Peter M. Kroisel

Maternal methylation imprints on human chromosome 15 are established during or after fertilization.

Prader-Willi syndrome (PWS) is a neurogenetic disorder that results from the lack of transcripts expressed from the paternal copy of the imprinted chromosomal region 15q11–q13 (refs. 1,2). In some patients, this is associated with a deletion of the SNURF-SNRPN exon 1 region inherited from the paternal grandmother and the presence of a maternal imprint on the paternal chromosome. Assuming that imprints are reset in the germ line, we and others have suggested that this region constitutes part of the 15q imprinting center (IC) and is important for the maternal to paternal imprint switch in the male germ line. Here we report that sperm DNA from two males with an IC deletion had a normal paternal methylation pattern along 15q11–q13. Similar findings were made in a mouse model. Our results indicate that the incorrect maternal methylation imprint in IC deletion patients is established de novo after fertilization. Moreover, we found that CpG-rich regions in SNURF-SNRPN and NDN, which in somatic tissues are methylated on the maternal allele, are hypomethylated in unfertilized human oocytes. Our results indicate that the normal maternal methylation imprints in 15q11–q13 also are established during or after fertilization.

Disruption of a Novel Gene (IMMP2L) by a Breakpoint in 7q31 Associated with Tourette Syndrome

Gilles de la Tourette syndrome (GTS) is a complex neuropsychiatric disorder characterized by multiple motor and phonic tics. We identified a male patient with GTS and other anomalies. It was determined that he carried a de novo duplication of the long arm of chromosome 7 [46,XY,dup(7)(q22.1-q31.1)]. Further molecular analysis revealed that the duplication was inverted. The distal chromosomal breakpoint occurred between the two genetic markers D7S515 and D7S522, which define a region previously shown to be disrupted in a familiar case of GTS. Yeast and bacterial artificial chromosome clones spanning the breakpoints were identified by means of FISH analysis. To further characterize the distal breakpoint for a role in GTS, we performed Southern blot hybridization analysis and identified a 6.5-kb SacI junction fragment in the patients genomic DNA. The DNA sequence of this fragment revealed two different breaks in 7q31 within a region of approximately 500 kb. IMMP2L, a novel gene coding for the apparent human homologue of the yeast mitochondrial inner membrane peptidase subunit 2, was found to be disrupted by both the breakpoint in the duplicated fragment and the insertion site in 7q31. The cDNA of the human IMMP2L gene was cloned, and analysis of the complete 1,522-bp transcript revealed that it encompassed six exons spanning 860 kb. The possible role of IMMP2L and several other candidate genes within the region of chromosomal rearrangement, including NRCAM, Leu-Rch Rep, and Reelin, is discussed. The 7q31 breakpoint interval has also been implicated in other neuropsychiatric diseases that demonstrate some clinical overlap with GTS, including autism and speech-language disorder.

Recessive mutations in EPG5 cause Vici syndrome, a multisystem disorder with defective autophagy

Vici syndrome is a recessively inherited multisystem disorder characterized by callosal agenesis, cataracts, cardiomyopathy, combined immunodeficiency and hypopigmentation. To investigate the molecular basis of Vici syndrome, we carried out exome and Sanger sequence analysis in a cohort of 18 affected individuals. We identified recessive mutations in EPG5 (previously KIAA1632), indicating a causative role in Vici syndrome. EPG5 is the human homolog of the metazoan-specific autophagy gene epg-5, encoding a key autophagy regulator (ectopic P-granules autophagy protein 5) implicated in the formation of autolysosomes. Further studies showed a severe block in autophagosomal clearance in muscle and fibroblasts from individuals with mutant EPG5, resulting in the accumulation of autophagic cargo in autophagosomes. These findings position Vici syndrome as a paradigm of human multisystem disorders associated with defective autophagy and suggest a fundamental role of the autophagy pathway in the immune system and the anatomical and functional formation of organs such as the brain and heart.

