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Birth weight variation is influenced by fetal and maternal genetic and non-genetic factors, and has been reproducibly associated with future cardio-metabolic health outcomes. In expanded genome-wide association analyses of own birth weight ( n  = 321,223) and offspring birth weight ( n  = 230,069 mothers), we identified 190 independent association signals (129 of which are novel). We used structural equation modeling to decompose the contributions of direct fetal and indirect maternal genetic effects, then applied Mendelian randomization to illuminate causal pathways. For example, both indirect maternal and direct fetal genetic effects drive the observational relationship between lower birth weight and higher later blood pressure: maternal blood pressure-raising alleles reduce offspring birth weight, but only direct fetal effects of these alleles, once inherited, increase later offspring blood pressure. Using maternal birth weight-lowering genotypes to proxy for an adverse intrauterine environment provided no evidence that it causally raises offspring blood pressure, indicating that the inverse birth weight–blood pressure association is attributable to genetic effects, and not to intrauterine programming. An expanded GWAS of birth weight and subsequent analysis using structural equation modeling and Mendelian randomization decomposes maternal and fetal genetic contributions and causal links between birth weight, blood pressure and glycemic traits.

Uniparental inheritance of mitochondrial DNA (mtDNA) is an evolutionary trait found in nearly all eukaryotes. In many species, including humans, the sperm mitochondria are introduced to the oocyte during fertilization 1 , 2 . The mechanisms hypothesized to prevent paternal mtDNA transmission include ubiquitination of the sperm mitochondria and mitophagy 3 , 4 . However, the causative mechanisms of paternal mtDNA elimination have not been defined 5 , 6 . We found that mitochondria in human spermatozoa are devoid of intact mtDNA and lack mitochondrial transcription factor A (TFAM)—the major nucleoid protein required to protect, maintain and transcribe mtDNA. During spermatogenesis, sperm cells express an isoform of TFAM, which retains the mitochondrial presequence, ordinarily removed upon mitochondrial import. Phosphorylation of this presequence prevents mitochondrial import and directs TFAM to the spermatozoon nucleus. TFAM relocalization from the mitochondria of spermatogonia to the spermatozoa nucleus directly correlates with the elimination of mtDNA, thereby explaining maternal inheritance in this species. The mitochondrial transcription factor A is excluded from the mitochondria in spermatozoa by virtue of phosphorylation of the mitochondrial presequence. This is associated with transport to the nucleus and loss of mitochondrial DNA (mtDNA) from the mitochondria, providing a mechanistic basis for uniparental inheritance of mtDNA in humans.

Cytoplasmic Incompatibility (CI) causes embryonic lethality in arthropods, resulting in a significant reduction in reproductive success. In most cases, this reproductive failure is driven by Wolbachia endosymbionts through their cifA - cifB gene pair, whose products disrupts arthropod DNA replication during embryogenesis. While a cif pair has been considered a hallmark of Wolbachia , its presence and functional significance in other bacterial lineages remains poorly investigated. Here, we conducted a comprehensive survey of 762 genomes spanning non- Wolbachia endosymbionts and their close relatives, revealing that the cif pair is far more widespread than previously recognized. We identified cif loci in 8.4% of the surveyed genomes, with a striking incidence of 17.4% in facultative symbionts. Beyond Wolbachia , cif pair occurs across eight bacterial genera spanning α-Proteobacteria, γ-Proteobacteria, Mollicutes, and Bacteroidota. Notably, cif pair has been identified in several intracellular pathogens of mammals showing high rate of transovarial transmission in their arthropod hosts, suggesting a potential role of cif pair and CI in vector-borne disease dynamics. Structural analyses further reveal that the PD(D/E)-XK nucleases and AAA-ATPase-like motifs are consistently conserved across cif pairs in all bacterial taxa. Moreover, cif pairs are frequently integrated within diverse mobile genetic elements, from transposons to large intact WO prophages in Wolbachia and RAGEs in Rickettsiaceae. Phylogenetic analyses reveal recent and potentially ongoing horizontal transfers of cif pair between distantly related bacterial lineages, a process potentially facilitated by mobile genetic elements. Indeed, the PDDEXK2 transposase exhibits a phylogenetic pattern consistent with the co-transmission of cif genes, suggesting that it may facilitate horizontal transfers of cif across bacterial lineages. Furthermore, the detection of endosymbionts harboring cif pair in arthropod groups where Wolbachia is scarce, such as ticks, suggests that CI may be more widespread than previously known, with significant implications for arthropod symbiosis, reproductive manipulation, and future biocontrol strategies.

