De Witte Lisa, Baetens Machteld, Tilleman Kelly, Vanden Meerschaut Frauke, Janssens Sandra, Van Tongerloo Ariane, Szymczak Virginie, Stoop Dominic, Dheedene Annelies, Symoens Sofie, Menten Björn
Center for Medical Genetics, Department of Biomolecular Medicine, Ghent University, Ghent, Belgium.
Center for Medical Genetics, Ghent University Hospital, Ghent, Belgium.
Hum Reprod Open. 2024 Sep 18;2024(4):hoae056. doi: 10.1093/hropen/hoae056. eCollection 2024.
To what extent can genotype analysis aid in the classification of (mosaic) aneuploid embryos diagnosed through copy number analysis of a trophectoderm (TE) biopsy?
In a small portion of embryos, genotype analysis revealed signatures of meiotic or uniform aneuploidy in those diagnosed with intermediate copy number changes, and signatures of presumed mitotic or putative mosaic aneuploidy in those diagnosed with full copy number changes.
Comprehensive chromosome screening (CCS) for preimplantation genetic testing has provided valuable insights into the prevalence of (mosaic) chromosomal aneuploidy at the blastocyst stage. However, diagnosis of (mosaic) aneuploidy often relies solely on (intermediate) copy number analysis of a single TE biopsy. Integrating genotype information allows for independent assessment of the origin and degree of aneuploidy. Yet, studies aligning both datasets to predict (putative mosaic) aneuploidy in embryos remain scarce.
A single TE biopsy was collected from 1560 embryos derived from 221 couples tested for a monogenic disorder (n = 218) or microdeletion-/microduplication syndrome (n = 3). TE samples were subjected to both copy number and genotyping analysis.
PARTICIPANTS/MATERIALS SETTING METHODS: Copy number and SNP genotyping analysis were conducted using GENType. Unbalanced chromosomal anomalies ≥10 Mb (or ≥20 Mb for copy number calls <50%) were classified by degree, based on low-range intermediate (LR, 30-50%), high-range intermediate (HR, 50-70%) or full (>70%) copy number changes. These categories were further subjected to genotyping analysis to ascertain the origin (and/or degree) of aneuploidy. For chromosomal gains, the meiotic division of origin (meiotic I/II versus non-meiotic or presumed mitotic) was established by studying the haplotypes. The level of monosomy (uniform versus putative mosaic) in the biopsy could be ascertained from the B-allele frequencies. For segmental aneuploidies, genotyping was restricted to deletions.
Of 1479 analysed embryos, 24% (n = 356) exhibited a whole-chromosome aneuploidy, with 19% (n = 280) showing full copy number changes suggestive of uniform aneuploidy. Among 258 embryos further investigated by genotyping, 95% of trisomies with full copy number changes were identified to be of meiotic origin. For monosomies, a complete loss of heterozygosity (LOH) in the biopsy was observed in 97% of cases, yielding a 96% concordance rate at the embryo level (n = 248/258). Interestingly, 4% of embryos (n = 10/258) showed SNP signatures of non-meiotic gain or putative mosaic loss instead. Meanwhile, 5% of embryos (n = 76/1479) solely displayed HR (2.5%; n = 37) or LR (2.6%; n = 39) intermediate copy number changes, with an additional 2% showing both intermediate and full copy number changes. Among embryos with HR intermediate copy number changes where genotyping was feasible (n = 25/37), 92% (n = 23/25) showed SNP signatures consistent with putative mosaic aneuploidy. However, 8% (n = 2/25) exhibited evidence of meiotic trisomy (9%) or complete LOH in the biopsy (7%). In the LR intermediate group, 1 of 33 (3%) genotyped embryos displayed complete LOH. Furthermore, segmental aneuploidy was detected in 7% of embryos (n = 108/1479) (or 9% (n = 139) with added whole-chromosome aneuploidy). These errors were often (52%) characterized by intermediate copy number values, which closely aligned with genotyping data when examined (94-100%).
N/A.
The findings were based on single TE biopsies and the true extent of mosaicism was not validated through embryo dissection. Moreover, evidence of absence of a meiotic origin for a trisomy should not be construed as definitive proof of a mitotic error. Additionally, a genotyping diagnosis was not always attainable due to the absence of a recombination event necessary to discern between meiotic II and non-meiotic trisomy, or the unavailability of DNA from both parents.
Interpreting (intermediate) copy number changes of a single TE biopsy alone as evidence for (mosaic) aneuploidy in the embryo remains suboptimal. Integrating genotype information alongside the copy number status could provide a more comprehensive assessment of the embryo's genetic makeup, within and beyond the single TE biopsy. By identifying meiotic aberrations, especially in presumed mosaic embryos, we underscore the potential value of genotyping analysis as a deselection tool, ultimately striving to reduce adverse clinical outcomes.
