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73. SIMULTANEOUS PGT-M APPLICATIONS FOR MULTIPLE GENETIC CONDITIONS
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RBMO VOLUME 39 ISSUE s1 2019
73. SIMULTANEOUS PGT-M APPLICATIONS FOR MULTIPLE GENETIC CONDITIONS
S. Aktuna, E. Unsal, L. Ozer, M. Aydin, V. Baltaci Mikrogen Genetic Diagnosis Center, Ankara, Turkey
Introduciton: Pre-implantation genetic diagnosis for monogenic disorders (PGT-M) have been extensively applied for genetic conditions resulting from mutations at single genetic locus . Vast amount of data have arised from Whole Exom Sequencing (WES) and Whole Genome Sequencing (WGS) technologies it is not always straight forward to filter out the mutation responsible for the disorder. Furthermore consanguinity increases the risk of cooccurence of two or more etiologically different genetic diseases in a single family. For this reason increased number of patients referred to PGT-M applications started to demand simultaneous testing of multiple genetic disorders. Drastically some families referred for one condition later had further offsprings with additional single gene defects. We are reporting PGT-M application for two or more genetic conditions performed in our center. Materials and Methods: PGT-M was performed by testing blastocyst/ blastomere samples depending on the familial pathogenic variants. For this purpose biopsied cells were lysed and fragment analysis for haplotyping and sequence analysis for mutation detection have been performed following multiplex nested PCR. PGT-M testing was performed simultaneously for multiple genetic conditions in 17 couples. 6 infromative STR markers were used for each loci in addition to mutation site. Results: was performed for 17 couples and 36 disorders including (Beta Thallasemia, DMD, Glycogen storage disease, Mitochondrial complex I deficiency, Maple syrup
urine disease etc.) For 2 couples 3 different conditions were screened simultaneously. While 5 out 7 embryos was appropriate for transfer in one of these patients only 1 out of 8 embyos was transferable for the second case. For 15 couples where 2 conditions were screened 32 embryos out of 104 were appropriate for transfer. Embryo transfer was performed in all patients except for one patient who had only 1 embryo for . Conclusion: Insufficient information in databeses regarding the pathogenicity of variants for rare diseases leads to a difficults in counselling patients for PGT-M. Frequent use of WES/WGS for families has become an effective tool for detecting the mutations to enable PGT-M application for families without previous diagnosis of their affected child. Unfortunately in many cases unusal phenotypes in consangenous couples forces us to exclude all variants including variants of unknown significance (VUS) that may be associated with phenotype. This a challanging approach since PGT-M should be designed for each condition together with linked STR markers for each of them to achieve high confidence results. Additionally the more we try to exclude the less likely we will find an appropriate embryo for transfer and families should be informed of this possibility before consenting to PGT-M applications. Because of this delineation of VUS will enable us to interprete patients history and give more efficient counselling to PGT-M patients thus limiting the number of embryos excluded due to these variants. Keywords: Preimplantation Genetic Testing
for Monogenic/Single Gene Disorders; In Vitro Fertilization; Whole Exom Sequencing
doi: 10.1016/j.rbmo.2019.04.126
74. NORMAL LIVE BIRTH FROM TWO CARRIERS OF RARE INSERTIONAL TRANSLOCATIONS UNDERGOING PGT
I. Bernicot1, Z. Reda1, C. Cendrine1, E. Haquet2, N. Ranisavljevic3, T. Anahory3 1 Cytogenetic
PGD department, Arnaud De Villeneuve Hospital, Montpellier, Montpellier, France 2 Department of Medical Genetics, Arnaud De Villeneuve Hospital, Montpellier, Montpellier, France 3 ART-PGD Department, Arnaud De Villeneuve Hospital, Montpellier, Montpellier, France
Introduction: Despite the use of more precise techniques that indicates greater incidence, meiotic segregation of interchromosomal insertion has rarely been studied. Theoretically, the risk to have a child at term with malformation or mental retardation is high but there are no tools to determine this risk. We have investigated the Preimplantation genetic diagnosis (PGT) management of patients with interchromosomal insertion (IT) by fluorescent in situ hybridization (FISH) to obtain a better understanding and improve the genetic counseling. Material & methods: Two couples were enrolled in our PGT unit. The male of the first couple carries the IT 46,XY,ins(4;11)(q22;p12p13) and the female karyotype of the second couple is 46,XX,ins(2;10) (q21;q25.2q22). We have investigated, by FISH technique, the meiotic segregation analysis of the sperm of the IT male carrier and embryos providing from the two carriers. One FISH analysis round was performed for the male IT carrier. Five specific probes of chromosomes 4 and 11 were applied to nuclei from spermatozoa and blastomeres from embryo biopsy. An independent X2 test was used to compare abnormal spermatozoa from the patient and the control. Two FISH analysis rounds were performed for the female IT carrier. Six specific probes of chromosomes 2 and 10 were applied to blastomeres of PGT embryos. Result(s): The sperm-FISH segregation analysis showed a significantly increased percentage
