bims-cebooc Biomed News
on Cell biology of oocytes
Issue of 2026–01–25
eighteen papers selected by
Gabriele Zaffagnini, Universität zu Köln
  1. Common variation in meiosis genes shapes human recombination and aneuploidy.
  2. Endogenous retroviruses synthesize heterologous chimeric RNAs to reinforce human early embryo development.
  3. Inorganic profiles of preimplantation embryos and the association of zinc with Nanog expression in the blastocyst.
  4. Oocyte surface proteins EGG-1 and EGG-2 are required for eggshell integrity in Caenorhabditis elegans.
  5. Dynamic regulation of astral microtubule growth in the meiotic spindle of mouse oocyte.
  6. Increased stiffness mimicking ovarian aging induces a fibroinflammatory response in follicles and impairs oocyte quality.
  7. Anaphase onset requires CKS-1-mediated destruction of securin in meiosis I and cyclin B1 in meiosis II.
  8. Mild defects in follicular development and reproductive performance in the heterozygous Hfm1 female mouse.
  9. The functional organization of chromosome territories in single nuclei during zygotic genome activation.
  10. Glycolysis is intrinsically required in the follicle stem cell lineage but not in female germline stem cells or their early progeny in Drosophila melanogaster.
  11. Guidelines for quantifying ovarian follicles: every follicle counts.
  12. Female Aging Affects Coilin Pattern in Mouse Cumulus Cells.
  13. Cyclin dependent kinases CDK8/19 are required for PKA inactivation during meiosis resumption.
  14. Allele Frequency Selection and No Age-Related Increase in Human Oocyte Mitochondrial Mutations.
  15. Fertilization with Protamine-2 deficient sperm triggers abnormal pronucleus development and zygotic cleavage†.
  16. Lifespan-extending downregulation of insulin signalling reduces germline mutation load.
  17. Parkin deficiency impairs female fertility, oocyte development, fertilization and mitochondrial function in mice.
  18. The human Zona-Pellucida shear modulus before and after fertilization and its implications in IVF embryo selection.
  1. Nature. 2026 Jan 21.
    Common variation in meiosis genes shapes human recombination and aneuploidy.
    Sara A Carioscia, Arjun Biddanda, Margaret R Starostik, Xiaona Tang, Eva R Hoffmann, Zachary P Demko, Rajiv C McCoy.
      The leading cause of human pregnancy loss is aneuploidy, often tracing to errors in chromosome segregation during female meiosis1,2. Although abnormal crossover recombination is known to confer risk for aneuploidy3,4, limited data have hindered understanding of the potential shared genetic basis of these key molecular phenotypes. To address this gap, we performed retrospective analysis of pre-implantation genetic testing data from 139,416 in vitro fertilized embryos from 22,850 sets of biological parents. By tracing transmission of haplotypes, we identified 3,809,412 crossovers, as well as 92,485 aneuploid chromosomes. Counts of crossovers were lower in aneuploid versus euploid embryos, consistent with their role in chromosome pairing and segregation. Our analyses further revealed that a common haplotype spanning the meiotic cohesin SMC1B is associated significantly with both crossover count and maternal meiotic aneuploidy, with evidence supporting a non-coding cis-regulatory mechanism. Transcriptome- and phenome-wide association tests also implicated variation in the synaptonemal complex component C14orf39 and crossover-regulating ubiquitin ligases CCNB1IP1 and RNF212 in meiotic aneuploidy risk. More broadly, variants associated with aneuploidy often showed secondary associations with recombination, and several also exhibited associations with reproductive ageing traits. Our findings highlight the dual role of recombination in generating genetic diversity, while ensuring meiotic fidelity.
    DOI:  https://doi.org/10.1038/s41586-025-09964-2
  2. Science. 2026 Jan 22. 391(6783): eadv5257
    Endogenous retroviruses synthesize heterologous chimeric RNAs to reinforce human early embryo development.
    Yangquan Xiang, Yuli Qian, Zhengyi Li, Jiaxu Wang, Ruonan Tian, Weikang Meng, Jiabao Bu, Fei Huang, Zhipeng Ai, Danya Wu, Xijia Chen, You Wu, Li Shen, Yun-Shen Chan, Yawei Gao, Jun Ma, Wanlu Liu, Shaorong Gao, Dan Zhang, Hongqing Liang.
