Project description:Growing data suggest companion dogs may be a promising model of human brain aging and Alzheimer’s disease (AD). However, while pathology is similar in AD and canine cognitive dysfunction (CCD), the transcriptomic similarities between these two conditions have not been thoroughly evaluated. Two emerging transcriptome-related mechanisms of brain aging and AD involve transposable elements (TEs) and microRNAs (miRNAs), which have the potential to be carried systemically and between cells by extracellular vesicles (EVs). To determine if evidence of these AD-related transcriptomic events might be present in CCD, we generated total transcriptome (RNA-seq) data on cortex tissue and plasma EVs from young, old, and old CCD dogs. We show that: 1) global transcriptome changes with CCD indicate reduced neuronal health; 2) TE transcripts increase with CCD in both the brain and plasma EVs; 3) brain- and disease-relevant miRNAs are present in the same EVs, and some of these miRNAs correlate with indices of cognitive function/CCD. Collectively, our data suggest that transcriptomic changes in the dog, including those related to novel RNA mechanisms of brain aging and disease, are similar to those observed in humans.

Project description:Growing evidence implicates transposable elements (TEs) in aging and Alzheimer’s disease (AD). To evaluate potential transcriptional and epigenetic differences related to TE expression in this context, we generated whole blood total RNA-seq, and peripheral blood cell whole-genome bisulfite sequencing (WGBS), and transposase-accessible chromatin sequencing (ATAC-seq) on samples from healthy middle-aged/older adults, mild cognitive impairment (MCI), and AD patients.

Project description:Craniofacial development is evolutionarily conserved, yet subtle changes in its regulatory network drive species-specific traits. Transposable elements (TEs) contribute to genome evolution, but their role in cranial neural crest cells (CNCCs) remains unclear. Here, we investigate the domestication of hominoid-specific TEs (LTR5Hs and SVAs) as enhancers during human CNCC specification, a process critical for vertebrate craniofacial development. Using human iPSC-derived CNCCs, we identified ~515 hominoid-specific TEs functioning as enhancers, including ~250 human-specific, predominantly LTR5Hs. These elements are enriched for CNCC coordinator motifs, are bound by the CNCC signature factor TWIST1, and their enhancer activity appears largely CNCC-specific. CRISPR-interference targeting ~75% of these active TEs led to widespread transcriptional dysregulation of genes involved in neural crest migration, and two orthogonal functional assays confirmed that CNCC migration is impaired upon TE repression. Finally, genes near human-specific TEs showed higher expression in human CNCCs compared to chimpanzee CNCCs, but TE repression restored gene expression to chimpanzee levels. These findings highlight how young TEs were domesticated to fine-tune CNCC regulatory networks, potentially contributing to lineage-specific craniofacial evolution.

Project description:Transposable elements (TEs) have significantly influenced the evolution of transcriptional regulatory networks in the human genome. Post-transcriptional regulation of human genes by TE-derived sequences has been observed in specific contexts, but has yet to be systematically and comprehensively investigated. Here, studied a collection of CLIP-Seq (CrossLinked ImmunoPrecipitation) experiments mapping the RNA binding sites for a diverse set of 46 human proteins across 68 experiments to explore the role of TEs in post-transcriptional regulation genome-wide via RNA-protein interactions. We detected widespread interactions between RNA binding proteins (RBPs) and various families of TE-derived sequence in the CLIP-Seq data. Alignment coverage clustered on specific positions of the TE consensus sequences, illuminating a diversity of TE-specific motifs for many RBPs. Evidence of binding and conservation of these motifs in the nonrepetitive transcriptome suggest that TEs have appropriated existing sequence preferences of the RBP. Upon depletion of the RBPs, transcripts possessing TE-derived binding sites were similarly regulated as those bound in nonrepetitive sequence. However, in a few cases the effect of RBP binding depended on the specific TE family boundM-bM-^@M-^Te.g., the ubiquitously expressed RBP HuR conferred opposite effects on stability to transcripts when bound to Alu elements versus other families. Our meta-analysis suggests a widespread role for TEs in shaping RNA-protein regulatory networks in the human genome. HuR formaldehyde RIP-Seq in K562 cells, with RIP and input sequenced in triplicate.

