Successful early fetal sex determination using cell-free fetal DNA isolated from maternal capillary blood: A pilot study.

OBJECTIVES: The discovery of cell-free fetal DNA (cffDNA) fragments in maternal plasma made it possible to determine fetal sex at early stages of pregnancy without carrying a risk miscarriage, which is especially important for the management of X-linked genetic abnormalities. The vast majority of studies used cffDNA extracted from maternal venous blood, excluding the possibility of capillary sampling for those who cannot tolerate venipuncture. This study evaluates the possibility of fetal sex determination using cffDNA isolated from capillary blood of women with early gestational pregnancies. STUDY DESIGN: Samples were obtained from 24 pregnant women from the Ukrainian population, whose gestational age varied between 5th to 10th weeks. Sex determination was performed using real-time quantitative PCR of SRY male-specific markers. Results were compared to the known fetal sex (detected by next-generation sequencing during the preimplantation genetic testing procedure) to calculate the test accuracy. RESULTS: Results demonstrated 85.71-100% sensitivity and 100% specificity of the test. Cohen's Kappa coefficient of agreement in sex determination test varied from 0.8 to 1.0 (P < 0.00001). CONCLUSION: This test, which is the first known so far detailed report of successful early fetal sex determination using cffDNA isolated from maternal capillary blood, is a reliable alternative to traditional venipuncture.

PGD for cystic fibrosis patients and couples at risk of an additional genetic disorder combined with 24-chromosome aneuploidy testing.

Preimplantation genetic diagnosis (PGD) for inherited disorders is presently applied for more than 300 different conditions. The most frequent PGD indication is cystic fibrosis (CF), the largest series of which is reviewed here, totalling 404 PGD cycles. This involved testing for 52 different CFTR mutations with almost half of the cases (195/404 cycles) performed for ΔF508 mutation, one-quarter (103/404 cycles) for six other frequent mutations and only a few for the remaining 45 CFTR mutations. There were 44 PGD cycles performed for 25 CF-affected homozygous or double-heterozygous CF patients (18 male and seven female partners), which involved testing simultaneously for three mutations, resulting in birth of 13 healthy CF-free children and no misdiagnosis. PGD was also performed for six couples at a combined risk of producing offspring with CF and another genetic disorder. Concomitant testing for CFTR and other mutations resulted in birth of six healthy children, free of both CF and another genetic disorder in all but one cycle. A total of 96 PGD cycles for CF were performed with simultaneous aneuploidy testing, including microarray-based 24-chromosome analysis, as a comprehensive PGD for two or more conditions in the same biopsy material.

PGD for inherited cardiac diseases.

Preimplantation genetic diagnosis (PGD) has been applied for more than 200 different inherited conditions, with expanding application to common disorders with genetic predisposition. One of the recent indications for PGD has been inherited cardiac disease, for which no preclinical diagnosis and preventive management may exist and which may lead to premature or sudden death. This paper presents the first, as far as is known, cumulative experience of PGD for inherited cardiac diseases, including familial hypertrophic and dilated cardiomyopathy, cardioencephalomyopathy and Emery-Dreifuss muscular dystrophy. A total of 18 PGD cycles were performed, resulting in transfer in 15 of them, which yielded nine unaffected pregnancies and the births of seven disease- or disease predisposition-free children. The data open the prospect of PGD for inherited cardiac diseases, allowing couples carrying cardiac disease predisposing genes to reproduce without much fear of having offspring with these genes, which are at risk for premature or sudden death. Preimplantation genetic diagnosis (PGD) is currently an established clinical procedure in assisted reproduction and genetic practices. Its application has been expanding beyond traditional indications of prenatal diagnosis and currently includes common disorders with genetic predisposition, such as inherited forms of cancer. This applies also to the diseases with no current prospect of treatment, which may manifest despite presymptomatic diagnosis and follow up, when PGD may provide the only relief for the at-risk couples to reproduce. One of the recent indications for PGD has been inherited cardiac disease, for which no preclinical diagnosis and preventive management may exist and which may lead to premature or sudden death. We present here our first cumulative experience of PGD for inherited cardiac diseases, including familial hypertrophic and dilated cardiomyopathy, cardioencephalomyopathy and Emery-Dreifuss muscular dystrophy. A total of 18 PGD cycles for these disorders was performed, resulting in transfer in 15 of them, which yielded nine unaffected pregnancies and birth of seven disease- or disease predisposition-free children. The data open the prospect of PGD for inherited cardiac diseases, allowing couples carrying cardiac disease predisposing genes to reproduce without much fear of having offspring with these genes at risk for premature or sudden death.