      Zygotic genome activation (ZGA) failure leads to developmental arrest and poses a clinical challenge to women's fertility. We observed that human embryos arresting at the eight-cell ZGA stage exhibited specific down-regulation of endogenous retrovirus MLT2A1. Depleting MLT2A1 resulted in a failure in embryo development and a reduction in ZGA gene expression. Mechanistically, MLT2A1s synthesized chimeric transcripts with downstream coding and noncoding sequences, predominantly with heterologous retro-transposable elements. These diverse fusion sequences expanded the genome-targeting spectrum of MLT2A1 RNAs. Nevertheless, the shared MLT2A1 sequences partnered with heterogeneous nuclear ribonucleoprotein U (HNRNPU) to recruit RNA polymerase II, promoting global transcription of ZGA genes and autoamplification of the MLT2A1 subfamily. Thus, MLT2A1 chimeric RNAs formed an interlocking network that acts synergistically to boost human ZGA and early embryogenesis.
    DOI:  https://doi.org/10.1126/science.adv5257
  3. Reproduction. 2026 Jan 15. pii: xaaf014. [Epub ahead of print]171(1):
    Inorganic profiles of preimplantation embryos and the association of zinc with Nanog expression in the blastocyst.
    Julia L Balough, Thomas V O'Halloran, Francesca E Duncan, Teresa K Woodruff.
      Elements such as iron, copper, and zinc play essential roles in the mammalian oocyte, egg, and embryo; however, among these metals, zinc plays unique regulatory roles. Temporal fluctuations in zinc concentrations drive reproductive milestones such as meiotic resumption, egg activation, and initiation of the mitotic cell cycle. Roles for zinc in late preimplantation embryo development have not been well characterized. Using a quantitative element approach we report the inorganic profiles of mouse embryos progressing through the late blastocyst stage. We find that blastocysts, like oocytes and eggs, and distinct to somatic cells, maintain higher levels of zinc than copper and iron. All three of these essential metals are more abundant in the inner cell mass, which contains the population of pluripotent stem cells that gives rise to the fetus, relative to the trophectoderm which gives rise to the placenta and extraembryonic tissues. To test whether zinc abundance was associated with mitotic progress and cell-fate lineage, we perturbed zinc homeostasis during blastocyst formation by artificially raising intracellular zinc concentrations with zinc pyrithione. This treatment during the morula-to-blastocyst transition, when cell-fate lineages emerge, resulted in an elevation of zinc in the inner cell mass. This treatment did not impact cell number but did increase expression of the pluripotency and epiblast marker, Nanog. These results demonstrate that the inorganic profiles of the late preimplantation embryo retain elemental hallmarks of earlier developmental stages, and perturbation of zinc levels alters pluripotency gene expression in the blastocyst.
    Keywords:  embryo development; inner cell mass; preimplantation embryo; zinc
    DOI:  https://doi.org/10.1093/reprod/xaaf014
  4. G3 (Bethesda). 2026 Jan 19. pii: jkag013. [Epub ahead of print]
    Oocyte surface proteins EGG-1 and EGG-2 are required for eggshell integrity in Caenorhabditis elegans.
    Ji Kent Kwah, Shannon Pfeiffer, Mst Gitika Khanom, Aimee Jaramillo-Lambert.
      Metazoan eggs are surrounded by a specialized coat of extracellular matrix that mediates sperm-egg interactions. This coat is rapidly remodeled after fertilization to form a barrier that prevents polyspermy, protects against environmental insults, and provides structural support to the developing embryo. In C. elegans, several oocyte surface proteins have been identified that mediate these events. However, whether two of these proteins, EGG-1 and EGG-2, are required for fertilization or downstream events has been unclear. Here, we address this question using more recent advances in genome editing tools through the creation of egg-1 egg-2 deletions of the endogenous loci. We found that egg-1 egg-2 oocytes are fertilization competent and form rudimentary eggshells. While the integrity of the egg-1 egg-2 eggshells are compromised and often rupture within the uterus, some embryos are capable of undergoing several rounds of cell division. Absence of EGG-1 and EGG-2 results in the mislocalization of proteins on the embryo surface and eggshell. CBD-1, CHS-1, and MBK-2, components of the egg activation complex and outermost eggshell layer, were mislocalized, while localization of CPG-1, a component of an inner eggshell layer, was not perturbed. Overall, our findings demonstrate that EGG-1 and EGG-2 are not required for fertilization but rather are involved in the organization of eggshell structural components and oocyte plasma membrane proteins.
