Compromised fertility disrupts Peg1 but not Snrpn and Peg3 imprinted methylation acquisition in mouse oocytes

doi:10.3389/fgene.2012.00129

. 2012 Jul 11:3:129.

doi: 10.3389/fgene.2012.00129. eCollection 2012.

Compromised fertility disrupts Peg1 but not Snrpn and Peg3 imprinted methylation acquisition in mouse oocytes

Michelle M Denomme¹, Carlee R White, Carolina Gillio-Meina, William A Macdonald, Bonnie J Deroo, Gerald M Kidder, Mellissa R W Mann

Affiliations

PMID: 22798963
PMCID: PMC3394371
DOI: 10.3389/fgene.2012.00129

Compromised fertility disrupts Peg1 but not Snrpn and Peg3 imprinted methylation acquisition in mouse oocytes

Michelle M Denomme et al. Front Genet. 2012.

. 2012 Jul 11:3:129.

doi: 10.3389/fgene.2012.00129. eCollection 2012.

Authors

Michelle M Denomme¹, Carlee R White, Carolina Gillio-Meina, William A Macdonald, Bonnie J Deroo, Gerald M Kidder, Mellissa R W Mann

Affiliation

¹ Children's Health Research Institute, London, ON, Canada.

PMID: 22798963
PMCID: PMC3394371
DOI: 10.3389/fgene.2012.00129

Abstract

Growth and maturation of healthy oocytes within follicles requires bidirectional signaling and intercellular gap junctional communication. Aberrant endocrine signaling and loss of gap junctional communication between the oocyte and granulosa cells leads to compromised folliculogenesis, oocyte maturation, and oocyte competency, consequently impairing fertility. Given that oocyte-specific DNA methylation establishment at imprinted genes occurs during this growth phase, we determined whether compromised endocrine signaling and gap junctional communication would disrupt de novo methylation acquisition using ERβ and connexin37 genetic models. To compare mutant oocytes to control oocytes, DNA methylation acquisition was first examined in individual, 20-80 μm control oocytes at three imprinted genes, Snrpn, Peg3, and Peg1. We observed that each gene has its own size-dependent acquisition kinetics, similar to previous studies. To determine whether compromised endocrine signaling and gap junctional communication disrupted de novo methylation acquisition,individual oocytes from Esr2- and Gja4-deficient mice were also assessed for DNA methylation establishment. We observed no aberrant or delayed acquisition of DNA methylation at Snrpn, Peg3, or Peg1 in oocytes from Esr2-deficient females, and no perturbation in Snrpn or Peg3de novo methylation in oocytes from Gja4-null females. However, Gja4 deficiency resulted in a loss or delay in methylation acquisition at Peg1. One explanation for this difference between the three loci analyzed is the late establishment of DNA methylation at the Peg1 gene. These results indicate that compromised fertility though impaired intercellular communication can lead to imprinting acquisition errors. Further studies are required to determine the effects of subfertility/infertility originating from impaired signaling and intercellular communication during oogenesis on imprint maintenance during preimplantation development.

Keywords: DNA methylation; connexin37; estrogen receptor beta; genomic imprinting; imprint acquisition; infertility; oocyte; oocyte diameter.

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Figures

**FIGURE 1**
**Methylation analysis of the *Snrpn* ICR in individual oocytes derived from control C57BL/6 female mice.** The *Snrpn* ICR region analyzed contains 16 CpGs. Black circles indicate methylated CpGs while white circles indicate unmethylated CpGs. Each row represents an individual oocyte (designation indicated to the left). Methylation percentage and diameter for each oocyte is shown at the right. Oocytes are grouped into cohorts ranging from 20 to 80 μm diameters in 5 μm increments. Oocytes with one methylation pattern represent one of the two parental alleles detected. Oocytes with two methylation patterns represent detection of both parental alleles.

**FIGURE 2**
**Methylation percentage of each parental allele at the *Snrpn* ICR in relation to oocyte diameter (μm).** For oocytes with two parental alleles, each allele was graphed separately. Blue diamonds represent oocytes from control females, red circles represent oocytes from *Esr2*^–/– females, and green triangles represent oocytes from *Gja4*^–/– females.

**FIGURE 3**
**Methylation analysis of the *Peg3* DMR in individual oocytes derived from control C57BL/6 females.** The *Peg3* DMR region analyzed contains 23 CpGs. Details are described in **Figure 1**.

**FIGURE 4**
**Methylation percentage of each parental allele at the *Peg3* DMR in relation to oocyte diameter (μm).** Oocytes from control females, *Esr2*^–/– females and *Gja4*^–/– females are represented by blue diamonds, red circles and green triangles, respectively.

**FIGURE 5**
**Methylation analysis of the *Peg1* DMR in individual oocytes derived from the control C57BL/6 mice.** The *Peg1* DMR region analyzed contains 15 CpGs. Details are described in **Figure 1**.

**FIGURE 6**
**Methylation percentage of each parental allele at the *Peg1* DMR in relation to oocyte diameter (μm).** Oocytes from control females, *Esr2*^–/– females and *Gja4*^–/– females are represented by blue diamonds, red circles and green triangles, respectively.

