采用多重连接探针扩增技术检测智力低下儿童的基因缺陷

目的 探讨原因不明智力低下儿童的发病与染色体亚端粒基因重组间的关系.方法 采用多重连接探针扩增(multiplex ligation-dependent probe amplification,MLPA)技术检测30名原因不明的综合征性智力低下患儿的染色体亚端粒区域.结果 检测到5例患儿存在染色体亚端粒的基因缺失或重复突变,分别为4p缺失,21q重复,10p重复、4p缺失,15p重复,3p重复、9p缺失.结论 不明原因智力低下儿童的发病与染色体亚端粒基因重组密切相关.MLPA技术可以作为一种高效、特异的方法对智能障碍儿童进行基因缺陷筛查.     

Multiplex ligation-dependent probe amplification to detect subtelomeric rearrangements in routine diagnostics

Subtelomeric rearrangements are believed to be responsible for 5-7% of idiopathic mental retardation cases. Due to the relative complexity and high cost of the screening methods used till now, only preselected patient populations including mostly the more severely affected cases have been screened. Recently, multiplex ligation-dependent probe amplification (MLPA) has been adapted for use in subtelomeric screening, and we have incorporated this technique into routine diagnostics of our laboratory. Since the evaluation of MLPA as a screening method, we tested 275 unselected patients with idiopathic mental retardation and detected 12 possible subtelomeric aberrations: a der(11)t(11;20)(qter;qter), a 19pter duplication, a der(18)t(18;10)(qter; pter), a 15qter deletion, a 8pter deletion, a 6qter deletion, a der(X)t(X;1)(pter;qter), a der(X)t(X;3)(pter;pter), a 5qter duplication, a 3pter deletion, and two 3qter duplications. The patients can be subdivided into two groups: the first containing de novo rearrangements that are likely related to the clinical presentation of the patient and the second including aberrations also present in one of the parents that may or may not be causative of the mental retardation. In our patient cohort, five (1.8%) subtelomeric rearrangements were de novo, three (1.1%) rearrangements were familial and suggestively disease causing, and four (1.5%) were possible polymorphisms. This high frequency of subtelomeric abnormalities detected in an unselected population warrants further investigation about the feasibility of routine screening for subtelomeric aberrations in mentally retarded patients.     

Subtelomeric rearrangements in the mentally retarded: a comparison of detection methods

In recent years, subtelomeric rearrangements, e.g., chromosome deletions or duplications too small to be detected by conventional cytogenetic analysis, have emerged as a significant cause of both idiopathic and familial mental retardation. As mental retardation is a common disorder, many patients need to be tested on a routine basis. In this review, we will discuss the different methods that have been applied in laboratories worldwide, including multiprobe fluorescence in situ hybridization (FISH), multiallelic marker analysis, multiplex amplifiable probe hybridization (MAPH), multiplex ligation-dependent probe amplification (MLPA), quantitative real-time PCR, comparative genomic hybridization (CGH), and multicolor FISH, including spectral karyotyping (SKY), subtelomeric combined binary ratio labeling FISH (S-COBRA FISH), multiplex FISH telomere integrity assay (M-TEL), telomeric multiplex FISH (TM-FISH), and primed in situ labeling (PRINS).     

Pure subtelomeric microduplications as a cause of mental retardation

Submicroscopic subtelomeric aberrations are a common cause of mental retardation (MR). New molecular techniques allow the identification of subtelomeric microduplications, but their frequency and significance are largely unknown. We determined the frequency of subtelomeric, pure microduplications in a cohort of 624 patients with MR and/or multiple congenital anomalies using multiplex ligation dependent probe amplification (MLPA) and delineated the identified microduplications using array based comparative genomic hybridization (array CGH). In 11 patients, MLPA revealed a subtelomeric duplication without a concurrent deletion. Additional fluorescence in situ hybridization studies and parental analyses showed that three had occurred de novo: one duplication 5q34qter (12.7 Mb), one duplication 9q34.13qter (7.2 Mb) and one duplication 9p24.2pter (4.1 Mb). Five microduplications (9p, 11q, 12q, 15q and 16p) appeared to be inherited from an unaffected parent, while in three cases (9p, 12p and 17p) the parents were not available for testing. Based on our findings and data from the literature, the three de novo duplications were the only ones likely to be disease-causing, leading to a frequency of pathogenic subtelomeric, pure microduplications of 0.5%. Our study shows that subtelomeric microduplications are an infrequent cause of MR and that additional clinical and family studies are required to assess their clinical significance.     