    Keywords:   Caenorhabditis elegans ; EGG-1; EGG-2; WormBase; egg activation; eggshell; fertilization
    DOI:  https://doi.org/10.1093/g3journal/jkag013
  5. Reproduction. 2026 Jan 15. pii: xaaf013. [Epub ahead of print]171(1):
    Dynamic regulation of astral microtubule growth in the meiotic spindle of mouse oocyte.
    Shan Li, Hui Zhou, Lixia Zhu, Xiaowen Liu, Zenghui Mao, Huaibiao Li, Wenpei Xiang.
      The spindle apparatus is essential for both mitotic and meiotic cell division. In contrast to its mitotic counterpart, the meiotic spindle of mammalian oocytes lacks centrosomes and thus relies on acentrosomal microtubule organizing centers to assemble the spindle. In addition, the positioning of spindle in oocytes is mediated by the F-actin network, not the astral microtubules (MTs). Overall, the role of astral MTs in meiotic spindle positioning has been overlooked due to the lack of centrosomes. In this study, we present an optimized method for staining and super-resolution imaging of astral MTs during meiosis. Though lacking centrosomes, both interpolar and astral MTs were present in the spindle through meiosis. The growth of astral MTs was inhibited by CDK1 and actin-related protein 2/3. Premature extension of astral MTs at metaphase I impaired the positioning of meiotic spindle, resulting in symmetric division of oocytes after meiosis I. Collectively, these results provide novel insights into the regulation of astral MT growth to facilitate the positioning of meiotic spindle in oocytes.
    Keywords:  astral microtubule; cytoskeleton; meiotic spindle; oocyte
    DOI:  https://doi.org/10.1093/reprod/xaaf013
  6. Reproduction. 2026 Jan 23. pii: xaaf026. [Epub ahead of print]
    Increased stiffness mimicking ovarian aging induces a fibroinflammatory response in follicles and impairs oocyte quality.
    Sara Pietroforte, Farners Amargant.
      Reproductive aging in females is characterized by decreased ovarian reserve and oocyte quality. With aging, both mouse and human ovaries become pro-fibrotic and stiff. However, whether follicles sense and respond to microenvironmental stiffness and affect folliculogenesis and oocyte quality independent of other aging-related factors is unknown. To address this question, we cultured mouse secondary follicles in alginate hydrogels that reproduce the stiffness of young and reproductively old mice. RNA-sequencing revealed that follicles respond rapidly to increased stiffness and exhibit enrichment in genes related to inflammation and extracellular matrix remodeling. Long-term culture in stiff hydrogels resulted in reduced follicle survival, granulosa cell viability, estradiol synthesis, and oocyte quality. To begin to determine how stiffness is transmitted within the follicle, we examined transzonal projections, which mediate granulosa cell-oocyte communication and nutrient exchange. In stiff conditions, the number of transzonal projections decreased. Our findings demonstrate that follicles are highly mechanosensitive and that stiffness alone can trigger hallmarks of ovarian aging, including reduced follicle growth, reduced oocyte quality, and a fibroinflammatory phenotype potentially integrated to the oocyte via TZPs.
    Keywords:  Ovarian aging; folliculogenesis; oocyte quality; stiffness
    DOI:  https://doi.org/10.1093/reprod/xaaf026
  7. J Cell Biol. 2026 Feb 02. pii: e202502087. [Epub ahead of print]225(2):
    Anaphase onset requires CKS-1-mediated destruction of securin in meiosis I and cyclin B1 in meiosis II.
    Jie Yang, Eisuke Sumiyoshi, Bruce Bowerman.