Centrioles are the core constituent of centrosomes, microtubule-organizing centers involved in directing mitotic spindle assembly and chromosome segregation in animal cells. In sexually reproducing species, centrioles degenerate during oogenesis and female meiosis is usually acentrosomal. Centrioles are retained during male meiosis and, in most species, are reintroduced with the sperm during fertilization, restoring centriole numbers in embryos. In contrast, the presence, origin, and function of centrioles in parthenogenetic species is unknown. We found that centrioles are maternally inherited in two species of asexual parthenogenetic nematodes and identified two different strategies for maternal inheritance evolved in the two species. In Rhabditophanes diutinus , centrioles organize the poles of the meiotic spindle and are inherited by both the polar body and embryo. In Disploscapter pachys , the two pairs of centrioles remain close together and are inherited by the embryo only. Our results suggest that maternally-inherited centrioles organize the embryonic spindle poles and act as a symmetry-breaking cue to induce embryo polarization. Thus, in these parthenogenetic nematodes, centrioles are maternally-inherited and functionally replace their sperm-inherited counterparts in sexually reproducing species. Centrioles are broken down during oogenesis and are provided by the sperm during sexual reproduction, though how centriole numbers are regulated during asexual reproduction is unclear. Here they study two asexually reproducing nematodes and identify distinct mechanisms for maternal centrosome inheritance.

The PIWI-interacting RNA (piRNA) pathway controls transposon expression in animal germ cells, thereby ensuring genome stability over generations. In Drosophila , piRNAs are intergenerationally inherited through the maternal lineage, and this has demonstrated importance in the specification of piRNA source loci and in silencing of I- and P- elements in the germ cells of daughters. Maternally inherited Piwi protein enters somatic nuclei in early embryos prior to zygotic genome activation and persists therein for roughly half of the time required to complete embryonic development. To investigate the role of the piRNA pathway in the embryonic soma, we created a conditionally unstable Piwi protein. This enabled maternally deposited Piwi to be cleared from newly laid embryos within 30 min and well ahead of the activation of zygotic transcription. Examination of RNA and protein profiles over time, and correlation with patterns of H3K9me3 deposition, suggests a role for maternally deposited Piwi in attenuating zygotic transposon expression in somatic cells of the developing embryo. In particular, robust deposition of piRNAs targeting roo , an element whose expression is mainly restricted to embryonic development, results in the deposition of transient heterochromatic marks at active roo insertions. We hypothesize that roo , an extremely successful mobile element, may have adopted a lifestyle of expression in the embryonic soma to evade silencing in germ cells. Maintaining the integrity of DNA, which encodes all of the instructions necessary for life, is essential for ensuring the survival of a species, especially when genetic information is transferred across generations. DNA, however, contains selfish, mobile elements, called transposons, that move around the genome, hence their nickname ‘jumping genes’. Their movement, a process by which these elements also multiply within genomes, can muddle an organism’s DNA if the transposon happens to land in the middle of a gene, creating a mutation which renders the gene inactive. Transposons have also been linked to the development of cancer, which is a group of diseases driven by accumulating genetic mutations. Animals have evolved various ways of protecting their DNA against transposons. These are especially important in developing egg cells and sperm, known collectively as germ cells. These cells can produce small fragments of RNA, a molecule similar to DNA, which are able to identify and disarm transposons. While it is known that these small RNAs effectively protect adult gonads from DNA damage, it has been unclear how germ cells formed during the beginning of life are protected. To find out more, Fabry et al. used a combination of genetic sequencing, protein binding and imaging studies to look at the activity of small RNAs, called piRNAs, which are passed on from the mother to her progeny. By studying the gene expression levels in fruit fly embryos, Fabry et al. showed that certain transposons become highly active in the first few hours of embryo development, posing a potential threat to DNA integrity. The experiments also identified clear signs in the embryos of an active mechanism for controlling transposons that resembles the small RNA system known from adult germ cells. Fabry et al. removed the piRNAs from the embryos and found that without piRNAs, transposons were more active. This indicates a direct role of these small RNAs in controlling transposons in early development and evidence for a maternally inherited defence system in early embryos. This study provides insights into the control of transposons in fly embryos. More research is needed to find out whether these embryonic mechanisms are conserved in other animals, including humans. Studying the intrinsic mechanisms that prevent DNA damage and protect our genome could, in time, help to identify new approaches to possibly treat and prevent diseases involving genetic mutations.

Mother’s curse refers to male-biased deleterious mutations that may accumulate on mitochondria due to its strict maternal inheritance. If these mutations persist, males should ideally compensate through mutations on Y-chromosomes given its strict paternal inheritance. Previous work addressed this hypothesis by comparing coevolved and non-coevolved Y-mitochondria pairs placed alongside completely foreign autosomal backgrounds, expecting males with coevolved pairs to exhibit greater fitness due to Y-compensation. To date, no evidence for Y-compensation has been found. That experimental design assumes Y-chromosomes compensate via direct interaction with mitochondria and/or coevolved autosomes are unimportant in its function or elucidation. If Y-chromosomes instead compensate by modifying autosomal targets (or its elucidation requires coevolved autosomes), then this design could fail to detect Y-compensation. Here we address if Y-chromosomes ameliorate mitochondrial mutations affecting male lifespan in Drosophila melanogaster. Using three disparate populations we compared lifespan among males with coevolved and non-coevolved Y-mitochondria pairs placed alongside autosomal backgrounds coevolved with mitochondria. We found coevolved pairs exhibited lower mortality risk relative to non-coevolved pairs. In contrast, no such pattern was observed when coevolved and non-coevolved pairs were placed alongside non-coevolved autosomes, as with previous studies. These data are consistent with Y-compensation and highlight the importance of autosomes in this capacity. However, we cannot fully exclude the possibility that Y-autosomal coevolution independent of mitochondrial mutations contributed to our results. Regardless, modern practices in medicine, conservation, and agriculture that introduce foreign Y-chromosomes into non-coevolved backgrounds should be used with caution, as they may disrupt Y-autosome coadaptation and/or inadvertently unbridle mother’s curse.

