Project description:Interspecific hybridization often induces epigenetic remodeling that leads to transposon activation, gene expression changes, and loss of imprinting. These genomic changes can be deleterious and lead to postzygotic hybrid incompatibility. In Arabidopsis, loss of genomic imprinting of PHERES1 and presumed failure of Polycomb Repressive Complex is partially responsible for seed inviability observed in A. thaliana X A. arenosa interspecific hybrids. We used this species pair to further analyze the relationship between parent-specific gene expression and postzygotic hybrid incompatibility using two A. thaliana ecotypes, Col-0 and C24, with differential seed survival. We found that maternal imprinting was perturbed for PHERES1, HDG3, and six other genes in both A. thaliana hybrids and paternal imprinting was lost for MEDEA as observed previously. Three classes of retroelements; Sadhu, Athila, and Copia, maintained proper repression patterns suggesting some regulatory mechanisms are not disrupted early in development. We propose that early genome remodeling and loss of imprinting of seed development genes induces lethality in both compatible and incompatible hybrids. We examined gene expression in A. thaliana intraspecific hybrid crosses to determine normal patterns of maternal and paternal expression early in seed development.

Project description:Hybridization of diverged taxa often result in lethality or sterility. We previously described natural variation for postzygotic incompatibility in the cross of diploid Arabidopsis thaliana to Arabidopsis arenosa. Hybrid seed death in this system has a complex genetic basis, involving many non-additive interactions. While activation of AGAMOUS-LIKE genes (AGL) and Athila elements have been detected 5-8 days after pollination (DAP), the molecular basis of death remains mysterious. To address this problem, we compared 3DAP transcriptomes in interspecific hybrids from two A. thaliana ecotypes, one compatible, the other incompatible. Relative to self crosses of the respective A. thaliana seed parent, hybrids displayed differential expression of key developmental regulators in both the endosperm and maternal seed coat as well as natural variation for stress response genes. Ribosomal protein genes and a photosynthetic cluster of genes were hyperactivated, presumably in response to growth signals. Suppressing endosperm growth factor IKU1 and defense response regulators such as NON-EXPRESSOR OF PATHOGENESIS RELATED1 (NPR1) improved hybrid seed survival. Therefore, in incompatible hybrids disruption of seed development most likely initiates in the endosperm, rapidly affecting embryo and seed coat. The activation of putative POLYCOMB REPRESSIVE COMPLEX (PRC) gene targets, together with a twenty-fold reduction in expression of the FERTILIZATION INDEPENDENT SEED 2 gene, indicates a PRC role. Examination of differential gene expression of incompatible A. thaliana eco. Col-0 X A. arenosa and compatible A. thaliana eco. C24 X A. arenosa hybrid seeds plus corresponding A. thaliana and A. arenosa control crosses.

Project description:Hybridization of eggs and sperm from closely related species can give rise to genetic diversity, or can lead to embryo inviability due to incompatibility. Although central to evolution, the cellular and molecular mechanisms underlying postzygotic barriers that drive reproductive isolation and speciation remain largely unknown. Species of the African Clawed frog Xenopus provide an ideal system to study hybridization and genome evolution. Xenopus laevis is an allotetraploid with 36 chromosomes that arose through interspecific hybridization of diploid progenitors, whereas Xenopus tropicalis is a diploid with 20 chromosomes that diverged from a common ancestor ~48 million years ago. Differences in genome size between the two species are accompanied by organism size differences, and size scaling of the egg and subcellular structures such as nuclei and spindles formed in egg extracts. Nevertheless, early development transcriptional programs, gene expression patterns, and protein sequences are generally conserved. Interestingly, whereas the hybrid produced when X. laevis eggs are fertilized by X. tropicalis sperm (le×ts) is viable, the reverse hybrid (te×ls) dies prior to gastrulation. Here, we applied cell biological tools and high-throughput methods to study the mechanisms underlying hybrid inviability. We reveal that two specific X. laevis chromosomes are incompatible with the X. tropicalis cytoplasm and are mis-segregated during mitosis, leading to unbalanced gene expression at the maternal to zygotic transition, followed by cell-autonomous catastrophic embryo death.