Interstitial 2.2 Mb deletion at 9q34 in a patient with mental retardation but without classical features of the 9q subtelomeric deletion syndrome

In a female patient with mild mental retardation an interstitial subtelomeric 9q34.3 deletion was identified by a multiplex ligation-dependent probe amplification (MLPA) based screen for subtelomeric abnormalities. Further characterization of the deletion by high-resolution tiling path array-based comparative genomic hybridization (array CGH) revealed a size of 2.2 Mb. The woman lacked the typical 9qter deletion phenotype characteristics, which is inline with the finding that both Eu-HMTase1 (EHMT) genes were present. However, she presented with mild mental retardation, some mild facial dysmorphisms and aplasia cutis. This is another example of an interstitial subtelomeric deletion, which underscores that further characterizing the precise nature of the deletion is of clinical importance. Moreover, it confirms the importance of the Eu-HMTase1 gene as the major causative factor of the classical 9qter syndrome phenotype.     

Array-based MLPA to detect recurrent copy number variations in patients with idiopathic mental retardation

Microdeletions, either subtelomeric or interstitial, are responsible for the mental handicap in approximately 10-20% of all patients. Currently, Multiplex Ligation-dependent Probe Amplification (MLPA) is widely used to detect these small aberrations in a routine fashion. Although cost-effective, the throughput is low and the degree of multiplexing is limited to maximally 40-50 probes. Therefore, we developed an array-based MLPA method, with probes identified by unique tag sequences, allowing the simultaneous analysis of 180 probes in a single experiment thereby covering all known mental retardation loci with at least two probes. We screened 120 patients with idiopathic mental retardation. In this group we detected 6 aberrations giving a detection rate of 5%, consistent with similar studies. In addition we tested 293 patients with mental retardation who were negative for fragile X syndrome and commercially available subtelomeric MLPA. We found seven causative rearrangements in this group (detection rate of 2.4%) thereby illustrating the value of including probes for interstitial microdeletion syndromes and additional probes in the telomeric regions in targeted screening sets for mental retardation. Array-based MLPA may thus be a good candidate to develop probe sets that rapidly detect copy number changes of disease associated loci in the human genome. This method may become a valuable tool in a routine diagnostic setting as it is a fast, user-friendly and relatively low-cost technique providing straightforward results requiring only 125 ng of genomic DNA.     

Application of a comprehensive subtelomere array in clinical diagnosis of mental retardation

In 2-8% of patients with mental retardation, small copy number changes in the subtelomeric region are thought to be the underlying cause. As detection of these genomic rearrangements is labour intensive using FISH, we constructed and validated a high-density BAC/PAC array covering the first 5 Mb of all subtelomeric regions and applied it in our routine screening of patients with idiopathic mental retardation for submicroscopic telomeric rearrangements. The present study shows the efficiency of this comprehensive subtelomere array in detecting terminal deletions and duplications but also small interstitial subtelomeric rearrangements, starting from small amounts of DNA. With our array, the size of the affected segments, at least those smaller than 5 Mb, can be determined simultaneously in the same experiment. In the first 100 patient samples analysed in our diagnostic practice by the use of this comprehensive telomere array, we found three patients with deletions in 3p, 10q and 15q, respectively, four patients with duplications in 9p, 12p, 21q and Xp, respectively, and one patient with a del 6q/dup 16q. The patients with del 3p and 10q and dup 12p had interstitial rearrangements that would have been missed with techniques using one probe per subtelomeric region chosen close to the telomere.     

