Role of Mitochondria Transfer in Infertility: A Commentary
Abstract
:1. Introduction
2. Heterologous Mitochondria Transfer
2.1. Ooplasmic Transfer (Cytotransfer)
2.2. Nuclear Transfer
2.2.1. Germinal Vesicle Transfer
2.2.2. Spindle Transfer
2.2.3. Pronuclear Transfer
2.2.4. Polar Body Transfer
3. Autologous Mitochondria Transfer
3.1. Ovarian Stem Cells
3.2. Immature Oocytes
3.3. Granulosa Cells
3.4. Non-Ovarian Stem Cells
4. Discussion
5. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Acknowledgments
Conflicts of Interest
References
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Study Name | Type of Mitochondria Transfer | n | Patients’ Etiology | Main Outcome |
---|---|---|---|---|
Cohen, 1997 [15] | Ooplasmic transfer | 1 patient | History of impaired embryo development | First human birth using this approach |
Cohen, 1998 [13] | 8 cycles | Repeated implantation failure | Improved results using the injection technique vs. electrofusion. One healthy infant and ongoing pregnancy in the injection group (total n = 5) vs. no pregnancy in the electrofusion group (n = 3) | |
Brenner, 2000 [16] | 23 cycles | Twelve clinical pregnancies and overall improved embryo development. Proven mtDNA heteroplasmy in the offspring. | ||
Huang, 1999 [17] | 9 cycles | Five healthy infants after ooplasmic transfer from tripronucleated zygotes | ||
Dale, 2001 [18] | 1 patient | Birth of healthy twins | ||
Chen, 2016 [19] | 33 cycles | Follow-up study of 17 healthy infants from 13 couples [13,15,16]. Limited study with high bias, but overall unaffected healthy offspring. | ||
Sobek, 2021 [20] | 125 cycles Ooplasmic transfer vs. control in sibling oocytes | Low ovarian function | Increased fertilization and embryo development rates. A reduction in fertilization rates with age was observed in the control group but not in the ooplasmic transfer group. 28 healthy infants in the ooplasmic transfer group. | |
Zhang, 1999 [21] | GV transfer | 60 GVs | Advanced maternal age | 12 GVs were successfully removed, transferred, and fused into previously enucleated oocytes from young patients. 7 of these matured to a metaphase II oocyte, similar maturation rate to the non-manipulated GVs. |
Darbandi, 2020 [22] | 10 GVs | 0% fusion rate | ||
Tanaka, 2009 [23] | Spindle transfer | 31 MII spindle transfer group 98 MII control group | In vitro matured MII oocytes (model of aged oocytes) | 25/31 correctly fused (80.6%). Significantly higher number of oocytes developed to the blastocyst stage in the spindle transfer group (7 vs. 3 in the control group). |
Zhang, 2017 [24] | 1 patient | History of pregnancy loss and asymptomatic carrier of a Leigh syndrome mutation | First human birth after spindle transfer | |
Costa-Borges, 2020 [25] | 9 cycles | Age range 32–40 years. History of embryo developmental arrest | Preliminary results from a larger pilot study (n = 25). Applied successfully in 39/44 oocytes (88.6%). Of these, 76.9% (30/39) fertilized and 20 developed into good quality blastocysts (66.7%). Genetic analysis revealed 35% (7/20) of the embryos to be euploid and mtDNA carryover levels <1%. Two blastocysts were warmed and transferred, resulting in two pregnancies. | |
Craven, 2010 [3] | PN transfer | 80 uni- and tripronucleated zygotes with PN transfer vs. 76 unmanipulated control group | Transfer of PN from abnormally fertilized zygotes discarded from IVF cycles | First PN transfer attempt in humans. Minimal mtDNA carryover and compatible with onward development to the blastocyst stage. |
Hyslop, 2016 [26] | 523 MII | MII donated oocytes fertilized with donated sperm | Alternative approach based on transplanting pronuclei shortly after completion of meiosis rather than shortly before the first mitotic division. mtDNA carryover below 2%. Efficient development to the blastocyst stage with no detectable effect on aneuploidy or gene expression. | |
Zhang, 2016 [27] | 1 patient | History of embryo developmental arrest | Viable pregnancy with normal karyotype and minimal mtDNA heteroplasmy | |