STUDY FUNDING/COMPETING INTERESTS: L.D.W. was supported by the Research Foundation Flanders (FWO; 1S74621N). M.B., K.T., F.V.M., S.J., A.V.T., V.S., D.S., A.D., and S.S. are supported by Ghent University Hospital. B.M. was funded by Ghent University. The authors have no conflicts of interest.
通过对滋养外胚层(TE)活检进行拷贝数分析诊断出的(嵌合)非整倍体胚胎,基因型分析在多大程度上有助于其分类?
在一小部分胚胎中,基因型分析在那些被诊断为拷贝数有中等变化的胚胎中揭示了减数分裂或均匀非整倍体的特征,在那些被诊断为拷贝数完全变化的胚胎中揭示了推测的有丝分裂或假定的嵌合非整倍体的特征。
用于植入前基因检测的全面染色体筛查(CCS)为囊胚期(嵌合)染色体非整倍体的发生率提供了有价值的见解。然而,(嵌合)非整倍体的诊断通常仅依赖于对单个TE活检进行(中等)拷贝数分析。整合基因型信息可以独立评估非整倍体的起源和程度。然而,将两个数据集结合起来预测胚胎中的(假定嵌合)非整倍体的研究仍然很少。
研究设计、规模、持续时间:从221对夫妇的1560个胚胎中收集了单个TE活检样本,这些夫妇接受了单基因疾病检测(n = 218)或微缺失/微重复综合征检测(n = 3)。对TE样本进行了拷贝数和基因分型分析。
参与者/材料、设置、方法:使用GENType进行拷贝数和单核苷酸多态性(SNP)基因分型分析。不平衡染色体异常≥10 Mb(对于拷贝数调用<50%,则为≥20 Mb)根据低范围中等(LR,30 - 50%)、高范围中等(HR,50 - 70%)或完全(>70%)拷贝数变化进行程度分类。这些类别进一步进行基因分型分析,以确定非整倍体的起源(和/或程度)。对于染色体增加,通过研究单倍型确定起源的减数分裂(减数分裂I/II与非减数分裂或推测的有丝分裂)。活检中单体性的水平(均匀与假定嵌合)可以从B等位基因频率确定。对于节段性非整倍体,基因分型仅限于缺失。
在1479个分析的胚胎中,24%(n = 356)表现出全染色体非整倍体,其中19%(n = 280)显示出完全拷贝数变化,提示均匀非整倍体。在通过基因分型进一步研究的258个胚胎中,95%拷贝数完全变化的三体被确定为减数分裂起源。对于单体性,97%的病例在活检中观察到杂合性完全丧失(LOH),在胚胎水平的一致性率为96%(n = 248/258)。有趣的是,4%的胚胎(n = 10/258)显示出非减数分裂增加或假定嵌合缺失的SNP特征。同时,5%的胚胎(n = 76/1479)仅表现出HR(2.5%;n = 37)或LR(2.6%;n = 39)中等拷贝数变化,另外2%表现出中等和完全拷贝数变化。在HR中等拷贝数变化且可行基因分型的胚胎中(n = 25/37),92%(n = 23/25)显示出与假定嵌合非整倍体一致的SNP特征。然而,8%(n = 2/25)在活检中表现出减数分裂三体的证据(9%)或完全LOH(7%)。在LR中等组中,33个基因分型胚胎中的1个(3%)显示出完全LOH。此外,7%的胚胎(n = 108/1479)检测到节段性非整倍体(或9%(n = 139)伴有全染色体非整倍体)。这些错误通常(52%)以中等拷贝数值为特征,在检查时与基因分型数据密切一致(94 - 100%)。
无。
局限性、谨慎的原因:研究结果基于单个TE活检,且嵌合的真实程度未通过胚胎解剖进行验证。此外,三体无减数分裂起源的证据不应被视为有丝分裂错误的确凿证据。此外,由于缺乏区分减数分裂II和非减数分裂三体所需的重组事件,或者无法获得双亲的DNA,并非总是能够进行基因分型诊断。
仅将单个TE活检的(中等)拷贝数变化解释为胚胎中(嵌合)非整倍体的证据仍然不够理想。将基因型信息与拷贝数状态相结合,可以在单个TE活检内外对胚胎的基因组成进行更全面的评估。通过识别减数分裂异常,特别是在假定的嵌合胚胎中,我们强调了基因分型分析作为一种筛选工具的潜在价值,最终致力于减少不良临床结果。
研究资金/利益冲突:L.D.W. 得到了弗拉芒研究基金会(FWO;1S74621N)的支持。M.B.、K.T.、F.V.M.、S.J.、A.V.T.、V.S.、D.S.、A.D. 和 S.S. 得到了根特大学医院的支持。B.M. 由根特大学资助。作者没有利益冲突。