Preimplantation genetic diagnosis for hemoglobinopathies.

Hemoglobinopathies are the most frequent indications for preimplantation genetic diagnosis (PGD), allowing couples at-risk of bearing offspring with thalassemia and sickle cell disease to reproduce without fear of having an affected child. The present experience includes PGD for sickle cell disease, α- and ß-thalassemia (α- and ß-thal). We present here the results of the world's largest experience of over 395 PGD cycles for hemoglobin (Hb) disorders, resulting in the birth of 98 healthy, hemoglobinopathy-free children, with seven pregnancies still ongoing. One-third of these cases were performed in combination with HLA typing, allowing the birth of unaffected children who were also HLA identical to the affected siblings with hemoglobinopathies in these families, with successful or pending stem cell transplantation in a dozen of them. The results show that PGD is presently a practical approach for prevention of hemoglobinopathies, gradually also becoming a useful approach to improving access to HLA-compatible stem cell transplantation for this group of diseases.

First systematic experience of preimplantation genetic diagnosis for de-novo mutations.

Standard preimplantation genetic diagnosis (PGD) cannot be applied for de-novo mutations (DNM), because neither origin nor relevant haplotypes are available for testing in single cells. PGD strategies were developed for 80 families with 38 genetic disorders, determined by 33 dominant, three recessive and two X-linked DNM. All three recessive mutations were of paternal origin, while of 93 dominant mutations, 40 were paternal, 46 maternal and seven detected in affected children. The development of specific PGD strategy for each couple involved DNA analysis of the parents and affected children prior to PGD, including a mutation verification, polymorphic marker evaluation, whole and single sperm testing to establish the normal and mutant haplotypes and PGD by polar body analysis and/or embryo biopsy. Overall, 151 PGD cycles were performed for 80 families, for which a specific PGD design has been established. The application of these protocols resulted in pre-selection and transfer of 219 (1.72 per cycle) DNM-free embryos in 127 (84.1%) PGD cycles, yielding 63 (49.6%) unaffected pregnancies and birth of 59 (46.5%) healthy children, confirmed to be free of DNM. The data show feasibility of PGD for DNM, which may routinely be performed with accuracy of over 99%, using the established PGD strategy.

Preimplantation diagnosis for immunodeficiencies.

Preimplantation genetic diagnosis (PGD) has become an established procedure for the detection of single gene disorders, and has recently been performed together with human leukocyte antigen (HLA) typing for couples with children affected by genetic disorders that require HLA-identical stem cell transplantation therapy. For these couples, PGD can ensure the birth of an unaffected child, and because HLA-matched stem cell transplantation improves or completely restores the immune system, this child may also serve as a potential stem cell donor for affected siblings. This paper presents the first cumulative experience (18 cycles) of PGD for detection of the following immunodeficiencies: Wiscott-Aldrich syndrome, X-linked hyper-IgM syndrome (HIGM), X-linked hypohidrotic ectodermal dysplasia with immune deficiency (HED-ID), ataxia telangiectasia and Omenn syndrome, resulting in the transfer of unaffected embryos in 13 cycles and the birth of seven unaffected children, with one healthy pregnancy ongoing. HLA-identical stem cells from some of these children have been used for transplantation therapy, resulting in the restoration of normal function in siblings with HIGM and HED-ID.

Pre-embryonic diagnosis for Sandhoff disease.

Embryos found to be abnormal during preimplantation genetic diagnosis (PGD) are discarded or analysed to confirm the diagnosis. To overcome this limitation, which is unacceptable in some communities and ethnic groups, pre-embryonic genetic diagnosis has been introduced, involving sequential first and second polar body analysis followed by transfer of embryos deriving from the mutation-free oocytes, while removing from culture and freezing the mutant oocytes at the pronuclear stage. The technique is applied here to PGD of Sandhoff disease caused by 16-kb deletion of the hexosaminidase B gene for a couple with a religious objection to discarding embryos irrespective of embryo genotype. Of 16 oocytes tested in a standard IVF protocol for 16-kb deletion, simultaneously with five linked polymorphic markers, eight were predicted mutant and frozen prior to syngamy, with the remaining eight, found to be free of mutation, further cultured and confirmed unaffected using blastomere biopsy. The transfer of two of these embryos resulted in birth of an unaffected child, demonstrating feasibility of pre-embryonic diagnosis to avoid embryo discard.

