Preimplantation genetic diagnosis in 10 couples at risk for transmitting beta-thalassaemia major: clinical experience including the initiation of six singleton pregnancies

Preimplantation genetic diagnosis (PGD) offers couples at risk for transmitting an inherited disorder the possibility to avoid the need to terminate affected pregnancies, since it allows the selection of unaffected IVF embryos for transfer. PGD for monogenic diseases is most commonly accomplished by blastomere biopsy from cleavage stage embryos, followed by polymerase chain reaction (PCR)-based DNA analysis. However, PCR-based DNA analysis of single cells is subject to several problems including sample contamination, total PCR failure, or failure of one allele to amplify--a phenomenon known as allelic drop-out (ADO). Furthermore, the molecular heterogeneity of many monogenic diseases requires a diagnostic strategy capable of detecting a spectrum of mutations and compound genotypes. With the above considerations we developed an accurate and reliable strategy for analysis of beta-globin gene mutations, applicable for PGD for the wide spectrum of beta-thalassaemia major genotypes in the Greek population. The strategy involves nested PCR followed by denaturing gradient gel electrophoresis (DGGE) analysis. DGGE is an advantageous method for mutation detection since it facilitates simultaneous analysis of more than one mutation in a single PCR fragment, it identifies the presence of normal alleles and in addition can monitor the occurrence of ADO. This report describes the application of the DGGE-based diagnostic strategy in 11 clinical IVF/PGD cycles, in 10 couples at risk for transmitting beta-thalassaemia major. The transfer of at least one embryo diagnosed as unaffected for beta-thalassaemia major in nine couples has resulted in the initiation of six pregnancies. Four pregnancies have so far been confirmed as unaffected for beta-thalassaemia major by first or second-trimester prenatal diagnosis, two of which have resulted in the birth of two healthy babies. Three singleton pregnancies are still on-going and one ectopic pregnancy was terminated.     

Preimplantation genetic diagnosis (PGD): the Gothenburg experience

BACKGROUND: A program for preimplantation genetic diagnosis of pre-embryos from patients with hereditary disorders was set up in our unit at Sahlgrenska University Hospital in 1994. The majority of the patients were carriers of X-chromosome linked disorders; a few patients were translocation carriers. In this paper we describe our experiences of our first 36 cycles, 30 gender determinations and six analyses of embryos with possible translocations. METHODS: Conventional hormone replacement treatment with intracytoplasmic sperm injection to fertilize the eggs followed by blastomere biopsy and fluorescent in situ hybridization at the eight cell stage was used for sexing as well as detection of translocations. RESULTS: Out of the 30 cycles in 13 patients for gender determination, blastomere biopsies could be carried out in 25 cycles. Transfer of normal female embryos (XX) was performed in 18 cycles, resulting in five pregnancies (pregnancy rate 27.8%) and an implantation rate of 20% per transfer. Three girls have been born. Hence the take home baby rate was 16.7% per transfer and 10% per started cycle. Six cycles (three patients) for detection of translocations in embryos were performed. Diagnosis was possible in four cycles. Transfer of normal embryos was carried out in one cycle. No pregnancy was achieved. CONCLUSION: Successful PGD in its clinical application demands close collaboration between a large group of specialists. Even so, the success rate is considerably lower than after conventional IVF or ICSI procedures. Taking into account the stress caused to the parents facing late interruption of pregnancy following conventional prenatal diagnosis we are convinced that this technique is well worthwhile continuing and refining.     

Preimplantation genetic diagnosis

Embryo biopsy for preimplantation genetic diagnosis can be performed on the oocyte/zygote, cleavage stage embryo, or blastocyst, but the majority of centres perform cleavage stage biopsy. Single-cell diagnosis is undertaken by the polymerase chain reaction or fluorescent in-situ hybridization. Technical difficulties have arisen with preimplantation genetic diagnosis, such as allele dropout and chromosomal mosaicism. However, it is hoped that these difficulties can be overcome in the future with the advent of new techniques.     

Preimplantation genetic diagnosis

This article aims to inform about the current practices in Preimplantation Genetic Diagnosis (PGD) from a United Kingdom perspective. Progress in the field has been marked over the last decade and new techniques have superseded traditional analysis. The review moves from governance and data collection for PGD to the patient journey. We discuss embryo biopsy and the challenges of analysis when starting with a small amount of DNA. Segments are introduced which introduce basic principles to allow better appreciation of the tests and when they should be applied. We discuss PGD for single gene disorders by preimplantation genetic haplotyping, including for autosomal dominant de novo mutations. Translocations are also discussed and PGD by microarray analysis. We conclude by considering next generation sequencing with the advantages and challenges this may provide to the field.     