MLPA vs multiprobe FISH: comparison of two methods for the screening of subtelomeric rearrangements in 50 patients with idiopathic mental retardation

Subtelomeric rearrangements not visible by conventional cytogenetic analysis have been reported to occur in approximately 5% of patients with unexplained mental retardation (MR). As the prevalence of MR is high, many patients need to be screened for these chromosomal abnormalities routinely. Multiplex ligation-dependent probe amplification (MLPA) is a new technique for measuring sequence dosage, allowing large number of samples to be processed simultaneously and thus significantly reducing laboratory work. We have assessed its performance for the detection of subtelomeric rearrangements by comparing the results with those of our previous multiprobe fluorescence in situ hybridization (FISH) assay. We have tested 50 patients with idiopathic MR, dysmorphic features, congenital malformations, and/or familial history of MR. Our results show a high degree of concordance between the two techniques for the 50 samples tested. On the basis of these results, we conclude that MLPA is a rapid, accurate, reliable, and cost-effective alternative to FISH for the screening of subtelomeric rearrangements in patients with idiopathic MR.     

一例类似Prader-Willi综合征表型患者的染色体1p36.3隐匿缺失检测

目的 对1例具有类似Prader-Willi综合征(Prader-Will-like syndrome,PWS)表型患者进行核型分析,确诊其病因.方法 应用高分辨染色体显带技术分析核型及甲基化PCR技术分析15号染色体的遗传印迹区,应用多重连接依赖性探针扩增(multiplex ligation-dependent probe amplification,MLPA)技术筛查患者染色体亚端粒区的异常,经荧光原位杂交(fluorescence in situ hybridization,FISH)验证并结合实时定量PCR进一步确定患者染色体的缺失区域.结果 高分辨染色体检测未发现患者核型异常,甲基化PCR未发现患者的15号染色体遗传印迹基因异常,MLPA分析显示患者存在1p亚端粒区缺失,该结果得到1p亚端粒区探针的FISH证实.进一步选择1p36区域的3个BAC探针进行FISH分析,结合实时定量PCR技术,显示缺失区域位于1p36.3区的4.2 Mb范围内,家系分析显示患者为新发生的染色体异常.确诊为1p36缺失综合征.结论 对类似PWS表型的患者,应进一步做细胞分子学诊断,以明确其发病原因.     

Prospective screening of patients with unexplained mental retardation using subtelomeric MLPA strongly increases the detection rate of cryptic unbalanced chromosomal rearrangements

This study was designed to increase the diagnostic detection rate for subtelomeric unbalanced chromosomal rearrangements (UCRs) that are believed to cause 3-5% of all cases of mental retardation (MR), but often remain undetected by routine karyotyping because of limited resolution in light microscopy. Increased detection of such cryptic UCRs may be achieved by CGH- or SNP-array technology adapted for genome wide screening but these techniques are labor-intensive and expensive. We have implemented subtelomeric Multiplex Ligation-dependant Probe Amplification (MLPA), a relatively low cost and technically uncomplicated molecular approach, as a high throughput prospective screening tool for UCRs in MR patients. We prospectively studied a cohort of 466 MR patients and detected 53 aberrant MLPA signals. After exclusion of false-positives, potential familial polymorphisms and of non-cryptic UCRs also found in routine chromosome analysis, 18 cases or 3.9% of total could be confirmed as true cryptic subtelomeric UCRs. These were 6 terminal deletions, 8 unbalanced translocations, 3 Prader-Willi deletions and 1 subtelomeric interstitial deletion. This result increases our laboratory's detection rate in this patient cohort from 8.3% (without MLPA) to 12.2% (with MLPA), representing a 47% improvement. This study demonstrates that when applying MLPA in a routine cytogenetic diagnostic setting, a major increase of the diagnostic yield can be achieved.     

Screening for subtelomeric rearrangements in 210 patients with unexplained mental retardation using multiplex ligation dependent probe amplification (MLPA)

Background: Subtelomeric rearrangements contribute to idiopathic mental retardation and human malformations, sometimes as distinct mental retardation syndromes. However, for most subtelomeric defects a characteristic clinical phenotype remains to be elucidated.