      The cyclin-dependent kinase subunit CKS remains poorly understood. We found that Caenorhabditis elegans CKS-1 and its partner CDK-1 co-localized to the cytosol, chromosomes, and spindle structures throughout cell division. Nevertheless, CKS-1 was required well after CDK-1, during oocyte meiosis I metaphase, which was prolonged in cks-1 mutants. Anaphase A precedes anaphase B in C. elegans oocytes, and while delayed in onset, chromosomes in cks-1 mutants separated normally during meiosis I anaphase A but failed to separate further and instead rapidly transitioned into meiosis II prometaphase, skipping anaphase B. The anaphase A to B transition also was defective during meiosis II. Furthermore, meiosis I anaphase B required that CKS-1 be bound to CDK-1 and have a functional anion pocket. Finally, our results suggest that CKS-1 promotes anaphase onset during meiosis I through securin destruction and during meiosis II through cyclin B1 destruction, and that both securin and cyclin B3 have positive roles independent of their destruction during meiosis II.
    DOI:  https://doi.org/10.1083/jcb.202502087
  8. Reproduction. 2026 Jan 23. pii: xaaf023. [Epub ahead of print]
    Mild defects in follicular development and reproductive performance in the heterozygous Hfm1 female mouse.
    Lavi Bhati, Adriana C Ene, Jessy Chen, Manqi Liang, Parinaz Kazemi, Jacinta H Martin, Rima Slim, Teruko Taketo.
      HFM1 (Helicase For Meiosis 1) is an ATP-dependent DNA helicase expressed primarily in the germ cells and plays a conserved role in meiotic synapsis and recombination. Biallelic HFM1 mutations are responsible for female infertility and various forms of pregnancy loss associated with primary ovarian insufficiency (POI), whereas monoallelic HFM1 mutations are found in women with milder forms of reproductive failures. Homozygous null mutation of Hfm1 in the female mouse exhibited severe defects in the meiotic synapsis and crossovers in oocytes, leading to aberrant chromosome segregation at the first meiotic division. However, the Hfm1 null female mouse loses all its oocytes prior to puberty, precluding further studies on the role of HFM1 in female reproduction. In the current study, we examined various fertility parameters in the heterozygous Hfm1 mutant mouse, which did not exhibit aberrant meiotic synapsis or recombination. Our results indicated largely normal ovarian development, consistent with their fertility. Nonetheless, we found (1) mild defects in follicle formation and recruitment, (2) delay in the initial increase in reproductive capacity and faster decline in fertility with age, (3) slower preimplantation development of embryos in culture, and (4) smaller ovarian reserve near the end of the reproductive life, compared to wild-type mice. We suggest that similar defects may underlie the reproductive failure of women with monoallelic HFM1 mutations.
    Keywords:  Hfm1; female mouse fertility; follicle; oocyte; ovary
    DOI:  https://doi.org/10.1093/reprod/xaaf023
  9. Sci Rep. 2026 Jan 18.
    The functional organization of chromosome territories in single nuclei during zygotic genome activation.
    Akshada Shankar Ganesh, Taylor M Orban, Romir Raj, Peter I Fatzinger, Anna Johnson, Sean M Riccard, Akhmed Zhanaidarov, Mayu Inaba, Jelena Erceg.
      Chromosome territories (CTs) are intricately organized and regulated within the nucleus. Despite remarkable advances in our understanding of genome packaging and gene expression, the interplay among CTs, pairing of parental homologous chromosomes, and genome function during development remains elusive. Here, we employ an Oligopaints-based high-resolution imaging approach to examine variable CT organization in single nuclei during the developmental process of zygotic genome activation. We reveal large-scale chromosome packaging differences and high levels of homolog pairing at the whole-chromosome scale that decreases locally due to spatial variability in chromosome conformations. In the absence of one homolog copy, the dynamics of CT compaction and RNA polymerase II recruitment are associated with the transcriptional changes in haploid embryos. Finally, global inhibition of transcription results in decreased CT opening and no significant impact on CT pairing levels. These findings enhance our understanding of variable parental genome folding and regulation during development, which may inform strategies for chromosome-based diseases.