植入前遗传学诊断四例临床分析

目的 探讨对遗传病高危夫妇采用单细胞荧光原位杂交（FISH）进行胚胎植入前遗传学诊断（PGD）的临床价值。方法 对曾生育过遗传病患儿的4对夫妇通过超排卵获得卵子,体外受精,体外培养至6-8细胞胚胎,每个胚胎取1-2个细胞,采用FISH进行遗传学分析。筛选无遗传病发病风险的胚胎移植入子宫。结果 4例患者共进行4个治疗周期,获得可供活检的胚胎12个,活检细胞20个,固定后有核细胞17个,FISH后除2个细胞无杂交信号外,其余杂交信号清楚,结果明确,活检后的12个胚胎继续发育,结合遗传学诊断,8个胚胎可供移植,其中1例妊娠,于2001年9月14日足月剖宫产分娩一女婴,发育正常,体重4270g,出生后染色体检查为正常女性核型。结论 对遗传病高危夫妇采用FISH技术进行PGD具有临床应用价值。     

Preimplantation genetic diagnosis using FISH for carriers of Robertsonian translocations: the Portuguese experience

Preimplantation genetic diagnosis (PGD) is an alternative to prenatal diagnosis for couples at risk of transmitting genetic disorders to their offspring. We present a fluorescence in situ hybridization (FISH) analysis of embryos obtained after seven PGD cycles in six couples with Robertsonian translocations and male factor infertility: 4 der(13;14), 1 der(14;21) and 1 der(15;21). Of 74 metaphase II (MII) injected oocytes, 61 (82.4%) fertilized normally and cleaved. Of these, 37/61 (60.7%) embryos were of high morphological quality with >or=6 blastomeres. After biopsy of 44 embryos at day 3 of development, seven degenerated, seven arrested in development and 30/44 (68.2%) evolved, of which 25/30 (83.3%) reached the morula/blastocyst stage. Analysis of biopsied blastomeres showed 23/44 (52.3%) of normal/balanced embryos, of which 15 (11 at the morula/blastocyst stage) were transferred in six cycles. One term pregnancy was achieved, which ended by cesarean section at 37 weeks of gestation, giving birth to two healthy newborn. Analysis of 49 embryos (excluding 12 inconclusive cases) showed a predominance of alternate segregation (38/49, 77.6%) over adjacent segregation (7/49, 14.3%), with one (2%) being a polyploid mosaic and three (6.1%) chaotic.     

Preimplantation genetic diagnosis

Pre-Implantation genetic diagnosis is available to couples at risk of conceiving a pregnancy affected with a known genetic disorder. Assisted reproductive techniques are used in combination with micromolecular diagnostic technologies to recognise at-risk embryos with pathogenic genetic variants at the pre-implantation stage using polar body, blastomere or trophectoderm biopsy. This review will discuss the varying genetic disorders diagnosed by Pre-Implantation Genetic Diagnosis, as well as the ethical, legal and safety implications of the process. Pioneering advances in molecular biology and cytogenomics have been utilised to expand the spectrum of genetic disorders detected.     

Preimplantation genetic diagnosis

Since its introduction in 1990, preimplantation genetic diagnosis (PGD) has allowed embryo genetic analysis prior to transfer into the uterus during an in vitro fertilisation (IVF) cycle. The commonest indications are for detection of single-gene, X-linked, structural chromosomal and mitochondrial disorders as well as for Human Leucocyte Antigen matching. Traditional cytogenetic and molecular techniques of fluorescent in situ hybridization and polymerase chain reaction are complemented by newer technologies e.g. array comparative genomic hybridization and whole genome amplification. Following a successful PGD cycle, pregnancy complications are comparable to those in standard IVF/intra-cytoplasmic sperm injection (ICSI) cycles, which are mostly related to preterm delivery due to multiple pregnancies. There are similar rates of congenital malformations, neonatal morbidity and developmental outcomes in children born after PGD compared with those born after IVF/ICSI. Clinical outcome data is collected by the Preimplantation Genetics International Society and the European Society for Human Reproduction and Embryology PGD Consortium.     

Preimplantation genetic diagnosis

Preimplantation genetic diagnosis is essentially an alternative to prenatal diagnosis, in which genetic testing is performed on embryos before a clinical pregnancy is established. Preimplantation genetic diagnosis has been applied to patients carrying chromosomal rearrangements, such as translocations, in which it has been proven to decrease the number of spontaneous abortions and prevent the birth of children affected with chromosome imbalance. Preimplantation genetic diagnosis techniques have also been applied to increase implantation rates, reduce the incidence of spontaneous abortion and prevent trisomic offspring in women of advanced maternal age undergoing fertility treatment. A third group of patients receiving preimplantation genetic diagnosis are those at risk of transmitting a single gene disorder to their children. The number of monogenic disorders that have been diagnosed in preimplantation embryos has increased each year. Recent protocols have tended to be more complex and more reliable than previous methods, making greater use of multiplex polymerase chain reaction. As well as an expansion in the variety of disorders for which preimplantation genetic diagnosis is offered, new indications have been reported including the use of human leukocyte antigen histocompatibility typing and the application of preimplantation genetic diagnosis to late onset diseases.     