RBMO VOLUME 39 ISSUE s1 2019
73. SIMULTANEOUS PGT-M APPLICATIONS FOR MULTIPLE GENETIC CONDITIONS
S. Aktuna, E. Unsal, L. Ozer, M. Aydin, V. Baltaci Mikrogen Genetic Diagnosis Center, Ankara, Turkey
Introduciton: Pre-implantation genetic diagnosis for monogenic disorders (PGT-M) have been extensively applied for genetic conditions resulting from mutations at single genetic locus . Vast amount of data have arised from Whole Exom Sequencing (WES) and Whole Genome Sequencing (WGS) technologies it is not always straight forward to filter out the mutation responsible for the disorder. Furthermore consanguinity increases the risk of cooccurence of two or more etiologically different genetic diseases in a single family. For this reason increased number of patients referred to PGT-M applications started to demand simultaneous testing of multiple genetic disorders. Drastically some families referred for one condition later had further offsprings with additional single gene defects. We are reporting PGT-M application for two or more genetic conditions performed in our center. Materials and Methods: PGT-M was performed by testing blastocyst/ blastomere samples depending on the familial pathogenic variants. For this purpose biopsied cells were lysed and fragment analysis for haplotyping and sequence analysis for mutation detection have been performed following multiplex nested PCR. PGT-M testing was performed simultaneously for multiple genetic conditions in 17 couples. 6 infromative STR markers were used for each loci in addition to mutation site. Results: was performed for 17 couples and 36 disorders including (Beta Thallasemia, DMD, Glycogen storage disease, Mitochondrial complex I deficiency, Maple syrup
urine disease etc.) For 2 couples 3 different conditions were screened simultaneously. While 5 out 7 embryos was appropriate for transfer in one of these patients only 1 out of 8 embyos was transferable for the second case. For 15 couples where 2 conditions were screened 32 embryos out of 104 were appropriate for transfer. Embryo transfer was performed in all patients except for one patient who had only 1 embryo for . Conclusion: Insufficient information in databeses regarding the pathogenicity of variants for rare diseases leads to a difficults in counselling patients for PGT-M. Frequent use of WES/WGS for families has become an effective tool for detecting the mutations to enable PGT-M application for families without previous diagnosis of their affected child. Unfortunately in many cases unusal phenotypes in consangenous couples forces us to exclude all variants including variants of unknown significance (VUS) that may be associated with phenotype. This a challanging approach since PGT-M should be designed for each condition together with linked STR markers for each of them to achieve high confidence results. Additionally the more we try to exclude the less likely we will find an appropriate embryo for transfer and families should be informed of this possibility before consenting to PGT-M applications. Because of this delineation of VUS will enable us to interprete patients history and give more efficient counselling to PGT-M patients thus limiting the number of embryos excluded due to these variants. Keywords: Preimplantation Genetic Testing
for Monogenic/Single Gene Disorders; In Vitro Fertilization; Whole Exom Sequencing
doi: 10.1016/j.rbmo.2019.04.126
74. NORMAL LIVE BIRTH FROM TWO CARRIERS OF RARE INSERTIONAL TRANSLOCATIONS UNDERGOING PGT
I. Bernicot1, Z. Reda1, C. Cendrine1, E. Haquet2, N. Ranisavljevic3, T. Anahory3 1 Cytogenetic
PGD department, Arnaud De Villeneuve Hospital, Montpellier, Montpellier, France 2 Department of Medical Genetics, Arnaud De Villeneuve Hospital, Montpellier, Montpellier, France 3 ART-PGD Department, Arnaud De Villeneuve Hospital, Montpellier, Montpellier, France
Introduction: Despite the use of more precise techniques that indicates greater incidence, meiotic segregation of interchromosomal insertion has rarely been studied. Theoretically, the risk to have a child at term with malformation or mental retardation is high but there are no tools to determine this risk. We have investigated the Preimplantation genetic diagnosis (PGT) management of patients with interchromosomal insertion (IT) by fluorescent in situ hybridization (FISH) to obtain a better understanding and improve the genetic counseling. Material & methods: Two couples were enrolled in our PGT unit. The male of the first couple carries the IT 46,XY,ins(4;11)(q22;p12p13) and the female karyotype of the second couple is 46,XX,ins(2;10) (q21;q25.2q22). We have investigated, by FISH technique, the meiotic segregation analysis of the sperm of the IT male carrier and embryos providing from the two carriers. One FISH analysis round was performed for the male IT carrier. Five specific probes of chromosomes 4 and 11 were applied to nuclei from spermatozoa and blastomeres from embryo biopsy. An independent X2 test was used to compare abnormal spermatozoa from the patient and the control. Two FISH analysis rounds were performed for the female IT carrier. Six specific probes of chromosomes 2 and 10 were applied to blastomeres of PGT embryos. Result(s): The sperm-FISH segregation analysis showed a significantly increased percentage