Rapid detection of chromosome aneuploidies by quantitative fluorescence PCR: first application on 247 chorionic villus samples

We report the results of the first major study of applying quantitative fluorescence polymerase chain reaction (QF-PCR) assays for the detection of major chromosome numerical disorders. The QF-PCR tests were performed on a total of 247 chorionic villus samples, which were analysed blind, without any knowledge of the results obtained using conventional cytogenetic analysis. The aims of this investigation were to evaluate the detection power and accuracy of this approach by testing a large number of fetal samples and to assess the diagnostic value of each of the chromosome specific small tandem repeat (STR) markers used. In addition, we introduced three more markers specific for chromosomes 13, 18, and X to allow an accurate analysis of samples homozygous for a particular STR. Fluorescent labelled primers were used to amplify 12 STRs specific for chromosomes 21, 18, 13, X, and the amylogenin-like DNA sequence AMXY, expressed on the X and Y chromosomes. In this blind study of 247 fetal samples, 222 were correctly diagnosed by QF-PCR as normal for each of the five chromosomes investigated; 20 were diagnosed by QF-PCR as trisomic for chromosomes 21, 18, or 13, in agreement with the cytogenetic tests. Only one false negative result was observed, probably owing to the mishandling of the sample, which had been transferred through three laboratories before being analysed by QF-PCR. The 247 samples also included four cases of mosaicism or translocation; one case of mosaic trisomy 21 was detected by QF-PCR and the other cases were not identified by QF-PCR. The results of this investigation provide clear evidence that the QF-PCR assays are powerful adjuncts to conventional cytogenetic techniques and can be applied for the rapid and accurate prenatal diagnosis of the most frequent aneuploidies.

Rapid detection of trisomies 21 and 18 and sexing by quantitative fluorescent multiplex PCR

Abstract Aneuploidies involving chromosomes 21, 18, 13, X and Y account for over 95% of all chromosomal abnormalities in live-born infants. Prenatal diagnosis of these disorders is usually accomplished by cytogenetic analysis of amniotic or chorionic cells but this is a lengthy procedure requiring great technical expertise.In this paper, we assess the diagnostic value of using a quantitative fluorescent polymerase chain reaction (PCR) suitable for the simultaneous and rapid diagnosis of trisomies 21 and 18 together with the detection of DNA sequences derived from the X and Y chromosomes. Samples of DNA, extracted from amniotic fluid, fetal blood or tissues, and peripheral blood from normal adults were investigated by quantitative fluorescent PCR amplification of polymorphic small tandem repeats (STRs) specific for two loci on each of chromosomes 21 and 18. Quantitative analysis of the amplification products allowed the diagnosis of trisomies 21 and 18, while sexing was performed simultaneously using PCR amplification of DNA sequences derived from the chromosomes X and Y. These results indicate the advantages of using two sets of STR markers for the detection of chromosome 21 trisomies and confirmed the usefulness of quantitative fluorescent multiplex PCR for the rapid prenatal diagnosis of selected chromosomal abnormalities.

Quantitative fluorescence polymerase chain reaction for the rapid prenatal detection of common aneuploidies and fetal sex

OBJECTIVE We have developed a quantitative fluorescence multiplex polymerase chain reaction assay for the rapid detection of sex and aneuploidies involving chromosomes 21, 18, and 13. STUDY DESIGN Samples of deoxyribonucleic acid (n = 85) extracted from amniotic fluid, fetal tissues, and blood were investigated by multiplex polymerase chain reaction amplification of polymorphic small tandem repeat markers specific for chromosomes 21, 18, 13, and X. RESULTS Quantitative analysis of the polymerase chain reaction products allowed us to distinguish between normal samples and samples with autosomal trisomies while sexing was performed simultaneously. From 85 samples only three produced unsatisfactory results with one of the two chromosome 13-specific markers. In these three cases the amplification of the other chromosome 13 marker always resulted in a correct normal pattern. CONCLUSION Quantitative fluorescence multiplex polymerase chain reaction is a reliable and rapid method that allows prenatal diagnosis of the major numeric chromosomal abnormalities to be performed within 24 hours.

The human γ-aminobutyric acid A receptor delta (GABRD) gene: molecular characterisation and tissue-specific expression

Abstract Terminal deletions of 1p36 result in a specific and common syndrome characterised by the following: growth delay, distinctive facial anomalies, hearing and visual deficits, heart defects, body asymmetry, moderate to severe psychomotor retardation, epilepsy, and self-abusive behaviour. The human gamma-aminobutyric acid A receptor delta-subunit gene ( GABRD ) encodes for one of at least 15 ligand-gated chloride channels for gamma-aminobutyric acid ( GABA ), the major inhibitory neurotransmitter in the mammalian brain. Recently we have mapped this gene by radiation hybrid mapping to the critical region of gene loss of the 1p36 deletion syndrome within 1p36.33. The complete complementary DNA (cDNA) sequence of GABRD was generated using assembled sequence of cDNA fragments already available, and 5′-rapid amplification of cDNA ends products. Fine physical mapping of the GABRD gene within this genomic interval was performed by screening bacterial artificial chromosome contigs spanning the critical region of the 1p36 deletion syndrome. The GABRD gene maps immediately proximal to the PRKCZ gene that is located between marker D1S243 and cosmid D1Z2 – a region thought to be critical for cognition and speech development. The GABRD gene is expressed most abundantly in brain and has three alternative exons (1A–C) with alternative start codons at the 5′-end. Genomic localisation, function, and expression would suggest that the GABRD gene represents a good candidate for the neurodevelopmental and neuropsychiatric anomalies seen in the 1p36 deletion syndrome.