Project description:Seed death resulting from hybridization between Arabidopsis thaliana and Arabidopsis arenosa has complex genetic determination, and involves deregulation 5-8 days after pollination (DAP) of AGAMOUS-LIKE genes (AGLs) and retroelements. To identify causal mechanisms, we compared 3 DAP transcriptomes of compatible and incompatible hybrids and parents at 3 DAP. Hybrids misexpressed endosperm and seed coat regulators, and hyperactivated genes encoding ribosomal, photosynthetic, stress-related and immune response proteins. Regulatory disruption was more severe in Col-0 hybrids than in C24 hybrids, consistent with the degree of incompatibility. Maternal loss-of-function alleles for endosperm growth factor TRANSPARENT TESTA GLABRA 2 and HAIKU 1, and defense response regulators NON-EXPRESSOR OF PATHOGENESIS RELATED 1 and SALICYLIC ACID INDUCTION-DEFICIENT 2 , increased hybrid seed survival. The activation of presumed POLYCOMB REPRESSIVE COMPLEX (PRC) targets, together with a twenty-fold reduction in expression of FERTILIZATION INDEPENDENT SEED 2, indicated a PRC role. Proximity to transposable elements affected natural vartiation for gene regulation, but transposon activation did not differ from controls. Collectively, this investigation provides candidates for multigenic orchestration of the incompatibility response through disruption of endosperm development, a novel role for communication between endosperm and maternal tissues and for pathways previously connected to immunity, but, surprisingly, does not identify a role for transposons.

Project description:We compared the expression between inter-specific hybrids (A. thaliana-A. lyrata, A. thaliana-A. halleri) and mid parent values of their parental lines. Mature leaves in A. thaliana (Col), A. lyrata ssp. lyrata, A. halleri ssp. gemmifera and interspecific hybrid between A. thaliana and A. lyrata and between A. thaliana and A. halleri

Project description:Interspecific hybrids in Arabidopsis result in seed abortion that causes reproductive barrier. To investigate the allelic expression pattern at transcriptome level during early seed abortion stage, we performed RNA-seq analysis in F1 interspecific hybrids with three different ecotypes in A. thaliana as maternal and A. arenosa as paternal and identified MEGs and PEGs. Interestingly, PEGs showed distinct expression pattern in several aspects, compared to MEGs: PEGs showed ecotype-specific expression pattern, suggesting a role for PEGs in ecotype-dependent seed lethality. 35% of previously known MEGs in non-lethal hybrids were found as PEGs in our lethal interspecific hybrids, implying the presence of abnormal paternal allelic upregulation. The correlation test between the upregulation of PEGs and previously reported paternal-excess interploidy cross (2X6) which exhibited seed abortion showed that dosage disruption by abnormal paternal upregulation is correlated with seed abortion. Moreover, epigenetic disruption appears to cause some of abnormal upregulation of paternal alleles in PEGs via mis-regulation of MEA-mediated PcG2 and MET1-mediated DNA methylation. The results provide clue on the critical role of PEGs in seed abortion via disruption of dosage balance and epigenetic regulation.

Project description:Hybrid phenotypes that contribute to postzygotic reproductive isolation often exhibit pronounced asymmetry, both between reciprocal crosses and between the sexes in accordance with Haldane's rule. Inviability in mammalian hybrids is associated with parent-of-origin placental growth abnormalities for which misregulation of imprinted genes is the leading candidate mechanism. However, direct evidence for the involvement of imprinted genes in hybrid growth dysplasia is limited. We used transcriptome and reduced representation bisulfite sequencing to conduct the first genome-scale assessment of the contribution of imprinted genes to parent-of-origin placental growth dysplasia in the cross between the house mouse (Mus musculus domesticus) and the Algerian mouse (Mus spretus). Imprinted genes with transgressive expression and methylation were concentrated in the Kcnq1 cluster, which contains causal genes for prenatal growth abnormalities in mice and humans. Hypermethylation of the cluster’s imprinting control region, and consequent misexpression of the genes Phlda2 and Ascl2, is a strong candidate mechanism for transgressive placental undergrowth. Transgressive placental and gene regulatory phenotypes, including expression and methylation in the Kcnq1 cluster, were more extreme in hybrid males. While consistent with Haldane’s rule, male-biased defects are unexpected in rodent placenta because the X-chromosome is effectively hemizygous in both sexes. In search of an explanation we found evidence of leaky imprinted (paternal) X-chromosome inactivation in hybrid female placenta, an epigenetic disturbance that may buffer females from the effects of X-linked incompatibilities to which males are fully exposed. Sex differences in chromatin structure on the X and sex-biased maternal effects are non-mutually exclusive alternative explanations for adherence to Haldane’s rule in hybrid placenta. The results of this study contribute to understanding the genetic basis of hybrid inviability in mammals, and the role of imprinted genes in speciation.