Objective: To screen for submicroscopic subtelomeric aberrations using multiplex ligation dependent probe amplification (MLPA).

Methods: 210 individuals with unexplained mental retardation were studied. A new set of subtelomeric probes, the SALSA P036 human telomere test kit, was used.

Results: A subtelomeric aberration was identified in 14 patients (6.7%) (10 deletions and four duplications). Five deletions were de novo; four were inherited from phenotypically normal parents, suggesting that these were polymorphisms. For one deletion, DNA samples of the parents were not available. Two de novo submicroscopic duplications were detected (dup 5qter, dup 12pter), while the other duplications (dup 18qter and dup 22qter) were inherited from phenotypically similarly affected parents. All clinically relevant aberrations (de novo or inherited from similarly affected parents) occurred in patients with a clinical score of 3 using an established checklist for subtelomeric rearrangements. Testing of patients with a clinical score of 3 increased the diagnostic yield twofold to 12.4%. Abnormalities with clinical relevance occurred in 6.3%, 5.1%, and 1.7% of mildly, moderately, and severely retarded patients, respectively, indicating that testing for subtelomeric aberrations among mildly retarded individuals is necessary.

Conclusions: The value of MLPA is confirmed. Subtelomeric screening can be offered to all mentally retarded patients, although clinical preselection increases the percentage of chromosomal aberrations detected. Duplications may be a more common cause of mental retardation than has been appreciated.

     

MLPA as first screening method for the detection of microduplications and microdeletions in patients with X-linked mental retardation

PurposeRoutine protocols for the study of mental retardation include karyotype, analysis for fragile X syndrome, and subtelomeric rearrangements. Nevertheless, detection of cryptic rearrangements requires more sensitive techniques. Mutation screening in all known genes responsible for X-linked mental retardation is not feasible, and linkage analysis is sometimes limited. Multiplex ligation probe amplification is a recently developed technique based on the amplification of specific probes that allows relative quantification of 40 to 46 different target DNA sequences in a single reaction.MethodsIn the present study, we assessed multiplex ligation probe amplification for the detection of microduplications/microdeletions in 80 male patients with suspicion of X-linked mental retardation.ResultsWe detected four copy number aberrations (5%): three duplications (GDI1, RPS6KA3, and ARHGEF6) and one deletion (OPHN1). All these changes were confirmed by other molecular techniques, and patients were clinically re-evaluated.ConclusionsWe strongly recommend the use of multiplex ligation probe amplification as a first screening method for the detection of copy number aberrations in patients with mental retardation because of its cost-effectiveness.     

Identification of chromosome abnormalities in subtelomeric regions by microarray analysis: a study of 5,380 cases

Subtelomeric imbalances are a significant cause of congenital disorders. Screening for these abnormalities has traditionally utilized GTG-banding analysis, fluorescence in situ hybridization (FISH) assays, and multiplex ligation-dependent probe amplification. Microarray-based comparative genomic hybridization (array-CGH) is a relatively new technology that can identify microscopic and submicroscopic chromosomal imbalances. It has been proposed that an array with extended coverage at subtelomeric regions could characterize subtelomeric aberrations more efficiently in a single experiment. The targeted arrays for chromosome microarray analysis (CMA), developed by Baylor College of Medicine, have on average 12 BAC/PAC clones covering 10 Mb of each of the 41 subtelomeric regions. We screened 5,380 consecutive clinical patients using CMA. The most common reasons for referral included developmental delay (DD), and/or mental retardation (MR), dysmorphic features (DF), multiple congenital anomalies (MCA), seizure disorders (SD), and autistic, or other behavioral abnormalities. We found pathogenic rearrangements at subtelomeric regions in 236 patients (4.4%). Among these patients, 103 had a deletion, 58 had a duplication, 44 had an unbalanced translocation, and 31 had a complex rearrangement. The detection rates varied among patients with a normal karyotype analysis (2.98%), with an abnormal karyotype analysis (43.4%), and with an unavailable or no karyotype analysis (3.16%). Six patients out of 278 with a prior normal subtelomere-FISH analysis showed an abnormality including an interstitial deletion, two terminal deletions, two interstitial duplications, and a terminal duplication. In conclusion, genomic imbalances at subtelomeric regions contribute significantly to congenital disorders. Targeted array-CGH with extended coverage (up to 10 Mb) of subtelomeric regions will enhance the detection of subtelomeric imbalances, especially for submicroscopic imbalances.     

