Identification of mosaic and segmental aneuploidies by next-generation sequencing in preimplantation genetic screening can improve clinical outcomes compared to array-comparative genomic hybridization

Lai, Hsing-Hua; Chuang, Tsu-Hwang; Wong, Lin-Kin; Lee, Meng-Ju; Hsieh, Chu‐Chin; Wang, Huai-Lin; Chen, Shee‐Uan

doi:10.1186/s13039-017-0315-7

Cited by 57 publications

(35 citation statements)

References 46 publications

(57 reference statements)

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“…The authors suggested that NGS detects mosaicism and triploidy better than aCGH, and this improvement in detection might have a positive impact on the clinical outcomes by decreasing the incidence of miscarriage (Maxwell et al 2016). The superiority of NGS for the detection of mosaicism has been supported by another study where there were 6.7% in overall inconsistencies of mosaicism between two methods (Lai et al 2017), NGS detected those not identified by aCGH. On the other hand, settings with a customized analysis software with a high specificity of detection of mosaicism might nonetheless pose a potential risk of overdiagnosing euploid embryos as mosaic.…”

Section: Next-generation Sequencingmentioning

confidence: 81%

Chromosomal analysis in IVF: just how useful is it?

Griffin

Oğur²

2018

Reproduction

104

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Designed to minimize chances of genetically abnormal embryos, preimplantation genetic diagnosis (PGD) involves fertilization (IVF), embryo biopsy, diagnosis and selective embryo transfer. Preimplantation genetic testing for aneuploidy (PGT-A) aims to avoid miscarriage and live born trisomic offspring and to improve IVF success. Diagnostic approaches include fluorescence hybridization (FISH) and more contemporary comprehensive chromosome screening (CCS) including array comparative genomic hybridization (aCGH), quantitative polymerase chain reaction (PCR), next-generation sequencing (NGS) and karyomapping. NGS has an improved dynamic range, and karyomapping can detect chromosomal and monogenic disorders simultaneously. Mosaicism (commonplace in human embryos) can arise by several mechanisms; those arising initially meiotically (but with a subsequent post-zygotic 'trisomy rescue' event) usually lead to adverse outcomes, whereas the extent to which mosaics that are initially chromosomally normal (but then arise purely post-zygotically) can lead to unaffected live births is uncertain. Polar body (PB) biopsy is the least common sampling method, having drawbacks including cost and inability to detect any paternal contribution. Historically, cleavage-stage (blastomere) biopsy has been the most popular; however, higher abnormality levels, mosaicism and potential for embryo damage have led to it being superseded by blastocyst (trophectoderm - TE) biopsy, which provides more cells for analysis. Improved biopsy, diagnosis and freeze-all strategies collectively have the potential to revolutionize PGT-A, and there is increasing evidence of their combined efficacy. Nonetheless, PGT-A continues to attract criticism, prompting questions of when we consider the evidence base sufficient to justify routine PGT-A? Basic biological research is essential to address unanswered questions concerning the chromosome complement of human embryos, and we thus entreat companies, governments and charities to fund more. This will benefit both IVF patients and prospective parents at risk of aneuploid offspring following natural conception. The aim of this review is to appraise the 'state of the art' in terms of PGT-A, including the controversial areas, and to suggest a practical 'way forward' in terms of future diagnosis and applied research.

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Section: Next-generation Sequencingmentioning

confidence: 81%

Chromosomal analysis in IVF: just how useful is it?

Griffin

Oğur²

2018

Reproduction

104

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“…6 in [1]). In humans, about 1% of all pregnancies include some form of deviation from normal diploidy [25], and chromosomal deletions of embryonic malformations data revealed that about 11% of the genome has never been recovered in the haploid condition or any other copy number variation [26][27][28][29]. Although small deletions in human genomes are recognized as largely underestimated [30], segmental aneuploidies have been identified in oocytes, 10.4%, raising to 24.3% by three days of embryogenesis, and declining to 15.6% in preimplantation blastocysts [31].…”