Ma, 2017 [28] | PB1 transfer | 32 oocytes in PB1T group vs. 21 in the control group 11 women | Healthy volunteers | Oocytes supported the formation of de novo meiotic spindles and, after fertilization with sperm, meiosis completion and formation of normal diploid zygotes. Lower blastocyst formation rates in the PB1T group in comparison to the control group |
Zhang, 2017 [29] | PB1 and PB2 transfer | 1 patient | Repeated embryo fragmentation of maternal origin | PB1T but not PB2T into enucleated in vitro matured donor MII oocytes successfully generate normal fertilized zygotes with high efficiency for developing into blastocysts |
Tang, 2019 [30] | PB2 transfer | 134 oocytes | In vitro matured oocytes and in vivo matured oocytes with smooth endoplasmic reticulum aggregate, both donated from young women | Novel strategy for PB2 transfer. Unaltered blastocyst quality in the PB2T and control groups and similar euploidy rates |
Study Name | Type of Mitochondria Transfer | n | Patients’ Etiology | Main Outcome |
---|---|---|---|---|
Fakih, 2015 [43] | Ovarian stem cells (AUGMENT®) | 59 + 34 patients (2 different clinics) | Poor oocyte and embryo quality | Poor study design with high bias. Increased pregnancy rates in comparison to the historic IVF success rates in the same patients |
Oktay, 2015 [44] | 16 patients | 2 or more previous IVF attempts failure, and poor oocyte and embryo quality | Poor study design with high bias. Higher fertilization rates (78.3% vs. 47.9%; p = 0.036) and better embryo quality (3.1% vs. 2.3%; p = 0.082) than the results obtained in previous cycles from the same patients. | |
Labarta, 2019 [42] | 57 patients | Previous IVF failures and well-documented poor embryo quality | Intrapatient and intracycle comparison design. Significantly lower day 5 blastocyst formation rate in the AUGMENT group. No statistically significant differences in any other variable studied. | |
Kong, 2004 [41] | Granulosa cells | 18 patients | A previous failed IVF treatment or order than 37 years | Similar fertilization rates (74.4% vs. 76.8% in the control group; p > 0.05). Significantly higher good quality embryo rate in mitochondria transfer group (59.4% vs. 34.9% in the control group; p < 0.05). There were 7 clinical pregnancies in the 18 cases. |
Tzeng, 2004 [45] | 71 cycles vs. 81 historic cycles in the same patient group | A previous failed IVF treatment | Significantly higher pregnancy rates (35.2% vs. 6.2% in the historic control group; p < 0.05) and lower miscarriage rates (15.4% vs. 100% in the historic control group; p < 0.05). Significantly higher day 3 embryo quality. Twenty live births. Oocytes following this technique had a propensity to cleave faster, as well as lower apoptosis and fragmentation rates. |
Type of Mitochondria Transfer | Clinically Used in Infertile Patients (Yes/No) | Has Showed Promising Results (Yes/No) | Live Birth/s (Yes/No) |
---|---|---|---|
Ooplasmic transfer | Yes | Yes | Yes |
Germinal vesicle transfer | Yes | Yes | No |
Spindle transfer | Yes | Yes | Yes |
Pronuclear transfer | Yes | Yes | Yes |
First polar body transfer | Yes | Yes | No |
Second polar body transfer | Yes | No | No |
Ovarian stem cells | Yes | No | Yes |
Immature oocytes | No | - | - |
Granulosa cells | Yes | Yes | Yes |
Non-ovarian stem cells | No | - | - |
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Rodríguez-Varela, C.; Labarta, E. Role of Mitochondria Transfer in Infertility: A Commentary. Cells 2022, 11, 1867. https://doi.org/10.3390/cells11121867
Rodríguez-Varela C, Labarta E. Role of Mitochondria Transfer in Infertility: A Commentary. Cells. 2022; 11(12):1867. https://doi.org/10.3390/cells11121867
Chicago/Turabian StyleRodríguez-Varela, Cristina, and Elena Labarta. 2022. "Role of Mitochondria Transfer in Infertility: A Commentary" Cells 11, no. 12: 1867. https://doi.org/10.3390/cells11121867
APA StyleRodríguez-Varela, C., & Labarta, E. (2022). Role of Mitochondria Transfer in Infertility: A Commentary. Cells, 11(12), 1867. https://doi.org/10.3390/cells11121867