Familial Mental Retardation Syndrome ATR-16 Due to an Inherited Cryptic Subtelomeric Translocation, t(3;16)(q29;p13.3)

In the search for genetic causes of mental retardation, we have studied a five-generation family that includes 10 individuals in generations IV and V who are affected with mild-to-moderate mental retardation and mild, nonspecific dysmorphic features. The disease is inherited in a seemingly autosomal dominant fashion with reduced penetrance. The pedigree is unusual because of (1) its size and (2) the fact that individuals with the disease appear only in the last two generations, which is suggestive of anticipation. Standard clinical and laboratory screening protocols and extended cytogenetic analysis, including the use of high-resolution karyotyping and multiplex FISH (M-FISH), could not reveal the cause of the mental retardation. Therefore, a whole-genome scan was performed, by linkage analysis, with microsatellite markers. The phenotype was linked to chromosome 16p13.3, and, unexpectedly, a deletion of a part of 16pter was demonstrated in patients, similar to the deletion observed in patients with ATR-16 syndrome. Subsequent FISH analysis demonstrated that patients inherited a duplication of terminal 3q in addition to the deletion of 16p. FISH analysis of obligate carriers revealed that a balanced translocation between the terminal parts of 16p and 3q segregated in this family. This case reinforces the role of cryptic (cytogenetically invisible) subtelomeric translocations in mental retardation, which is estimated by others to be implicated in 5%-10% of cases.

SNURF-SNRPN and UBE3A transcript levels in patients with Angelman syndrome

The imprinted domain on human chromosome 15 consists of two oppositely imprinted gene clusters, which are under the control of an imprinting center (IC). The paternally expressed SNURF-SNRPN gene hosts several snoRNA genes and overlaps the UBE3A gene, which is encoded on the opposite strand, expressed — at least in brain cells — from the maternal chromosome only, and affected in patients with Angelman syndrome (AS). In contrast to SNURF-SNRPN, imprinted expression of UBE3A is not regulated by a 5′ differentially methylated region. Here we report that splice forms of the SNURF-SNRPN transcript overlapping UBE3A in an antisense orientation are present in brain but barely detectable in blood. In contrast, splice forms that do not overlap with UBE3A are of similar abundance in brain and blood. The tissue distribution of the splice forms parallels that of the snoRNAs encoded in the respective parts of the SNURF-SNRPN transcript. Using a quantitative PCR assay, we have found that the ratio of SNURF-SNRPN/UBE3A transcript levels is increased in blood cells of AS patients with an imprinting defect, but not in AS patients with a UBE3A mutation or an unknown defect. Our findings are compatible with the assumption that imprinted UBE3A expression is regulated through the SNURF-SNRPN sense-UBE3A antisense transcript.

Molecular and genomic studies of IMMP2L and mutation screening in autism and Tourette syndrome

We recently reported the disruption of the inner mitochondrial membrane peptidase 2-like (IMMP2L) gene by a chromosomal breakpoint in a patient with Gilles de la Tourette syndrome (GTS). In the present study we sought to identify genetic variation in IMMP2L, which, through alteration of protein function or level of expression might contribute to the manifestation of GTS. We screened 39 GTS patients, and, due to the localization of IMMP2L in the critical region for the autistic disorder (AD) locus on chromosome 7q (AUTS1), 95 multiplex AD families; however, no coding mutations were found in either GTS or AD patients. In addition, no parental-specific expression of IMMP2L was detected in somatic cell hybrids containing human chromosome 7 and human cell lines carrying a maternal uniparental disomy for chromosome 7 (mUPD7). Despite the fact that no deleterious mutations in IMMPL2 (other than the inverted duplication identified previously) were identified in either GTS or AD, this gene cannot be excluded as a possible rare cause of either disorder.