Preimplantation HLA typing with aneuploidy testing.

Preimplantation HLA typing has been introduced for the treatment of affected siblings, requiring HLA-identical stem cell transplantation. This was applied either in combination with preimplantation genetic diagnosis (PGD) to ensure that the preselected HLA-matched embryos were also free of the genetic disorder, or without PGD, with the only purpose of selecting and transferring the HLA-matched embryos. Because patients requesting preimplantation HLA typing are usually of advanced reproductive age, aneuploidy testing allows not only the avoidance of the birth of children with chromosomal disorders, but also improvement of the reproductive outcome, which is still not sufficiently high in preimplantation HLA typing at the present time. This study presents the results of the first experience of preimplantation HLA typing combined with aneuploidy testing, demonstrating feasibility and impact of aneuploidy testing on the accuracy and outcome of preimplantation HLA typing. Of a total of 138 cycles performed, 87 were combined with PGD and 52 without testing for the causative gene, of which aneuploidy testing was performed in 27 cycles, allowing the preselection and transfer of only those HLA-matched embryos that were also euploid. Although the euploid HLA-identical embryos were available for transfer in only half of these cycles, pregnancy and birth of unaffected HLA-identical children were observed in approximately half of these cycles, suggesting the potential usefulness of incorporating aneuploidy testing into preimplantation HLA typing.

Reprogramming of human somatic cells by embryonic stem cell cytoplast.

Somatic cell nuclear transfer (SCNT) provides the basis for the development of patient-specific stem cell lines. Recent progress in SCNT suggested the presence of reprogramming factors in human embryonic stem (hES) cells, although no method is currently available for replacement of nuclei of hES cells by somatic cell nuclei. An original technique has been developed, involving the fusion of different types of somatic cells with hES cells, which allowed a complete replacement of the nuclei of hES cells by nuclei of somatic cells. The resulting 'cybrids' were demonstrated to have the genotype of the donor somatic cells and 'stemness' of the recipient hES cells. However, the colonies isolated from the resulting fusion contained a mixture of these cybrid cells with the cells with the recipient nuclei, as well as hybrid cells containing both donor and recipient nuclei, so future purification will be necessary before the technique can be considered for future practical application.

Cytoplasmic cell fusion: Stembrid technology for reprogramming pluripotentiality.

Recent progress in somatic cell nuclear transfer (SCNT) provides the evidence for the presence of reprogramming factors in human embryonic stem cells (hESC). Hybrid hESC with donor human somatic nuclei have been established, but the resulting hybrid hESC contained DNA originating from both hESC and donor somatic cells. There is still no method to completely replace the hESC nuclei by the nuclei of somatic cells and to obtain the pure colonies of hESC with donor genotype. We present here the original technology, which is based on enucleation of h ESC and their fusion with the adult somatic cells, resulting in the establishment of individual-specific hESC with the genotype of the donor somatic cells. The resulting constructs was demonstrated to have the "stemness" of hESC and the genotype of the donor somatic cells. So this "Stembrid technology," may be used for the construction of patient-specific hESC.

Preimplantation genetic diagnosis for polycystic kidney disease.

OBJECTIVE: To use preimplantation genetic diagnosis for achieving a polycystic kidney disease (PKD)-free pregnancy for a couple in which the female partner was affected by PKD but whose PKD1 or PKD2 carrier status was not established. DESIGN: Case report. SETTING: The IVF program of Reproductive Genetics Institute, Chicago, Illinois. PATIENT(S): An at-risk couple with the female partner affected by PKD, whose PKD1 or PKD2 carrier status was not established. INTERVENTION(S): Removal of PB1 and PB2 and testing for three closely linked markers to PKD1 (Kg8, D16S664, and SM7) and four closely linked markers to PKD2 (D4S2922, D4S2458, D4S423, and D4S1557) after standard IVF. MAIN OUTCOME MEASURE(S): Deoxyribonucleic acid analysis of PB1 and PB2 indicating whether corresponding oocytes were PKD1 or PKD2 allele free, for the purpose of transferring only embryos resulting from mutation-free oocytes. RESULT(S): Of 11 oocytes tested by PB1 and PB2 DNA analysis, 7 were predicted to contain PKD1 or PKD2, with the remaining 4 free of both mutations. Three embryos resulting from these oocytes were transferred, yielding a twin pregnancy and the birth of two unaffected children. CONCLUSION(S): This is the first preimplantation genetic diagnosis for PKD, which resulted in the birth of healthy twins confirmed to be free of PKD1 and PKD2. Preimplantation genetic diagnosis based on linked marker analysis provides an alternative for avoiding the pregnancy and birth of children with PKD, even in at-risk couples without exact PKD1 or PKD2 carrier information.