Preimplantation genetic diagnosis for the Kell genotype

OBJECTIVE: To use preimplantation genetic diagnosis (PGD) to achieve a Kell 1 (K1) allele-free pregnancy in couples at risk for producing a child with hemolytic disease of the newborn (HDN) caused by maternofetal incompatibility in sensitized mothers. DESIGN: DNA analysis of biopsied blastomeres from cleavage-stage embryos in IVF-ET with the goal of identifying and transferring back to patients the K1 allele-free embryos. SETTING: IVF program at the Reproductive Genetics Institute, Chicago, Illinois, and IVF Michigan, Rochester Hills, Michigan. PATIENT(S): Two at-risk couples with a history of neonatal death caused by HDN due to K1/K2 genotype in a male partner. INTERVENTION(S): Biopsy of single blastomeres and testing for paternal K1 allele in each embryo after standard IVF. MAIN OUTCOME MEASURE(S): DNA analysis of blastomeres indicating whether corresponding embryos were K1 allele-free for the purpose of transferring only embryos without the K1 allele. RESULT(S): Of 36 embryos tested in five cycles from two couples, 18 were predicted to be K1 allele-free. Of these, 9 were transferred, resulting in a K1 allele-free twin pregnancy and the birth of two healthy children. CONCLUSION(S): PGD of the K1 genotype resulted in the birth of healthy twins confirmed to be free of the K1 allele. PGD in couples with a heterozygous K1/K2 male partner provides an option for avoiding HDN in sensitized mothers.     

Preimplantation genetic diagnosis for single gene disorders: experience with five single gene disorders

We report our experience of 14 preimplantation genetic diagnosis (PGD) cycles in eight couples carrying five different single gene disorders, during the last 18 months. Diagnoses were performed for myotonic dystrophy (DM), cystic fibrosis (CF) [Delta F508 and exon 4 (621+1 G>T)], fragile X and CF simultaneously, and two disorders for which PGD had not been previously attempted, namely neurofibromatosis type 2 (NF2) and Crouzon syndrome. Diagnoses for single gene disorders were carried out on ideally two blastomeres biopsied from Day 3 embryos. A highly polymorphic marker was included in each diagnosis to control against contamination. For the dominant disorders, where possible, linked polymorphisms provided an additional means of determining the genotype of the embryo hence reducing the risk of misdiagnosis due to allele dropout (ADO). Multiplex fluorescent polymerase chain reaction (F-PCR) was used in all cases, followed by fragment analysis and/or single-stranded conformation polymorphism (SSCP) for genotyping. Embryo transfer was performed in 13 cycles resulting in one biochemical pregnancy for CF, three normal deliveries (a twin and a singleton) and one early miscarriage for DM and a singleton for Crouzon syndrome. In each case the untransferred embryos were used to confirm the diagnoses performed on the biopsied cells. The results were concordant in all cases. The inclusion of a polymorphic marker allowed the detection of extraneous DNA contamination in two cells from one case. Knowing the genotype of the contaminating DNA allowed its origin to be traced. All five pregnancies were obtained from embryos in which two blastomeres were biopsied for the diagnosis. Our data demonstrate the successful strategy of using multiplex PCR to simultaneously amplify the mutation site and a polymorphic locus, fluorescent PCR technology to achieve greater sensitivity, and two-cell biopsy to increase the efficiency and success of diagnoses.     

Preimplantation genetic diagnosis for familial dysautonomia

Familial dysautonomia (FD) is the most common congenital sensory neuropathy in Ashkenazi Jews, caused by a single major mutation in the IKBKAP gene. Effective management for this severe debilitating disease is still not available, making preimplantation genetic diagnosis (PGD) a useful option for at-risk couples to establish an FD free pregnancy from the outset. PGD was performed for a couple with a previous affected child with FD, using first and second polar body testing to preselect mutation-free oocytes, based on mutation analysis with simultaneous testing of two closely linked markers, D9S58 and D9S1677. Of 15 tested oocytes, 11 carried information about both polar bodies' genotype, of which seven were predicted to be free of the FD gene. Three embryos resulting from these oocytes were transferred back to the patient, resulting in a triplet pregnancy and the birth of three unaffected children confirmed to be free of FD. This is the first PGD for FD, providing an alternative for those at-risk couples who cannot accept prenatal diagnosis and termination of pregnancy as an option for avoiding FD.