Maternal imprinting, mitochondrial DNA, nuclear DNA and Alzheimer’s disease

Familial early-onset Alzheimer’s disease (AD) is more probable in individuals coming from mothers diagnosed with AD than from fathers diagnosed with AD. Studies in animal models have shown maternal imprinting due to the transmission to the embryo of altered material in the ovum. In the case of transgenic animals harboring a mutated form of the human amyloid precursor protein (APP), offspring from crosses with wild-type (WT) fathers and transgenic mothers display more abnormalities than offspring from crosses with transgenic fathers and WT mothers. Expression of the mutated APP in the ovum may lead to alterations that may be genetic and/or epigenetic in the nuclear and/or the mitochondrial DNA. These modifications that are transmitted to the new living beings affect more mitochondrial proteins and, therefore, the mitochondrial function may be affected in adulthood by trends present in the ovum.

Detection of a new deleterious SGCE gene variant in Moroccan family with inherited Myoclonic-dystonia

Myoclonus-Dystonia is a neuropsychiatric disorder with autosomal dominant mode of inheritance with variable severity and incomplete penetrance. Pathogenic variants in SGCE are the most frequent genetic cause of M-D with maternal imprinting. Herein we report a new deleterious variant based on protein modeling analysis (c.662G> T) inherited in moroccan family.

Meiotic Drive in Chronic Lymphocytic Leukemia compared with other Malignant Blood Disorders

Studies of families with two or more cases of malignant blood disorders (lympoproliferative and/or myeloproliferative) provide a description of the pathway of susceptibility down through the generations towards the proband. The united observations fit into a non-Mendelian operational model consisting of parental genomic imprinting combined with feto-maternal microchimerism. Male affected relatives of a proband are predominant in paternal lines with maternal imprinting, while female affected relatives are predominant in lines with maternal affiliation and paternal imprinting. The findings suggest the influence of a so-called polymorphic equilibrium with segregation distortion related to parental imprinting (fitness optimalization). In the generations before a proband, affected relatives with the same diagnosis may covariate, viz. be present with a higher frequency than expected (relative superiority); or contravariate, that is a lower frequency than expected (mutual minority). Covariation has been observed especially among affected relatives with multiple myeloma, diffuse large B-cell lymphoma, acute myeloid leukemia, Hodgkin’s lymphoma and some few other diagnoses. Contravariation is only seen among affected relatives with chronic lymphocytic leukemia. The dynamic drive of susceptibility in an affected family with birth order effect and/or anticipation is regarded as an additional polymorphic equilibrium with segregation distortion caused by feto-maternal microchimerism.

Maternal imprinting of the neonatal microbiota colonization in intrauterine growth restricted piglets: a review

Early colonization of intestinal microbiota during the neonatal stage plays an important role on the development of intestinal immune system and nutrients absorption of the host. Compared to the normal birth weight (NBW) piglets, intrauterine growth restricted (IUGR) piglets have a different intestinal microbiota during their early life, which is related to maternal imprinting on intestinal microbial succession during gestation, at birth and via suckling. Imbalanced allocation of limited nutrients among fetuses during gestation could be one of the main causes for impaired intestinal development and microbiota colonization in neonatal IUGR piglets. In this review, we summarized the potential impact of maternal imprinting on the colonization of the intestinal microbiota in IUGR piglets, including maternal undernutrition, imbalanced allocation of nutrients among fetuses, as well as vertical microbial transmission from mother to offspring during gestation and lactation. At the same time, we give information about the current maternal nutritional strategies (mainly breastfeeding, probiotics and prebiotics) to help colonization of the advantageous intestinal microbiota for IUGR piglets.

Humanized H19/Igf2 locus reveals diverged imprinting mechanism between mouse and human and reflects Silver–Russell syndrome phenotypes

Genomic imprinting affects a subset of genes in mammals, such that they are expressed in a monoallelic, parent-of-origin–specific manner. These genes are regulated by imprinting control regions (ICRs), cis-regulatory elements that exhibit allele-specific differential DNA methylation. Although genomic imprinting is conserved in mammals, ICRs are genetically divergent across species. This raises the fundamental question of whether the ICR plays a species-specific role in regulating imprinting at a given locus. We addressed this question at the H19/insulin-like growth factor 2 (Igf2) imprinted locus, the misregulation of which is associated with the human imprinting disorders Beckwith–Wiedemann syndrome (BWS) and Silver–Russell syndrome (SRS). We generated a knock-in mouse in which the endogenous H19/Igf2 ICR (mIC1) is replaced by the orthologous human ICR (hIC1) sequence, designated H19hIC1. We show that hIC1 can functionally replace mIC1 on the maternal allele. In contrast, paternally transmitted hIC1 leads to growth restriction, abnormal hIC1 methylation, and loss of H19 and Igf2 imprinted expression. Imprint establishment at hIC1 is impaired in the male germ line, which is associated with an abnormal composition of histone posttranslational modifications compared with mIC1. Overall, this study reveals evolutionarily divergent paternal imprinting at IC1 between mice and humans. The conserved maternal imprinting mechanism and function at IC1 demonstrates the possibility of modeling maternal transmission of hIC1 mutations associated with BWS in mice. In addition, we propose that further analyses in the paternal knock-in H19+/hIC1 mice will elucidate the molecular mechanisms that may underlie SRS.

Mother–offspring and nest-mate resemblance but no heritability in early-life telomere length in white-throated dippers

Telomeres are protective DNA–protein complexes located at the ends of eukaryotic chromosomes, whose length has been shown to predict life-history parameters in various species. Although this suggests that telomere length is subject to natural selection, its evolutionary dynamics crucially depends on its heritability. Using pedigree data for a population of white-throated dippers ( Cinclus cinclus ), we test whether and how variation in early-life relative telomere length (RTL, measured as the number of telomeric repeats relative to a control gene using qPCR) is transmitted across generations. We disentangle the relative effects of genes and environment and test for sex-specific patterns of inheritance. There was strong and significant resemblance among offspring sharing the same nest and offspring of the same cohort. Furthermore, although offspring resemble their mother, and there is some indication for an effect of inbreeding, additive genetic variance and heritability are close to zero. We find no evidence for a role of either maternal imprinting or Z-linked inheritance in generating these patterns, suggesting they are due to non-genetic maternal and common environment effects instead. We conclude that in this wild bird population, environmental factors are the main drivers of variation in early-life RTL, which will severely bias estimates of heritability when not modelled explicitly.