Project description:We described in this work the reproductive barrier between Capsella rubella and Capsella grandiflora leading to hybrid seed inviability. The transcriptome revealed a similar response to the one observed in interploidy hybrid seeds.

Project description:In this work, we evaluated the genetic stabilization process, of the intra- (Saccharomyces cerevisiae) and interspecific (S. cerevisiae x Saccharomyces kudriavzevii) hybrids obtained by different non-GMO techniques, under fermentative conditions. Large-scale transitions in genome size, detected by measuring total DNA content, and genome reorganizations in both nuclear and mitochondrial DNA, evidenced by changes in molecular markers, were observed during the experiments. Interspecific hybrids seem to need fewer generations to reach genetic stability than intraspecific hybrids. The largest number of molecular patterns among the derived stable colonies was observed for intraspecific hybrids, particularly for those obtained by rare-mating in which the total amount of initial DNA was larger. Finally, a representative intraspecific stable hybrid underwent a normal industrial process to obtain active dry yeast production as an important point at which inducing changes in genome composition was possible. No changes in hybrid genetic composition after this procedure were confirmed by comparative genome hybridization. According to our results, fermentation steps 2 and 5 –comprising between 30 and 50 generations- suffice to obtain genetically stable interspecific and intraspecific hybrids, respectively. This work aimed to develop and validate a fast genetic stabilization method for newly generated Saccharomyces hybrids under selective enological conditions. A comparison of the whole stabilization process in intra- and interspecific hybrids showing different ploidy levels, as a result of using different hybridization methodologies, was also made. A stable hybrid strain was compared with itself before and after ADY (active dry yeast) production in order to evaluate the genetic stability of this strain.

Project description:Background: The Dobzhansky-Muller (D-M) model of speciation by genic incompatibility is widely accepted as the primary cause of interspecific postzygotic isolation. Since the introduction of this model, there have been theoretical and experimental data supporting the existence of such incompatibilities. However, speciation genes have been largely elusive, with only a handful of candidate genes identified in a few organisms. The Saccharomyces sensu stricto yeasts have small genomes, can be easily cultured, and can mate interspecifically to produce sterile hybrids, are thus an ideal model for studying postzygotic isolation. Among them, only a single D-M pair has been found, between S. bayanus and S. cerevisiae, comprising the mitochondrially targeted product of a nuclear gene, AEP2, and a mitochondrially encoded locus, OLI1, the 5' region of whose transcript is bound by Aep2. Thus far, no D-M pair of nuclear genes has been identified between any sensu stricto yeasts. Methods: We report here the first detailed genome-wide analysis of rare F2 progeny from an otherwise sterile hybrid, and show that no classic D-M pairs of speciation genes exist between the nuclear genomes of the closely related yeasts S. cerevisiae and S. paradoxus. Instead, our analyses suggest that more complex interactions may be responsible for their post-zygotic separation. These interactions most likely involve multiple loci having weak effects, as there were multiple significant pairwise combinations of loci, with no single combination being completely excluded from the viable F2s. Conclusions: The lack of a nuclear encoded classic D-M pair between these two yeasts, yet the existence of multiple loci that may each exert a small effect through complex interactions, suggests that initial speciation events might not always be mediated by D-M pairs. An alternative explanation may be that "death by a thousand cuts" leads to speciation, whereby an accumulation of polymorphisms can lead to an incompatibility between the species "transcriptional and metabolic networks, with no single pair at least initially being responsible for the incompatibility. After such a speciation event, it is possible that one or more D-M pairs might subsequently arise following isolation. Genotypes for hybrids between S. cerevisiae and S. paradoxus. A genotyping experiment design type classifies an individual or group of individuals on the basis of alleles, haplotypes, SNP's.