    Keywords:  Chromosome territories (CTs); Haploid; Homolog pairing; RNA polymerase II; Transcription; Zygotic genome activation (ZGA)
    DOI:  https://doi.org/10.1038/s41598-026-35953-0
  10. Genetics. 2026 Jan 20. pii: iyag015. [Epub ahead of print]
    Glycolysis is intrinsically required in the follicle stem cell lineage but not in female germline stem cells or their early progeny in Drosophila melanogaster.
    Emily M Wessel, Daniela Drummond-Barbosa.
      Multiple tissue stem cells depend on glycolysis or β-oxidation for cell fate decisions. However, how universal these requirements are and how they change as stem cell daughters undergo differentiation remains unclear. The Drosophila ovary is a powerful stem cell model with two distinct stem cell populations: germline stem cells (GSCs), which produce oocytes to perpetuate the species, and follicle stem cells (FSCs), a somatic lineage. Several studies have begun addressing the roles of metabolism within the Drosophila female GSC lineage, but direct systematic analyses of glycolysis and/or mitochondrial fatty acid β-oxidation requirements across these lineages have been lacking. Here, using genetic mosaic analysis with null alleles, we found that genes encoding key regulatory glycolytic enzymes-Phosphofructokinase (Pfk) and Pyruvate kinase (Pyk)-are not cell autonomously required for GSC maintenance, proliferation, or early differentiation through 16-cell germline cyst formation and oocyte specification. Although germline cysts lacking Pfk or Pyk function can develop through early vitellogenesis, they grow slowly and display impaired nurse cell chromatin dispersal. By contrast, FSCs and their early daughters require Pfk (but not Pyk) for normal survival, while later follicle cells need both Pfk and Pyk for survival and only Pfk for proliferation, suggesting that follicle cells predominantly require glycolytic intermediates upstream of Pyk. Surprisingly, mitochondrial β-oxidation was dispensable in both lineages. These findings uncover an unusual metabolic state in GSCs and their early daughters, with marked differences from the neighboring FSC lineage and other somatic stem cells.
    Keywords:   Drosophila ; follicle stem cells; germline stem cells; glycolysis; oogenesis; β-oxidation
    DOI:  https://doi.org/10.1093/genetics/iyag015
  11. Reproduction. 2026 Jan 23. pii: xaag002. [Epub ahead of print]
    Guidelines for quantifying ovarian follicles: every follicle counts.
    Elyse O K Swindells, Lauren R Alesi, Jessica M Stringer, Karla J Hutt.
      Quantifying ovarian follicles is a fundamental tool in reproductive biology, providing the only direct measure of the ovarian reserve. The characterisation of follicle dynamics and depletion across the reproductive lifespan, and in response of the compounding effects of pathological insults, is essential for understanding women's reproductive, endocrine, and systemic health. Manually tallying follicles across serial histological sections is the most widely used method for quantifying ovarian follicles. However, this approach is prone to protocol inconsistencies and interpretation bias. Consequently, the accuracy, reproducibility, and suitability of the data for cross-study comparisons or meta-analyses are often compromised. In this protocol, we outline key considerations for follicle counting and provide standardized approaches using the two principal methods: direct counting with paraffin-embedded tissue and stereological analysis with glycol methyl-acrylate sections. These guidelines are intended to ensure consistent, accurate, and objective follicle quantification, and to support researchers across disciplines in adopting ovarian health and function, measured by follicle number, as a routine outcome in preclinical animal studies.
    Keywords:  Follicle counting; Folliculogenesis; Morphology; Oocyte; Ovarian reserve; Ovary; Protocols; Stereology; follicle
    DOI:  https://doi.org/10.1093/reprod/xaag002
  12. J Dev Biol. 2026 Jan 15. pii: 6. [Epub ahead of print]14(1):
    Female Aging Affects Coilin Pattern in Mouse Cumulus Cells.
    Alexey S Anisimov, Dmitry S Bogolyubov, Irina O Bogolyubova.