Mature seed dormancy is a vital plant trait that prevents germination out of season. In Arabidopsis, the trait can be maternally regulated but the underlying mechanisms sustaining this regulation, its general occurrence and its biological significance among accessions are poorly understood. Upon seed imbibition, the endosperm is essential to repress the germination of dormant seeds. Investigation of genomic imprinting in the mature seed endosperm led us to identify a novel set of imprinted genes that are expressed upon seed imbibition. Remarkably, programs of imprinted gene expression are adapted according to the dormancy status of the seed. We provide direct evidence that imprinted genes play a role in regulating germination processes and that preferential maternal allelic expression can implement maternal inheritance of seed dormancy levels.

The concept that exposure in utero to maternal anti-brain antibodies contributes to the development of autism spectrum disorders (ASD) has been entertained for over a decade. We determined that antibodies targeting Caspr2 are present at high frequency in mothers with brain-reactive serology and a child with ASD, and further demonstrated that exposure in utero to a monoclonal anti-Caspr2 antibody, derived from a mother of an ASD child, led to an-ASD like phenotype in male offspring. Now we propose a new model to study the effects of in utero exposure to anti-Caspr2 antibody. Dams immunized with the extracellular portion of Caspr2 express anti-Caspr2 antibodies throughout gestation to better mimic the human condition. Male but not female mice born to dams harboring polyclonal anti-Caspr2 antibodies showed abnormal cortical development, decreased dendritic complexity of excitatory neurons and reduced numbers of inhibitory neurons in the hippocampus, as well as repetitive behaviors and impairments in novelty interest in the social preference test as adults. These data supporting the pathogenicity of anti-Caspr2 antibodies are consistent with the concept that anti-brain antibodies present in women during gestation can alter fetal brain development, and confirm that males are peculiarly susceptible.

Most mammals rely on chemosensory cues for individual recognition, which is essential to many aspects of social behavior, such as maternal bonding, mate recognition, and inbreeding avoidance. Both volatile molecules and nonvolatile peptides secreted by individual conspecifics are detected by olfactory sensory neurons in the olfactory epithelium and the vomeronasal organ. The pertinent cues used for individual recognition remain largely unidentified. Here we show that nonformylated, but not N-formylated, mitochondrially encoded peptides—that is, the nine N-terminal amino acids of NADH dehydrogenases 1 and 2—can be used to convey strain-specific information among individual mice. We demonstrate that these nonformylated peptides are sufficient to induce a strain-selective pregnancy block. We also observed that the pregnancy block by an unfamiliar peptide derived from a male of a different strain was prevented by a memory formed at the time of mating with that male. Our findings also demonstrate that pregnancy-blocking chemosignals in the urine are maternally inherited, as evidenced by the production of reciprocal sons from two inbred strains and our test of their urine’s ability to block pregnancy. We propose that this link between polymorphic mitochondrial peptides and individual recognition provides the molecular means to communicate an individual’s maternal lineage and strain.

The Triticum (wheat) –Aegilops (goatgrass) complex has been extensively studied, but the evolutionary history of polyploid wheats has not been fully elucidated. The chloroplast (cp) with maternal inheritance and homoplasy can simplify the sequence-based evolutionary inferences, but informative inferences would require a complete and accurate cp genome sequence. In this study, 16 cp genomes representing five Aegilops and 11 Triticum species and subspecies were sequenced, assembled and annotated, yielding five novel circular cp genome sequences. Analyzing the assembled cp genomes revealed no marked differences in genome structure and gene arrangement across the assayed species. A polymorphism analysis of 72 published cp genome sequences representing 10 Aegilops and 15 Triticum species and subspecies detected 1183 SNPs and 1881 SSRs. More than 80% SNPs detected resided on the downstream and upstream gene regions and only 2.78% or less SNPs were predicted to be deleterious. The largest nucleotide diversity was observed in the short single-copy genomic region. Relatively weak selection pressure on cp coding genes was detected. Different phylogenetic analyses confirmed that the maternal divergence of the Triticum–Aegilops complex had three deep lineages each representing a diploid species with nuclear A, B, or D genome. Dating the maternal divergence yielded age estimates of divergence that matched well with those reported previously. The divergence between emmer and bread wheats occurred at 8200–11,200 years ago. These findings are useful for further genomic studies, provide insight into cp genome evolvability and allow for better understanding of the maternal divergence of the Triticum–Aegilops complex.