Detection of cryptic subtelomeric chromosome abnormalities and identification of anonymous chromatin using a quantitative multiplex ligation-dependent probe amplification (MLPA) assay

The need to detect clinically significant segmental aneuploidies beyond the range of light microscopy demands the development of new cost-efficient, sensitive, and robust analytical techniques. Multiplex ligation-dependent probe amplification (MLPA) has already been shown to be particularly effective and flexible for measuring copy numbers in a multiplex format. Previous attempts to develop a reliable MLPA to assay all chromosome subtelomeric regions have been confounded by unforeseen copy number variation in some genes that are very close to the telomeres in healthy individuals. We addressed this shortcoming by substituting all known polymorphic probes and using two complementary multiplex assays to minimize the likelihood of false results. We developed this new quantitative MLPA strategy for two important diagnostic applications. First, in a group of cases with high clinical suspicion of a chromosome abnormality but normal, high-resolution karyotypes, MLPA detected subtelomeric abnormalities in three patients. Two were de novo terminal deletions (del(4p) and del(1p)), and one was a derivative chromosome 1 from a maternal t(1p;17p). The range of these segmental aneuploidies was 1.8-6.6 Mb, and none were visible on retrospective microscopy. Second, in a group of six patients with apparently de novo single-chromosome abnormalities containing anonymous chromatin, MLPA identified two cases with simple intrachromosomal duplications: dup(6p) and dup(8q). Three cases showed derivative chromosomes from translocations involving the distal regions of 9q and 4q, 5p and 11q, and 6q and 3p. One case showed a nonreciprocal, interchromosomal translocation of the distal region of 10p-7p. All abnormalities in both groups were confirmed by fluorescence in situ hybridization (FISH) using bacterial artificial chromosomes (BACs). This quantitative MLPA technique for subtelomeric assays is compared with previously described alternative techniques.     

High resolution microarray CGH and MLPA analysis for improved genotype/phenotype evaluation of two childhood genetic disorder cases: ring chromosome 19 and partial duplication 2q

A detailed analysis of the constitutional chromosomal changes in two pediatric patients was performed using high resolution genetic analysis techniques, microarray comparative genomic hybridization (array CGH) and multiplex ligation-dependent probe amplification (MLPA) as well as FISH. The aim was to come to a more precise characterization of the genotype/phenotype relationship. Case 1 was a girl of 25 months, showing areas of hypopigmentation along the lines of Blaschko and no other developmental abnormality. She carried a ring chromosome 19 which we found not to have resulted in loss of subtelomeric sequences, ruling out the possibility that a small subtelomeric loss was causally related to this patient's phenotype. Case 2 was a 9-year-old girl with facial anomalies and mild growth and mental retardation carrying an unidentified addition on chromosome 2p. We found that the addition was duplicated 2q35-q37.3 and that the addition was not accompanied by loss of 2pter or any other chromosomal region. Together with literature data, we hypothesize that pediatric patients with 'pure' trisomy 2q including bands 2q35-q37.1 may have a moderate clinical phenotype as opposed to patients with duplications proximal to 2q33 or patients with duplications 2q3 with accompanying distal deletion. These two examples illustrate the additional value of new, high resolution genetic analysis techniques for a better characterization of the genotype/phenotype relationship in childhood chromosomal disorders.     