Morula-derived human embryonic stem cells.

Human embryonic stem (ES) cells are known to derive from the inner cell mass of blastocyst. Although the embryos of other developmental stages have also been used as a source for ES cells in animal models, the feasibility of obtaining ES cell lines from human morula is not known, despite being an obvious source available through assisted reproduction and preimplantation genetic diagnosis programmes. This study describes an original technique for derivation of ES cells from human morula, which enabled the establishment of eight morula-derived ES cell lines. These ES cell lines were shown to have no morphological differences from the ES cells derived from blastocysts, and expressed the same ES cell specific markers, including Oct-4, tumour-resistance antigens TRA-2-39, stage-specific embryonic antigens SSEA-3 and SSEA-4, and high molecular weight glycoproteins TRA-1-60 and TRA-1-81, detected in the same colony of morula-derived ES cells showing specific alkaline phosphatase expression. No differences were observed in these marker expressions in the morula-derived ES cells cultured in the feeder layer free medium. Similar to ES cell originating from blastocyst, the morula-derived ES cells were shown to spontaneously differentiate in vitro into a variety of cell types, including the neuron-like and contracting primitive cardiocyte-like cells.

Preimplantation genetic diagnosis for cancer predisposition.

Preimplantation genetic diagnosis (PGD) has recently been offered for couples with an inherited predisposition for late onset disorders. This paper presents the results of PGD for a group of couples at risk for producing children with cancer predisposition. Using a standard IVF procedure, oocytes or embryos were tested for different mutations predisposing to cancer, preselecting and transferring only mutation-free embryos back to the patients. The procedure was performed for patients with predisposition to familial adenomatous polyposis coli (FAP), Von Hippel-Lindau syndrome (VHL), retinoblastoma, Li-Fraumeni syndrome, determined by p53 tumour suppressor gene mutations, neurofibromatosis types I and II and familial posterior fossa brain tumour (hSNF5). Overall, 20 PGD cycles were performed for 10 couples, resulting in preselection and transfer of 40 mutation-free embryos, which resulted in five unaffected clinical pregnancies and four healthy children born by the present time. Despite the controversy of PGD use for late onset disorders, the data demonstrate the usefulness of this approach as the only acceptable option for at-risk couples to avoid the birth of children with an inherited predisposition to cancer, and to have a healthy child.

Preimplantation diagnosis for early-onset Alzheimer disease caused by V717L mutation.

CONTEXT: Indications for preimplantation genetic diagnosis (PGD) have recently been expanded to include disorders with genetic predisposition to allow only embryos free of predisposing genes to be preselected for transfer back to patients, with no potential for pregnancy termination. OBJECTIVE: To perform PGD for early-onset Alzheimer disease (AD), determined by nearly completely penetrant autosomal dominant mutation in the amyloid precursor protein (APP) gene. DESIGN: Analysis undertaken in 1999-2000 of DNA for the V717L mutation (valine to leucine substitution at codon 717) in the APP gene in the first and second polar bodies, obtained by sequential sampling of oocytes following in vitro fertilization, to preselect and transfer back to the patient only the embryos that resulted from mutation-free oocytes. SETTING: An in vitro fertilization center in Chicago, Ill. PATIENTS: A 30-year-old AD-asymptomatic woman with a V717L mutation that was identified by predictive testing of a family with a history of early-onset AD. MAIN OUTCOME MEASURES: Results of mutation analysis; pregnancy outcome. RESULTS: Four of 15 embryos tested for maternal mutation in 2 PGD cycles, originating from V717L mutation--free oocytes, were preselected for embryo transfer, yielding a clinical pregnancy and birth of a healthy child free of predisposing gene mutation according to chorionic villus sampling and testing of the neonate's blood. CONCLUSION: This is the first known PGD procedure for inherited early-onset AD resulting in a clinical pregnancy and birth of a child free of inherited predisposition to early-onset AD.

