Among women with both uterine and kidney anomalies, 18% (~1:6) had a 17q12 deletion or pathogenic HNF1B sequence variant [Oram et al 2010].

Evaluations Following Initial Diagnosis

To establish the extent of disease and needs in an individual diagnosed with the 17q12 recurrent deletion syndrome, the evaluations summarized in Table 5 (if not performed as part of the evaluation that led to the diagnosis) are recommended.

Treatment of Manifestations

Treatment is symptomatic and depends on an individual's specific needs.

Surveillance

Agents/Circumstances to Avoid

Individuals with HNF1B-associated kidney disease (including the 17q12 recurrent deletion) who develop ESKD and require kidney transplantation are at increased risk for developing post-transplant diabetes mellitus; therefore, use of an immunosuppressive regimen that avoids tacrolimus and mammalian target of rapamycin (mTOR) inhibitors and reduces corticosteroid exposure may be beneficial, including for those who do not have preexisting diabetes [Zuber et al 2009, Faguer et al 2011, Clissold et al 2015].

Nephrotoxic drugs (e.g., NSAIDs) should be avoided by those with kidney abnormalities. Hepatotoxic medications and alcohol should be avoided by those with liver abnormalities.

For individuals with mental health conditions such as autism, schizophrenia, or bipolar disorder, the authors recommend careful consideration of antipsychotic agents that may lead to weight gain, as this potential increase has been associated with metabolic syndrome and the later development of diabetes mellitus, for which people with 17q12 deletions are at baseline increased risk. Likewise, the use of mood stabilizers that affect kidney function in the long term, such as lithium, should be carefully considered in the setting of potential underlying anatomic and functional abnormalities in people with 17q12 deletions. These recommedations stem from empirically grounded clinical reasoning based on the underlying phenotypes associated with 17q12 deletions, as large studies assessing the efficacy of these interventions have not yet been performed.

Evaluation of Relatives at Risk

If genomic testing detects the 17q12 recurrent deletion in one of the proband's parents, it is appropriate to clarify the genetic status of older and younger sibs of the proband and other relatives at risk in order to identify those who would benefit from close assessment/monitoring for evidence of kidney structural or functional defects, maturity-onset diabetes of the young, and developmental delays / intellectual disability.

See Genetic Counseling for issues related to testing of at-risk relatives for genetic counseling purposes.

Therapies Under Investigation

Search ClinicalTrials.gov in the US and EU Clinical Trials Register in Europe for access to information on clinical studies for a wide range of diseases and conditions. Note: There may not be clinical trials for this disorder.

Mode of Inheritance

The 17q12 recurrent deletion is inherited in an autosomal dominant manner.

Risk to Family Members

Parents of a proband

• Most studies examining the 17q12 recurrent deletion have not reported whether or not the parents were tested; therefore, inheritance status is often unknown or the data are limited. However, in 70 individuals with the deletion from 18 studies for which this information is available, the deletion was de novo in 51 (73%) and inherited in 19 (27%).
• Evaluation of the parents by genomic testing to determine if they have the 17q12 recurrent deletion present in the proband is recommended. Because features range in severity, it is possible for parents who are mildly affected to be unaware of any clinical manifestations (diabetes and kidney problems may not be evident until adulthood). See Clinical Characteristics, Intrafamilial Variability.

Sibs of a proband. The risk to the sibs of the proband depends on the genetic status of the parents:

• If the 17q12 recurrent deletion identified in the proband is not identified in a parent, the risk to sibs is slightly greater than that of the general population (though still <1%) because of the theoretic possibility of parental germline mosaicism for the deletion.
• If one of the parents has the 17q12 recurrent deletion, the risk to each sib of inheriting the deletion is 50%. However, it is not possible to reliably predict the full phenotypic expression in a sib who inherits the deletion because significant intrafamilial variability may be observed (see Clinical Characteristics, Intrafamilial Variability).

Offspring of a proband. Each child of an individual with the 17q12 recurrent deletion has a 50% chance of inheriting the deletion.

Other family members. The risk to other family members depends on the genetic status of the proband's parent: if a parent has the 17q12 recurrent deletion, the parent's family members may also have the deletion.

Related Genetic Counseling Issues

See Management, Evaluation of Relatives at Risk for information on evaluating at-risk relatives for the purpose of early diagnosis and treatment.

Family planning

• The optimal time for determination of genetic risk and discussion of the availability of prenatal/preimplantation genetic testing is before pregnancy.
• It is appropriate to offer genetic counseling (including discussion of potential risks to offspring and reproductive options) to young adults who are at risk of having a child with the 17q12 recurrent deletion syndrome.

Prenatal Testing and Preimplantation Genetic Testing

Pregnancies known to be at increased risk for the 17q12 recurrent deletion. Once the 17q12 recurrent deletion has been identified in an affected family member, prenatal and preimplantation genetic testing for 17q12 recurrent deletion syndrome are possible.

Prenatal testing or preimplantation genetic testing using genomic testing that will detect the 17q12 recurrent deletion may be offered when:

• A parent has the 17q12 recurrent deletion;
• Neither parent has the 17q12 recurrent deletion but the couple is concerned about a recurrence in subsequent pregnancies after having had a child with the 17q12 recurrent deletion based on the theoretic possibility of parental germline mosaicism or other predisposing genetic mechanisms (presumed to be ~1%).