Smith-Magenis syndrome and Moyamoya disease in a patient with del(17)(p11.2p13.1)

Chromosomal rearrangements causing microdeletions and microduplications are a major cause of congenital malformation and mental retardation. Because they are not visible by routine chromosome analysis, high resolution whole-genome technologies are required for the detection and diagnosis of small chromosomal abnormalities. Recently, array-comparative genomic hybridization (aCGH) and multiplex ligation-dependent probe amplification (MLPA) have been useful tools for the identification and mapping of deletions and duplications at higher resolution and throughput. Smith-Magenis syndrome (SMS) is a multiple congenital anomalies/mental retardation syndrome caused by deletion or mutation of the retinoic acid induced 1 (RAI1) gene and is often associated with a chromosome 17p11.2 deletion. We report here on the clinical and molecular analysis of a 10-year-old girl with SMS and moyamoya disease (occlusion of the circle of Willis). We have employed a combination of aCGH, FISH, and MLPA to characterize an approximately 6.3 Mb deletion spanning chromosome region 17p11.2-p13.1 in this patient, with the proximal breakpoint within the RAI1 gene. Further, investigation of the genomic architecture at the breakpoint intervals of this large deletion documented the presence of palindromic repeat elements that could potentially form recombination substrates leading to unequal crossover.     

Subtelomeric chromosome rearrangements in children with idiopathic mental retardation: applicability of three molecular-cytogenetic methods

Aim

To identify cryptic subtelomeric rearrangement, a possible cause of idiopathic mental retardation by means of multiprobe telomere fluorescent in situ hybridization (T-FISH).

Methods

Hundred patients (median age 3.0 years) with mental retardation and dysmorphic features were screened using specific T-FISH probes. Multiplex ligation-dependent probe amplification and comparative genomic hybridization were used for the confirmation of results.

Results

Telomere fluorescent in situ hybridization revealed 11 subtelomeric abnormalities in 10 patients (10%; 95% CI, 5.0-17.5). Four of these had only a deletion of subtelomere 2q, which was apparently a normal variant. Among 6 true aberrations (6%; 95% CI, 2.5-12.5) we found 2 de novo subtelomeric deletions and 4 unbalanced subtelomeric rearrangements (one de novo). All clinically significant subtelomeric rearrangements were confirmed by multiplex ligation-dependent probe amplification. Comparative genomic hybridization was used to investigate the whole genome of patients in whom a subtelomeric anomaly was found, confirming some, but not all subtelomeric rearrangements.

Conclusion

Telomere fluorescent in situ hybridization and multiplex ligation-dependent probe amplification are both very useful and interchangeable methods for the detection of unbalanced chromosome rearrangements, but T-FISH also detects balanced rearrangements. In our experiment, the resolution power of comparative genomic hybridization was too low for subtelomeric screening compared with T-FISH and multiplex ligation-dependent probe amplification.A significant diagnostic challenge exists to identify the new causes of mental retardation. Mental retardation is present in about 1-3% of individuals in the general population, but it can only be explained in about half of the cases, despite thorough clinical and laboratory investigations (1). Several lines of evidence indicate that genetic factors are involved in many of the idiopathic cases, as they often show prenatal and postnatal signs such as dysmorphic features, growth retardation, and malformations or have a family history of mental retardation (1).The subtelomeric regions are interesting from a genomic perspective, as they are gene rich and often involved in chromosomal rearrangements (2). Most telomeres stain lightly with G-banding, and small rearrangements are therefore difficult to detect. In 1996, a complete set of fluorescence in situ hybridization (FISH) probes located within a distance of 300 kB from the telomeric repeats was presented, and an updated set was announced (3,4). These probes made it possible to analyze all chromosome ends for subtelomeric rearrangements in one experiment (5). Today, the most frequently used methods to screen for chromosomal abnormalities in patients with mental retardation are the following: FISH with a complete set of subtelomere probes (T-FISH) (5), multicolor FISH/spectral karyotyping (M-FISH/SKY) (6,7), multiplex amplifiable probe hybridization (MAPH) (8), multiplex ligation-dependent probe amplification (9), comparative genomic hybridization (10), high resolution-comparative genomic hybridization (11), microarray-comparative genomic hybridization (12-14), primed in situ labeling (PRINS) (15), and genotyping (1). The prevalence of abnormalities in the entire group of patients with idiopathic mental retardation is 5.1% but the figure is higher (6.8%) in the individuals with moderate to severe mental retardation (16).We analyzed 100 patients with mental retardation and/or dysmorphic features using T-FISH. By means of multiplex ligation-dependent probe amplification, positive results of T-FISH were confirmed and by means of comparative genomic hybridization the whole genome of patients with subtelomeric aberrations was screened.     