      Cumulus cells (CCs) are a distinct population of granulosa cells (GCs) that surround the developing and ovulated mammalian oocyte. The features of their structural organization and the expression pattern of key genes significantly affect oocyte viability. Changes in the functional activity of the nucleus are often expressed in changes in the structure of nuclear bodies (NBs), including Cajal bodies (CBs). The diagnostic protein of CBs is coilin, which maintains their structural integrity. Using fluorescent and electron microscopy, we examined maternal aging-associated changes in coilin pattern in mouse CCs. We found that older mice had a decrease in the number of coilin-positive bodies, while external transcriptome data analysis revealed no significant changes in Coil and Smn1 gene expression. We hypothesized that the age-related dynamics of coilin-containing bodies are determined not by changes in the expression level of key components of these bodies, but by age-related changes in CC metabolism. Considering that CCs are a by-product of IVF protocols, making them available for analysis in sufficient quantities, age-related changes in the number and size of coilin-positive NBs in CCs may serve as a promising biomarker for assessing ovarian functional aging.
    Keywords:  3D image analysis; Cajal bodies; bioinformatics analysis; coilin; cumulus cells; granulosa cells; immunocytochemistry; ovary aging
    DOI:  https://doi.org/10.3390/jdb14010006
  13. Biochim Biophys Acta Mol Cell Res. 2026 Jan 17. pii: S0167-4889(26)00010-8. [Epub ahead of print] 120114
    Cyclin dependent kinases CDK8/19 are required for PKA inactivation during meiosis resumption.
    D Yulia Okulova, A Maxim Filatov, A Ekaterina Varlamova, V Anna Tvorogova, V Evgeniy Korshunov, Yulia Silaeva Yu, V Victor Tatarskiy, V Alexandra Bruter.
      CDK8/19 are transcriptional cyclin dependent kinases, which do not directly control cell cycle progression. CDK8/19 are involved in regulation of multiple processes in embryogenesis, cancer progression, immune activation and others. Previously we demonstrated that CDK8/19 are critical for spermatogenesis in mice. Here we report that CDK8/19 activity is also required for oocyte maturation playing a significant role in meiosis resumption in mouse oocytes. Two chemically distinct CDK8/19 inhibitors - Senexin B and Snx631 prevented nuclear envelope breakdown and first polar body extrusion, blocking key molecular events required for exiting the dictyate - inhibition of PKA activity and activation of the CDK1/Cyclin B complex. This effect did not cause cytotoxicity, and oocytes could resume progression upon transfer into fresh media. Inhibition of CDK8/19 also prevented meiotic-specific mitochondrial expansion and clustering. Notably, these effects appear to be independent of roles of CDK8/19 in transcription, which is not required for resumption of meiosis. These findings for the first time demonstrate the roles of CDK8/19 activity in oocyte maturation, through its role in transcription-independent regulation of PKA activity.
    Keywords:  CDK19; CDK8; Meiosis; Mouse; Oocytes; PKA
    DOI:  https://doi.org/10.1016/j.bbamcr.2026.120114
  14. Obstet Gynecol Surv. 2026 Jan 01. 81(1): 25-26
    Allele Frequency Selection and No Age-Related Increase in Human Oocyte Mitochondrial Mutations.
    Barbara Arbeithuber, Kate Anthony, Bonnie Higgins, Peter Oppelt, Omar Shebl, Irene Tiemann-Boege, Francesca Chiaromonte, Thomas Ebner, Kateryna D Makova.