Pregnancies not known to be at increased risk for the 17q12 recurrent deletion. Prenatal CMA performed in follow up to indications other than a positive family history (e.g., fetal kidney anomalies detected on ultrasound examination) may detect the 17q12 recurrent deletion [Hendrix et al 2012, Wapner et al 2012]. There is a high correlation between fetal hyperechogenic kidneys and the 17q12 deletion [Jing et al 2019, Wan et al 2019, Cai et al 2020] prompting several authors to recommend genetic testing for the 17q12 recurrent deletion when hyperechogenic kidneys of unknown cause are detected prenatally [Jones et al 2015, Jing et al 2019].

Note: Regardless of whether the pregnancy is known or not known to be at increased risk for the 17q12 recurrent deletion syndrome, prenatal test results cannot reliably predict the phenotype (see Clinical Characteristics, Intrafamilial Variability).

Differences in perspective may exist among medical professionals and within families regarding the use of prenatal testing. While most centers would consider use of prenatal testing to be a personal decision, discussion of these issues may be helpful.

Molecular Pathogenesis

The 17q12 deletion is recurrent, meaning that it involves the same unique genomic sequence. The 17q12 region is considered a hot spot for copy number variants, as it has specific molecular features (known as segmental duplications) that predispose to these events [Mefford et al 2007, Moreno-De-Luca et al 2010].

Deletion mechanism. The 17q12 genomic region involved in the recurrent 17q12 deletion is flanked on each side by segmental duplications, which are highly repetitive segments of genomic material. Since these segmental duplications have a high degree of homology to one another, they can misalign during meiosis and give rise to deletions and duplications of the intervening genomic interval. This process, called nonallelic homologous recombination, accounts for the absence of the same unique genomic region in individuals with 17q12 recurrent deletion [Sharp et al 2006, Moreno-De-Luca et al 2010].

Genes of interest in this region. Genes within the 17q12 recurrent deletion region include AATF, ACACA, C17orf78, DDX52, DHRS11, DUSP14, GGNBP2, HNF1B, LHX1, MRM1, MYO19, PIGW, SYNRG, TADA2A, and ZNHIT3.

Three genes are of particular interest with respect to phenotypes associated with the 17q12 recurrent deletion:

• HNF1B. HNF1B haploinsufficiency has been established as the cause of the kidney, urogenital, and endocrine abnormalities that occur as part of the 17q12 recurrent deletion syndrome. Heterozygous pathogenic sequence variants in HNF1B cause renal cysts and diabetes (RCAD) syndrome, which is characterized by the combination of congenital anomalies of the kidney and urinary tract (CAKUT) and maturity-onset diabetes of the young type 5 (MODY5) [Bingham et al 2001]. While other genes in the 17q12 recurrent deletion region likely account for most of the neurodevelopmental features associated with the syndrome, isolated sequence variants within HNF1B have also been associated with an increased risk for learning problems, albeit at a lesser frequency [Clissold et al 2016, Dubois-Laforgue et al 2017a, Laliève et al 2020]. Thus, more research is needed to define the role of HNF1B in the human brain.
• LHX1. Heterozygous LHX1 likely pathogenic variants have been identified in females with müllerian aplasia / Mayer-Rokitansky-Küster-Hauser syndrome, though inheritance information was not available [Ledig et al 2011, Ledig et al 2012, Sandbacka et al 2013]. Because of its role in neural development, LHX1 may also contribute to the neurodevelopmental manifestations observed in the 17q12 recurrent deletion syndrome [Moreno-De-Luca et al 2010, Nagamani et al 2010].
• ACACA encodes acetyl-CoA carboxylase 1, involved in lipogenesis in adipose tissue. There has been speculation that haploinsufficiency of ACACA may contribute to the leaner phenotype and decreased risk of diabetic glomerular disease in individuals with the 17q12 recurrent deletion compared to those with HNF1B sequence variants [Dubois-Laforgue et al 2017b].

Author Notes

Geisinger Autism & Developmental Medicine Institute 17q12 Project
120 Hamm Drive, Suite 2
Lewisburg, PA 17837
Phone: 570-522-9430
Fax: 570-522-9431
Website: 17q12 Project

Genomic Psychiatry Consultation Service & PRecISion Medicine in Autism (PRISMA) Project
Verrecchia Clinic for Children with Autism and Developmental Disabilities
Bradley Hospital
Phone: 401 432 1583|
Fax: 401 432 1506
Website: vivo.brown.edu/display/dmorenod

Acknowledgments

This work was funded in part by the National Institute for Mental Health of the National Institutes of Health under awards RO1MH074090 (to DHL and CLM), RO1MH107431 (to CLM), K23MH120376 (to DMD), and grants from the Simons Foundation (SFARI# 215355 to CLM and SFARI# 240413 to DHL). The authors would also like to thank all of the individuals and families with 17q12 deletions for their participation in these research studies.

Author History

Brenda Finucane, MS, LGC; Geisinger Health System (2016-2020)
David H Ledbetter, PhD, FACMG (2016-present)
Rebecca V Levy, BM BCh, MSc (2020-present)
Christa L Martin, PhD, FACMG (2016-present)
Marissa W Mitchel, MS, CCC-SLP (2016-present)
Daniel Moreno-De-Luca, MD, MSc (2016-present)
Scott M Myers, MD (2016-present)
Stefanie Turner, MS, CGC (2020-present)

Revision History

• 15 October 2020 (sw) Comprehensive update posted live
• 8 December 2016 (bp) Review posted live
• 10 August 2015 (mm) Original submission

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