**FIGURE 7**
**Methylation analysis of the *Snrpn* ICR in individual oocytes derived from *Esr2*^–/– females.** Details are described in **Figure 1**.

**FIGURE 8**
**Methylation analysis of the *Peg3* DMR in individual oocytes derived from *Esr2*^–/– mice.** Details are described in **Figure 1**.

**FIGURE 9**
**Methylation analysis of the *Peg1* DMR individual oocytes derived from *Esr2*^–/– female mice.** Details are described in **Figure 1**.

**FIGURE 10**
**Methylation analysis of the *Snrpn* ICR in individual oocytes derived from *Gja4*^–/– mice.** Details are described in **Figure 1**.

**FIGURE 11**
**Methylation analysis of the *Peg3* DMR individual GV oocytes derived from *Gja4*^–/– female mice.** Details are described in **Figure 1**.

**FIGURE 12**
**Methylation analysis of the *Peg1* DMR individual GV oocytes derived from *Gja4*^–/– females.** Details are described in **Figure 1**.

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References

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1. Anckaert E., Romero S., Adriaenssens T., Smitz J. (2010). Effects of low methyl donor levels in culture medium during mouse follicle culture on oocyte imprinting establishment. Biol. Reprod. 83 377–386 - PubMed
1. Azzi S., Rossignol S., Steunou V., Sas T., Thibaud N., Danton F., Le Jule M., Heinrichs C., Cabrol S., Gicquel C., Le Bouc Y., Netchine I. (2009). Multilocus methylation analysis in a large cohort of 11p15-related foetal growth disorders (Russell–Silver and Beckwith–Wiedemann syndromes) reveals simultaneous loss of methylation at paternal and maternal imprinted loci. Hum. Mol. Genet. 18 4724–4733 - PubMed
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[1] Anckaert E., Adriaenssens T., Romero S., Dremier S., Smitz J. (2009). Unaltered imprinting establishment of key imprinted genes in mouse oocytes after in vitro follicle culture under variable follicle-stimulating hormone exposure. Int. J. Dev. Biol. 53 541–548 - PubMed

[2] Anckaert E., Adriaenssens T., Romero S., Dremier S., Smitz J. (2009). Unaltered imprinting establishment of key imprinted genes in mouse oocytes after in vitro follicle culture under variable follicle-stimulating hormone exposure. Int. J. Dev. Biol. 53 541–548 - PubMed

[3] Anckaert E., Romero S., Adriaenssens T., Smitz J. (2010). Effects of low methyl donor levels in culture medium during mouse follicle culture on oocyte imprinting establishment. Biol. Reprod. 83 377–386 - PubMed

[4] Anckaert E., Romero S., Adriaenssens T., Smitz J. (2010). Effects of low methyl donor levels in culture medium during mouse follicle culture on oocyte imprinting establishment. Biol. Reprod. 83 377–386 - PubMed

[5] Azzi S., Rossignol S., Steunou V., Sas T., Thibaud N., Danton F., Le Jule M., Heinrichs C., Cabrol S., Gicquel C., Le Bouc Y., Netchine I. (2009). Multilocus methylation analysis in a large cohort of 11p15-related foetal growth disorders (Russell–Silver and Beckwith–Wiedemann syndromes) reveals simultaneous loss of methylation at paternal and maternal imprinted loci. Hum. Mol. Genet. 18 4724–4733 - PubMed

[6] Azzi S., Rossignol S., Steunou V., Sas T., Thibaud N., Danton F., Le Jule M., Heinrichs C., Cabrol S., Gicquel C., Le Bouc Y., Netchine I. (2009). Multilocus methylation analysis in a large cohort of 11p15-related foetal growth disorders (Russell–Silver and Beckwith–Wiedemann syndromes) reveals simultaneous loss of methylation at paternal and maternal imprinted loci. Hum. Mol. Genet. 18 4724–4733 - PubMed

[7] Barrett S. L., Albertini D. F. (2010). Cumulus cell contact during oocyte maturation in mice regulates meiotic spindle positioning and enhances developmental competence. J. Assist. Reprod. Genet. 27 29–39 - PMC - PubMed

[8] Barrett S. L., Albertini D. F. (2010). Cumulus cell contact during oocyte maturation in mice regulates meiotic spindle positioning and enhances developmental competence. J. Assist. Reprod. Genet. 27 29–39 - PMC - PubMed

[9] Bartolomei M. S., Ferguson-Smith A. C. (2011). Mammalian genomic imprinting. Cold Spring Harb. Perspect. Biol. 3 pii: a002592 - PMC - PubMed

[10] Bartolomei M. S., Ferguson-Smith A. C. (2011). Mammalian genomic imprinting. Cold Spring Harb. Perspect. Biol. 3 pii: a002592 - PMC - PubMed

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Compromised fertility disrupts Peg1 but not Snrpn and Peg3 imprinted methylation acquisition in mouse oocytes

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Compromised fertility disrupts Peg1 but not Snrpn and Peg3 imprinted methylation acquisition in mouse oocytes

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