      Mitochondrial dysfunction can cause a multitude of systemic diseases, and thus, the origin of such dysfunction is of great interest to many clinicians and researchers. Part of mitochondrial dysfunction can be explained by mutations in mitochondrial DNA (mtDNA), which can be measured both in somatic and germline cells. As the average maternal age continues to increase, determining if mutations in mtDNA increase with age is an important aspect of reproductive health care. This study was designed to assess the frequency of de novo mutations in mtDNA in oocytes based on age, compared with the frequency of mutations in somatic cells. This study used high-quality, full-length mtDNA sequences for 22 individuals between the ages of 20 and 42, obtaining samples from blood, saliva, and oocytes. Duplex sequencing was used to identify variants in mtDNA; median mtDNA enrichment was 85.4%, 0.7%, and 4.0% and a median duplex consensus sequence (DCS) depth of 1440X, 78X, and 158X for oocytes, blood, and saliva, respectively. There were 3525 high-confidence variants identified across all samples. Across age groups and geographic regions, there were significantly fewer mutations in oocytes compared with blood and saliva. When predicting the probability of a mutation in mtDNA as a function of age, there were significant increases in mutation frequency in blood and saliva, but not in oocytes (P<0.001, P<0.001, P=0.688, respectively). Comparing different age groups, mutation frequency was higher in blood and saliva in older women compared with younger women, but there was no significant difference in oocyte mutation frequency. Within oocyte mtDNA, mutations were more frequent in the D-loop than in the "coding region" for each age group, consistent with previous literature. This remained true in several different analyses of regions of mtDNA, though no significant differences were found related to age. A total of 109 de novo mutations were located at confirmed disease-associated sites, with 32 variants in 29 positions. Lower proportions of disease-related mutations were present in oocytes compared with blood or saliva, suggesting preferential selection for oocytes against mutations. Hotspots for variants were identified in each type of cell, showing 58 sites overlapping between cell types; 40 of these were in the D-loop, 4 in rRNA, 4 in tRNA, and 10 in protein-coding regions. This supports the previous finding of high mutation frequency in the D-loop for oocytes. These results indicate that there is no increase in mutation frequency in oocytes as women age, though there was an increase in mutation frequency in both blood and saliva. This contrasts with previous literature in animal models that showed either continuous increases in mutation frequency with age or increases up to a certain age after which there was a plateau. The age group of this study was limited to 20-42, meaning that there could be an increase in mutation frequency that occurs either before or after this time period in humans. This is the first study to use duplex sequencing, and thus the most accurate to date in terms of pinpointing variants and mutation sites. Future research should focus on validating these results with similar methods as well as implementing duplex sequencing of pedigrees to form a more complete picture.
    DOI:  https://doi.org/10.1097/OGX.0000000000001486
  15. Biol Reprod. 2026 Jan 20. pii: ioag010. [Epub ahead of print]
    Fertilization with Protamine-2 deficient sperm triggers abnormal pronucleus development and zygotic cleavage†.
    Shannon R Rainsford, Kevin Tse, Benjamin William Walters, Jong-Nam Oh, Kaelyn Sumigray, Bluma J Lesch, Zachary D Smith.
      Spermatozoan DNA is hyper-condensed by protamines, which are essential for sperm motility and function. Since defects in this process impact natural fertilization, little is known about how changes to protamine-mediated condensation impact the oocyte's ability to recognize and reprogram the paternal genetic material for the early stages of embryogenesis. Here, we performed intracytoplasmic sperm injection (ICSI) with sperm lacking Protamine 2 (Prm2 KO) and tracked preimplantation development in mice. We found that ICSI with Prm2 KO sperm leads to embryo fragmentation and arrest at the 2-cell stage. Surprisingly, injected Prm2 KO sperm DNA is rapidly depleted from the oocyte during the completion of maternal meiosis II, leading to a zygote with one morphologically abnormal pronucleus. Direct induction of DNA damage in wild type sperm did not recapitulate the pronuclear abnormalities found in Prm2 KO-derived zygotes. Co-injection with wild type sperm failed to rescue these defects, indicating that they were not caused by absence of a normally protaminated paternal genome. Finally, we find that testicular Prm2 KO sperm support progression to the blastocyst stage, suggesting a model where fertility-compromising factors are acquired during epididymal maturation. Our results demonstrate that Protamine 2 is necessary for correct maturation of epididymal sperm and essential for their ability to form of a functional zygote at fertilization.
    Keywords:  Protamine; infertility; intracytoplasmic sperm injection; sperm; zygote
    DOI:  https://doi.org/10.1093/biolre/ioag010
  16. bioRxiv. 2025 Dec 05. pii: 2025.12.05.692572. [Epub ahead of print]
    Lifespan-extending downregulation of insulin signalling reduces germline mutation load.
    Elizabeth M L Duxbury, Alice M Godden, Jean-Charles de Coriolis, Hanne Carlsson, Simone Immler, Alexei A Maklakov.
