Two additional reports of deletion on the short arm of the Y chromosome.

Deletions on the short arm of the Y chromosome involving the amelogenin Y gene (AMELY), located on Yp11.2, can be misleading for sex typing with serious consequences in forensic applications and prenatal diagnosis. In this study, we describe two AMELY null cases concerning two unrelated Italian males from Northeast Italy. PCR amplification of short tandem repeats on the Y chromosome (Y-STRs) showed a lack of AMELY and DYS458 markers. The presence of all the other markers located on the Y chromosome and of the SRY gene in both samples led us to conclude that a deletion had occurred in a portion of the short arm of the Y chromosome. Twenty-three Y-specific sequence tagged sites (STSs) were chosen to delineate the deletion's length, which was estimated to be in the range of 3.35-3.87Mb for one sample and 1.51-2.58Mb for the other. These and previous findings suggest that in all cases where potential AMELY drop out has occurred, it should be used additional specific Y chromosome markers or human DNA quantification methods that specifically quantify male DNA using target male genomic markers, which not being located within the deletion regions, allow an accurate sex identification.

De novo balanced chromosome rearrangements in prenatal diagnosis.

OBJECTIVE: We surveyed the datasheets of 29 laboratories concerning prenatal diagnosis of de novo apparently balanced chromosome rearrangements to assess the involvement of specific chromosomes, the breakpoints distribution and the impact on the pregnancy outcome. METHOD: By means of a questionnaire, data on 269.371 analyses performed from 1983 to 2006 on amniotic fluid, chorionic villus and fetal blood samples were collected. RESULTS: A total of 246 balanced anomalies were detected at frequencies of 72% for reciprocal translocations, 18% for Robertsonian translocations, 7% for inversions and 3% for complex chromosome rearrangements. The total frequencies of balanced rearrangements were 0.09%, 0.08% and 0.05% on amniotic fluid, chorionic villus and fetal blood samples. CONCLUSION: A preferential involvement of chromosomes 22, 7, 21, 3, 9 and 11 and a less involvement of chromosomes X, 19, 12, 6 and 1 was observed. A nonrandom distribution of the breakpoints across chromosomes was noticed. Association in the location of recurrent breakpoints and fragile sites was observed for chromosomes 11, 7, 10 and 22, while it was not recorded for chromosome 3. The rate of pregnancy termination was about 20%, with frequencies decreasing from complex chromosomal rearrangements (33%), reciprocal translocations (24%) to inversions (11%) and Robertsonian translocations (3%).

Rapid prenatal diagnosis of common chromosome aneuploidies by QF-PCR, results of 9 years of clinical experience.

BACKGROUND: Despite being deliberately targeted to common chromosome aneuploidies, the rapid quantitative fluorescent polymerase chain reaction (QF-PCR) tests can detect the majority of chromosome abnormalities in prenatal diagnosis. The main advantages of this assay are low cost, speed and automation allowing large-scale application. METHODS: We developed a QF-PCR test that was applied on 43 000 clinical samples reporting results in 24 h. Most common indications were biochemical risk (32%) and advanced maternal age (30%). Samples were also tested by cytogenetic analysis and the results compared. RESULTS: Aneuploidies involving chromosomes 21, 18, 13, X and Y were detected with 100% specificity. Several cases of partial trisomies and mosaicism were also identified. Overall 95% of clinically relevant abnormalities were readily detected and termination of affected pregnancies could be performed without waiting for the cytogenetic results. CONCLUSIONS: Our study supports the possibility of reducing the load of prenatal cytogenetic tests if the pregnancies are carefully monitored by non-invasive screening. In case of abnormal QF-PCR results, medical action can be taken within few hours from sampling. In cases of negative QF-PCR results, cytogenetic analyses might only be performed for fetuses with ultrasound abnormalities. In countries where large-scale cytogenetic tests are not available, QF-PCR may be used as the only prenatal diagnostic procedure.

Rapid prenatal diagnosis by QF-PCR: evaluation of 30,000 consecutive clinical samples and future applications.

Rapid prenatal diagnoses of major chromosome abnormalities can be performed on a large scale using highly polymorphic short tandem repeats (STRs) amplified by the quantitative fluorescent polymerase chain reaction (QF-PCR). The assay was introduced as a preliminary investigation to remove the anxiety of the parents waiting for the results by conventional cytogenetic analysis using amniotic fluid or chorionic cells. However, recent studies, on the basis of the analyses of several thousand samples, have shown that this rapid approach has a very high rate of success and could reduce the need for cytogenetic investigations. Its high efficiency, for example, allows early interruption of affected fetuses without the need of waiting for completion of fetal karyotype. The main advantages of the QF-PCR are its accuracy, speed, automation, and low cost that allows very large number of samples to be analyzed by few operators. Here, we report the results of using QF-PCR in a large series of consecutive clinical cases and discuss the possibility that, in a near future, it may even replace conventional cytogenetic analyses on selected samples.