Screening for submicroscopic chromosome rearrangements in children with idiopathic mental retardation using microsatellite markers for the chromosome telomeres

Recently much attention has been given to the detection of submicroscopic chromosome rearrangements in patients with idiopathic mental retardation. We have screened 27 subjects with mental retardation and dysmorphic features for such rearrangements using a genetic marker panel screening. The screening was a pilot project using markers from the subtelomeric regions of all 41 chromosome arms. The markers were informative for monosomy in both parents at 3661902 loci (40.6%, 95% confidence interval 37.0-44.2%) in the 22 families where DNA was available from both parents. In two of the 27 subjects, submicroscopic chromosomal aberrations were detected. The first patient had a 5-6 Mb deletion of chromosome 18q and the second patient had a 4 Mb deletion of chromosome 1p. The identification of two deletions in 27 cases gave an aberration frequency of 7.5% without adjustment for marker informativeness (95% confidence interval 1-24%) and an estimated frequency of 18% if marker informativeness for monosomy was taken into account. This frequency is higher than previous estimates of the number of subtelomeric chromosome abnormalities in children with idiopathic mental retardation (5-10%) although the confidence interval is overlapping. Our study suggests that in spite of the low informativeness of this pilot screening, submicroscopic chromosome aberrations may be a common cause of dysmorphic features and mental retardation.     

Subtelomeric 6p deletion: clinical, FISH, and array CGH characterization of two cases

Thirty patients have been described with cytogenetically visible deletion of the short arm of chromosome 6. However, subtelomeric 6p deletion detected by subtelomeric specific probes has been reported only twice. We report two new patients with terminal 6p deletion detected by subtelomeric screening using fluorescence in situ hybridization (FISH). The two patients exhibited mental retardation, ocular abnormalities, hearing loss, and a characteristic facial appearance. Detailed FISH analyses with probes covering the distal 6p25 region estimated the size of the terminal deletions to approximately 5.5 Mb and approximately 4.8 Mb. Array-based comparative genomic hybridization (array CGH) was used to confirm the cryptic deletions. Most patients with subtelomeric defects lack a characteristic phenotype. However, some of the subtelomeric deletions result in a specific phenotype, which can direct the clinician towards the diagnosis. Submicroscopic 6p deletion appears to be a recognizable clinical phenotype, and this region should be thoroughly investigated with FISH probes, including at least a subtelomeric 6p probe and a probe covering FOXC1, for patients presenting with a characteristic facial appearance, ocular abnormalities, predominantly anterior-chamber eye defects, hearing loss, and mental retardation.     

Delineation of the phenotype associated with 7q36.1q36.2 deletion: long QT syndrome, renal hypoplasia and mental retardation

Terminal deletions of the long arm of chromosome 7 are well known and are frequently associated with hypotelorism or holoprosencephaly due to the involvement of the SHH gene located in 7q36.3. These deletions are easily detectable with routine subtelomeric MLPA analysis. Deletions affecting a more proximal part of 7q36, namely bands 7q36.1q36.2 are less common, and may be missed by subtelomeric MLPA analysis. We report a 9-year-old girl with a 5.27 Mb deletion in 7q36.1q36.2, and compare her to literature patients proposing a phenotype characterized by mental retardation, unusual facial features, renal hypoplasia and long QT syndrome due to loss of the KCNH2 gene. These characteristics are sufficiently distinct that the syndrome may be diagnosed on clinical grounds.