Preimplantation diagnosis for neurofibromatosis.

Preimplantation genetic diagnosis (PGD) has recently been performed for inherited cancer predisposition determined by p53 tumour suppressor gene mutations, suggesting the usefulness of PGD for late onset disorders with genetic predisposition, including those caused by the germline mutations of other tumour suppressor genes. Here PGD was performed for two couples, one at risk for producing a child with maternally derived neurofibromatosis type I (NF1), and the other with paternally derived neurofibromatosis type II (NF2). The procedure involved a standard IVF protocol, combined with testing of oocytes or embryos prior to their transfer back to the patients. Maternal mutation Trp-->Ter (TGG-->TGA) in exon 29 of the NF1 gene was tested by sequential PCR analysis of the first and second polar bodies, and paternal L141P mutation in exon 4 of the NF2 gene by embryo biopsy at the cleavage stage. In both cases, multiplex nested PCR was applied, involving NF1 and NF2 mutation analysis simultaneously with the 3 and 2 linked markers, respectively. Of 57 oocytes tested in four PGD cycles for NF1 mutation, 26 mutation-free oocytes were detected, from which eight were preselected for transfer, two in each cycle. These produced two clinical pregnancies, one confirmed to be mutation free by chorionic villus sampling but ending in a stillbirth, and the other still ongoing. Of 18 embryos analysed in a cycle performed for NF2 mutation, eight mutation-free embryos were detected, three of which were transferred back to the patient, resulting in a singleton pregnancy and the birth of a mutation-free child. This suggests that PGD is a useful approach for avoiding the birth of children with inherited cancer predisposition, determined by NF1 and NF2 gene mutations.

Preimplantation diagnosis for p53 tumour suppressor gene mutations.

Preimplantation genetic diagnosis (PGD) was introduced for high-risk couples to avoid establishing affected pregnancies potentially requiring termination following prenatal diagnosis. This opens the possibility for PGD for late onset disorders with genetic predisposition, including inherited cancer predisposition, because only embryos free from the predisposing gene may be transferred back to the patient, with no potential risk for pregnancy termination. PGD was performed for two couples, one with maternally and one with paternally derived p53 tumour-suppressor mutations, 902insC in exon 8 and G524A in exon 5, respectively. This involved a standard IVF protocol, allowing oocytes or embryos to be tested prior to their transfer back to uterus. Maternal mutation was tested by sequential PCR analysis of the first and second polar bodies, removed following maturation and fertilization of oocytes, while paternal mutation analysis required embryo biopsy at the cleavage stage. To avoid misdiagnosis due to allele drop out, multiplex nested PCR was applied, involving p53 mutation analysis simultaneously with the linked short tandem repeats in intron 1. Of 10 oocytes tested in two PGD cycles for 902insC mutation, four unaffected oocytes were pre-selected for transfer yielding no clinical pregnancy. Of 18 embryos analysed in two cycles for G524A mutation, seven mutation-free embryos were detected, two of which were transferred in each cycle, resulting in a singleton pregnancy and birth of a mutation-free child. This is the first PGD for inherited cancer predisposition determined by p53 tumour suppressor mutations, resulting in a clinical pregnancy and birth of a child free from inherited cancer predisposition.

Preimplantation diagnosis for long-chain 3-hydroxyacyl-CoA dehydrogenase deficiency.

Long-chain 3-hydroxyacyl-CoA dehydrogenase (LCHAD) deficiency is a fatal autosomal recessive metabolic disorder, presenting during infancy. Preimplantation genetic diagnosis (PGD) provides an option for establishing an unaffected pregnancy, avoiding the risk for termination of pregnancy following prenatal diagnosis. The method for pre-selection of mutation-free oocytes for LCHAD deficiency was developed by testing the first and second polar body removed from oocytes by micromanipulation techniques in the framework of in-vitro fertilization. To avoid misdiagnosis, testing was done using hemi-nested polymerase chain reaction (PCR), with outer primers designed to lie outside the pseudogene, eliminating false priming. Four of 12 tested oocytes were predicted to be unaffected, based on the heterozygous first and mutant second polar body. The embryos resulting from these mutation-free oocytes were replaced, yielding a singleton clinical pregnancy and birth of a healthy child following confirmation by prenatal diagnosis.