A large interstitial deletion encompassing the amelogenin gene on the short arm of the Y chromosome.

Sex tests based on amelogenin are part of various PCR multiplex reaction kits widely used for human gender identification and have important applications in forensic casework, prenatal diagnosis, DNA databasing and blood sample storage. The two most common sex tests based on amelogenin are represented by primer sets that delimit a 6-bp deletion on the X chromosome to produce X/Y fragments of 106/112 or 212/218 bp, respectively. Few cases of AMELY deletion, usually considered as polymorphisms, have been reported so far and a detailed characterization of the molecular alteration is still lacking. In this study, we describe a large interstitial deletion of the Y short arm encompassing the AMELY locus in two unrelated individuals. The first case was identified in an oligozoospermic, otherwise phenotypically normal, 32-year-old man during the screening for Y microdeletions performed on a sample of infertile males. The second one was found among amniotic liquid samples tested by quantitative fluorescence-polymerase chain reaction and cytogenetic analysis for prenatal diagnosis. The extent of the deletion, spanning approximately 2.5 Mb, was better characterised by pulsed-field gel electrophoresis, followed by fluorescence in situ hybridization and STS marker analysis.

Non-invasive screening and rapid QF-PCR assay can greatly reduce the need for conventional cytogenetic analyses in prenatal diagnosis.

In 2004, the UK National Screening Committee suggested that rapid screening tests, such as fluorescence in-situ hybridization (FISH) and/or quantitative fluorescence PCR (QF-PCR), should replace prenatal diagnosis of Down syndrome performed by conventional karyotyping. However, doubts have been expressed that replacement of conventional cytogenetic investigations would result in a substantial number of infants affected by preventable handicaps. Based on a brief analysis of 28,000 prenatal tests performed in genetic units, this paper discusses the advantages of using QF-PCR. All normal fetuses were correctly diagnosed without false positive results and approximately 93% major chromosome disorders were detected by the molecular approach. The need for cytogenetic tests was thus greatly reduced, since pregnancy can be terminated, if necessary, without the need to confirm the results. A careful combination of accurately performed non-invasive ultrasound and maternal blood tests, eventually followed by QF-PCR, should reduce the need for conventional chromosome analyses.

Sex chromosome rearrangements leading to partial aneuploidies and mosaicisms: use of QF-PCR for detection and quantification of the involved cell lines.

Chromosome rearrangements can lead to aneuploidies of specific chromosome regions and could be present in the entire individual or limited to some tissues (mosaicism) depending on the developmental stage of the embryo when the rearrangement occurs. We report 6 cases with sex chromosome rearrangements identified by conventional cytogenetics and tested by quantitative fluorescent polymerase chain reaction (QF-PCR). QF-PCR has been largely employed for rapid detection of common aneuploidies in pre-natal and post-natal diagnosis and consists in DNA amplification by polymerase chain reaction (PCR) using fluorescent labelled primers and the analysis of chromosome specific small tandem repeats (STR). We tested 5 sex chromosome specific STR markers in multiplex PCR amplifications together with other chromosome specific STR markers as control amplifications. The PCR products were analysed by capillary electrophoresis. The results from QF-PCR analysis were obtained within one day and confirmed our cytogenetic observations. This study shows that QF-PCR analysis can detect sex chromosome imbalance and also suspect mosaicism or chromosome rearrangement.

Immunohistochemical expression analysis of the human interferon-inducible gene IFI16, a member of the HIN200 family, not restricted to hematopoietic cells.

This is the first description of an extensive immunohistochemical analysis of interferon (IFN)-inducible gene IFI16 expression in normal tissues. Immunohistochemical detection of IFI16 in paraffin-embedded tissues is achieved by using a polyclonal antibody raised against its C-terminal fragment that recognizes its three closely migrating isoforms in Western blotting. The results clearly indicate that IFI16 expression is not restricted to the hematopoietic compartment. In normal adult human tissues, it is prominent in stratified squamous epithelia and particularly intense in parabasal cells in the proliferating compartments, but it gradually decreases in the more differentiated suprabasal layers. Understanding of IFI16 expression in vivo is essential for interpretation of the results obtained from in vitro studies and elucidation of its physiologic role. The constitutive expression and wider distribution of IFI16 in normal human tissues, not restricted to the hematopoietic compartment, strongly support the possibility of an important role in cell differentiation that can be further modulated by other stimuli, such as IFN.