Section: Introductionmentioning

confidence: 99%

The haplolethality paradox of thewupAgene inDrosophila

Casas‐Tintó

Ferrús

2020

Preprint

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Haplolethals (HL) are regions of diploid genomes that in one dose are fatal for the organism. Their biological meaning is obscure, given that heterozygous loss-of-function mutations will result in dominant lethality and, consequently, should be under strong negative selection. In addition, their biological nature is under debate: a chromosomal structure that is essential for the expression of several genes (regulatory hypothesis), or the strict dosage requirement of one particular gene (functional hypothesis). We report the first in depth study of an haplolethal region, the one associated to the Drosophila gene wings up A (wupA). It encodes 13 transcripts (A-M) that yield 11 protein isoforms (A-K) of Troponin I (TnI). They are functionally diverse in their control of muscle contraction, cell polarity and cell proliferation. Isoform K can transfer to the nucleus where it increases the transcription of the cell proliferation related genes CDK2, CDK4, Rap and Rab5. The nuclear translocation of isoform K is prevented by the co-expression of A or B isoforms, which illustrates isoform interactions. The corresponding dominant lethal mutations (DL) result from DNA rearrangements, clustered in the intron between exons 7-8, and affect the genomic organization of all transcripts. The joint elimination of isoforms C, F, G and H, however, do not cause DL phenotypes. Genetically driven expression of single isoforms rescue neither DL nor any of the mutants known in the gene, suggesting that normal function of wupA requires the properly regulated expression of specific combinations, rather than single, TnI isoforms along development. We conclude that the HL function at wupA results from the combined haploinsufficiency of a large set of TnI isoforms. The qualitative and quantitative normal expression of which, requires the chromosomal integrity of the wupA genomic region. Since all fly TnI isoforms are encoded in the same gene, its HL condition becomes unavoidable.Author summaryMost species contain two copies of their genetic endowment, each received from their progenitors. If one of the duplicated genes is non-functional, due to either null mutations or genomic loss, the remaining gene copy may supply enough product as to cover the requirements for normal function or, alternatively, may reflect the insufficiency through a visible phenotype. In rare occasions, however, mutation in one copy is so deleterious that causes lethality, usually at early stages of development. These so called “haplolethal regions”, exist across species and represent an evolutionary paradox since they should have been subject to intense negative selection. The inherent difficulties to study haplolethals have precluded their study so far. Here, we analyzed the case of one of the five haplolethal regions of Drosophila, the one associated to the Troponin I encoding gene wupA, by measuring the transcriptional effects of mutations and chromosomal rearrangements affecting this gene. The data show that haplolethality results from the combined insufficiency of a large number of Troponin I isoforms, which are functionally specialized, show interference and require the integrity of the native chromatin structure for their quantitatively regulated expression. These features unveil novel aspects of gene expression and, possibly, on evolutionary gene splitting.

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“…At 5-15%, complex systems are required to handle the imputation and when >15%, the estimation will be strongly affected. Several explanations have been given for the occurrence of MVs and most of them involve the presence of artifacts, hybridization failures, and low-resolution on the microarray [8].…”

Section: Introductionmentioning

confidence: 99%

An Examination of Machine Learning Algorithms for Missing Values Imputation

2019

IJITEE

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In gene expression studies missing values have been a common problem. It has an important consequence on the explanation of the final data. Numerous Bioinformatics examination tools that are used for cancer prediction includes the dataset matrix. Hence, it is necessary to resolve this problem of missing values imputation. Our research paper presents a review of missing values imputation approaches. It represents the research and imputation of missing values in gene expression data. By using the local or global correlation of the data we focus mostly on the contrast of the algorithms. We considered the algorithms in a global, hybrid, local, and knowledge-based technique. Additionally, we presented the different approaches with a suitable assessment. The purpose of our review article is to focus on the developments of current techniques. For scientists rather applying different or newly develop algorithms with the identical functional goal. We want an adaptation of algorithms to the characteristics of the data".

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Identification of mosaic and segmental aneuploidies by next-generation sequencing in preimplantation genetic screening can improve clinical outcomes compared to array-comparative genomic hybridization

Cited by 57 publications

References 46 publications

Chromosomal analysis in IVF: just how useful is it?

Chromosomal analysis in IVF: just how useful is it?

The haplolethality paradox of thewupAgene inDrosophila

An Examination of Machine Learning Algorithms for Missing Values Imputation

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