Genome constraint through sexual reproduction: application of 4D-Genomics in reproductive biology

Assisted reproductive technologies have been used to achieve pregnancies since the first successful test tube baby was born in 1978. Infertile couples are at an increased risk for multiple miscarriages and the application of current protocols are associated with high first-trimester miscarriage rate...

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Bibliographic Details
Published in:Systems biology in reproductive medicine 2013-06, Vol.59 (3), p.124-130
Main Authors: Horne, Steven D., Abdallah, Batoul Y., Stevens, Joshua B., Liu, Guo, Ye, Karen J., Bremer, Steven W., Heng, Henry H.Q.
Format: Article
Language:English
Subjects:
4D-Genomics
Aneuploidy
Animals
assisted reproductive technologies
Chromosome Aberrations
Developmental Biology - methods
Female
Gene Regulatory Networks
Genetic Testing
genome theory
Genome, Human
Genomic Instability
Genomics - methods
Humans
Infertility - genetics
Infertility - physiopathology
Infertility - therapy
Karyotyping
Male
Models, Genetic
Pregnancy
Pregnancy Outcome
Prenatal Diagnosis
Reproduction - genetics
Reproductive Techniques, Assisted - adverse effects
sexual reproduction
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Summary:Assisted reproductive technologies have been used to achieve pregnancies since the first successful test tube baby was born in 1978. Infertile couples are at an increased risk for multiple miscarriages and the application of current protocols are associated with high first-trimester miscarriage rates. Among the contributing factors of these higher rates is a high incidence of fetal aneuploidy. Numerous studies support that protocols including ovulation-induction, sperm cryostorage, density-gradient centrifugation, and embryo culture can induce genome instability, but the general mechanism is less clear. Application of the genome theory and 4D-Genomics recently led to the establishment of a new paradigm for sexual reproduction; sex primarily constrains genome integrity that defines the biological system rather than just providing genetic diversity at the gene level. We therefore propose that application of assisted reproductive technologies can bypass this sexual reproduction filter as well as potentially induce additional system instability. We have previously demonstrated that a single-cell resolution genomic approach, such as spectral karyotyping to trace stochastic genome level alterations, is effective for pre- and post-natal analysis. We propose that monitoring overall genome alteration at the karyotype level alongside the application of assisted reproductive technologies will improve the efficacy of the techniques while limiting stress-induced genome instability. The development of more single-cell based cytogenomic technologies are needed in order to better understand the system dynamics associated with infertility and the potential impact that assisted reproductive technologies have on genome instability. Importantly, this approach will be useful in studying the potential for diseases to arise as a result of bypassing the filter of sexual reproduction.
ISSN:1939-6368
1939-6376
DOI:10.3109/19396368.2012.754969