Ingrid Lai scite author profile

Cytoplasmic transfer is an assisted reproductive technique that involves the infusion of ooplasm from a donor oocyte into a recipient oocyte of inferior developmental competence. Although this technique has shown some success for couples with recurrent in vitro fertilization failure, it results in mitochondrial heteroplasmy in the offspring, defined as the presence of two different mitochondrial genomes in the same individual. Because the long-term health consequences of mitochondrial heteroplasmy are unknown, there is a need for appropriate animal models to evaluate any physiological changes of dual mtDNA genotypes. This longitudinal study was designed as a preliminary screen of basic physiological functions for heteroplasmic mice (NZB mtDNA on a BALB/cByJ background). The mice were tested for cardiovascular and metabolic function, hematological parameters, body mass analysis, ovarian reserve, and tissue histologic abnormalities over a period of 15 mo. Heteroplasmic mice developed systemic hypertension that corrected over time and was accompanied by cardiac changes consistent with pulmonary hypertension. In addition, heteroplasmic animals had increased body mass and fat mass compared with controls at all ages. Finally, these animals had abnormalities in electrolytes and hematological parameters. Our findings suggest that there are significant physiological differences between heteroplasmic and control mice. Because ooplasm transfer appears to be consistently associated with mitochondrial heteroplasmy, children conceived through ooplasm transfer should be closely followed to determine if they are at risk for any health problems.

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Automated Microinjection of Recombinant BCL-X into Mouse Zygotes Enhances Embryo Development

Liu

Fernandes

Gertsenstein

et al. 2011

PLoS ONE

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Progression of fertilized mammalian oocytes through cleavage, blastocyst formation and implantation depends on successful implementation of the developmental program, which becomes established during oogenesis. The identification of ooplasmic factors, which are responsible for successful embryo development, is thus crucial in designing possible molecular therapies for infertility intervention. However, systematic evaluation of molecular targets has been hampered by the lack of techniques for efficient delivery of molecules into embryos. We have developed an automated robotic microinjection system for delivering cell impermeable compounds into preimplantation embryos with a high post-injection survival rate. In this paper, we report the performance of the system on microinjection of mouse embryos. Furthermore, using this system we provide the first evidence that recombinant BCL-XL (recBCL-XL) protein is effective in preventing early embryo arrest imposed by suboptimal culture environment. We demonstrate that microinjection of recBCL-XL protein into early-stage embryos repairs mitochondrial bioenergetics, prevents reactive oxygen species (ROS) accumulation, and enhances preimplantation embryo development. This approach may lead to a possible treatment option for patients with repeated in vitro fertilization (IVF) failure due to poor embryo quality.

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Developmental consequences of alternative Bcl‐x splicing during preimplantation embryo development

et al. 2010

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Elevated cell death in human preimplantation embryos is one of the cellular events compromising pregnancy rates after assisted reproductive technology treatments. We therefore explored the molecular pathways regulating cell death at the blastocyst stage in human embryos cultured in vitro. Owing to limited availability of human embryos, these pathways were further characterized in mouse blastocysts. Gene expression studies revealed a positive correlation between the cell death index and the expression of Bcl‐x transcript. Cell death activation in human blastocysts was accompanied by changes in Bcl‐x splicing, favoring production of Bcl‐xS, an activator of cell death. Expression of Bcl‐xS was detected in a subset of human blastocysts that show particular clustering in dying and/or dead cells. Altering the Bcl‐xL/Bcl‐xS ratio in mouse embryos, in antisense experiments, confirmed that upregulation of Bcl‐xS, with concomitant downregulation of Bcl‐xL, compromised developmental potential and committed a subset of cells to undergoing cell death. This was accompanied by increased accumulation of reactive oxygen species levels without any impact on mtDNA content. In addition, altered Bcl‐x splicing in favor of Bcl‐xS was stimulated by culture in HTF medium or by addition of excessive glucose, leading to compromised embryo development. Thus, we conclude that inappropriate culture conditions affect Bcl‐x isoform expression, contributing to compromised preimplantation embryo development.

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Ingrid Lai

Neutral Mitochondrial Heteroplasmy Alters Physiological Function in Mice1

Automated Microinjection of Recombinant BCL-X into Mouse Zygotes Enhances Embryo Development

Developmental consequences of alternative Bcl‐x splicing during preimplantation embryo development

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