      Reduced insulin/IGF-1 signalling (IIS) robustly extends lifespan and enhances somatic stress resistance across taxa, yet its consequences for germline genome integrity remain unclear. Here we combine multigenerational mutation accumulation with whole-genome sequencing in C. elegans to test whether adulthood-only IIS downregulation can simultaneously promote somatic maintenance and limit germline mutational burden. We reduced IIS by adult-onset daf-2 RNAi in wild-type and heritable RNAi-deficient ( hrde-1 ) backgrounds, allowing either spontaneous or UV-induced germline mutations to accumulate over multiple generations. In wild-type animals, reduced IIS lowered germline single-nucleotide mutation rates by up to ∼50% and prevented the UV-induced elevation in mutation rate, without detectable costs to fecundity or lineage persistence. By contrast, in hrde-1 mutants the same intervention increased both point mutations and transposable-element-driven insertions under UV exposure, accelerating lineage extinction. Thus, the genome-protective effect of reduced IIS critically requires the germline nuclear Argonaute HRDE-1, which mediates small-RNA-guided epigenetic silencing. Functional annotation of germline variants revealed enrichment in pathways linked to development, cellular maintenance and conserved longevity regulators, including IIS and mTOR, and identified high-impact mutations in genes with human orthologs implicated in neurodegeneration and cancer. Our findings show that IIS can coordinate somatic and germline maintenance in concert, rather than in competition, through an HRDE-1-dependent epigenetic pathway. This work positions nutrient-sensing IIS as a central regulator of germline genome stability and suggests that IIS downregulation can reduce germline mutation load while extending lifespan, with broad implications for biogerontology and evolutionary biology.
    DOI:  https://doi.org/10.64898/2025.12.05.692572
  17. NPJ Aging. 2026 Jan 22.
    Parkin deficiency impairs female fertility, oocyte development, fertilization and mitochondrial function in mice.
    Michelle Volovsky, Adolfo Rodríguez-Eguren, Yagmur Ergun, Raziye Melike Yildirim, Gizem Nur Sahin, Rolando Garcia Milian, Sameet Mehta, Lavinia Turanli, Irene Cervelló, Richard Scott, Emre Seli.
      Parkin, a mitochondrial E3 ubiquitin ligase, plays a central role in mitophagy and cellular homeostasis. Although well studied in neurobiology, its role in female reproduction remains unclear. This study investigated the role of Parkin on female fertility using young (2-3 months old) and older (9-10 months old) mice with a global germline Parkin deletion. Parkin knockout (KO) females exhibited significantly reduced fertility with total pups per female lower in KO mice (16.0 ± 1.53) compared to wild type (WT) (22.33 ± 0.67; p = 0.02). In young mice, GV oocyte yield was significantly reduced in KO (30.0 ± 1.53) compared to WT (52.7 ± 6.96; p = 0.03), as was MII oocyte count (7.7 ± 0.67 vs. 22.3 ± 0.88; p = 0.0002). In older mice, similar trends were observed. Fertilization rates were significantly lower in KO mice compared to WT (36.2 ± 8.1% vs. 61.2 ± 5.5%; p = 0.03). RNA sequencing identified multiple differentially expressed genes between KO and WT, with associated pathway changes. These findings indicate that Parkin deficiency impairs oocyte yield, fertilization capacity, and overall fertility, suggesting that Parkin plays a key role in reproductive competence.
    DOI:  https://doi.org/10.1038/s41514-026-00332-6
  18. Sci Rep. 2026 Jan 18.
    The human Zona-Pellucida shear modulus before and after fertilization and its implications in IVF embryo selection.
    E Priel, Y Yosef, T Priel, I Har-Vardi.
      Previous studies have shown a clear correlation between the value of the human ZP shear modulus and implantation potential. Nevertheless, the mechanical response of the ZP changes following fertilization due to a phenomenon termed Zona hardening were not demonstrated. The current study investigated the Zona hardening phenomenon using a computational approach based on oocyte specific clinical data taken from IVF procedures. By analysis of ZP deformation before and after fertilization the value of the ZP shear modulus was estimated. The results clearly show an increase in ZP shear modulus by an average factor of 1.768 ± 0.83 which is consistent with past studies. There is, however, great variability in the amount of Zona hardening for the different oocytes analyzed. It is shown, that while the value of the ZP shear modulus before fertilization is well correlated with embryo implantation potential, strengthening past observations, the ZP shear modulus estimated at days 2-3 after oocyte retrieval is not correlated with implantation.
    DOI:  https://doi.org/10.1038/s41598-026-36595-y
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