Project description:Older age is the primary risk factor for most chronic diseases, including Alzheimer’s disease (AD). Current preclinical models to study brain aging and AD are mainly transgenic and harbor mutations intended to mirror brain pathologies associated with human brain aging/AD (e.g., by increasing production of amyloid precursor protein, amyloid beta [Aβ], and/or phosphorylated tau, all of which are key pathological mediators of AD). Although these models may provide insight on pathophysiological processes in AD, none completely recapitulate the disease and its strong age-dependence, and there has been limited success in translating preclinical results and treatments to humans. Here, we describe two non-transgenic guinea pig (GP) models, a standard PigmEnTed (PET) strain and lesser-studied Dunkin-Hartley (DH) strain, that may naturally mimic key features of brain aging and AD in humans. We show that brain aging in PET GP is transcriptomically similar to human brain aging, whereas older DH brains are transcriptomically more similar to human AD. Both strains/models also exhibit increased neurofilament light chain (NFL, a marker of neuronal damage) with aging, and DH animals display greater S100 calcium-binding protein B (S100β), ionized calcium-binding adapter molecule 1 (Iba1), and Aβ and phosphorylated tau— which are all important markers of neuroinflammation-associated AD. Collectively, our results suggest that both the PET and DH GP may be useful, non-transgenic models to study brain aging and AD, respectively.

Project description:Transposable elements (TEs) are threats to genome stability and thus small RNA-mediated heterochromatinization suppresses the transcription of TEs. Paradoxically, transcription of non-coding RNA (ncRNA) from TEs is needed for the production of TE-targeting small RNAs and/or recruiting the silencing machinery to TEs. Hence, specialized RNA polymerase II (Pol II) transcription machinery is required for such unconventional transcription in different organisms. Indeed, the developmental stage-specific Mediator complex (Med)-associated proteins play essential roles in the ncRNA transcription from TE-related sequences in Tetrahymena. Yet it remains unknown how those Med-associated proteins are linked to the TE transcription by Pol II. Here, have found that Pol II is regulated by Emit3, a stage-specific, TFIIB-like protein specialized in TE transcription. Hence, to find out potential interactions, we did LC-MS/MS analysis for immunoprecipitation samples of Emit3 and the zinc-ribbon mutated Emit3.

Project description:East African cichlid fishes have radiated in an explosive fashion. The (epi)genetic basis for the abundant phenotypic diversity of these fishes remains largely unknown. As transposable elements (TEs) contribute extensively to genome evolution, we reasoned that TEs may have fuelled cichlid radiations. While TE-derived genetic and epigenetic variability has been associated with phenotypic traits, TE expression and epigenetic silencing remain unexplored in cichlids. Here, we profiled TE expression in African cichlids, and describe dynamic expression patterns during embryogenesis and according to sex. Most TE silencing factors are conserved and expressed in cichlids. We describe an expansion of two truncated Piwil1 genes in Lake Malawi/Nyasa cichlids, encoding a Piwi domain with catalytic potential. To further dissect epigenetic silencing of TEs, we focused on small RNA-driven epigenetic silencing. We detect a small RNA population in gonads consistent with an active Piwi-interacting RNA (piRNA) pathway targeting TEs. We uncover fluid genomic origins of piRNAs in closely related cichlid species. This, along with signatures of positive selection in piRNA pathway factors, points towards fast co-evolution of TEs and the piRNA pathway. Our study is the first step to understand the contribution of ongoing TE-host arms races to the cichlid radiations in Africa.

Project description:In this study we leveraged several lines of AD patient derived induced Pluripotent Stem Cells (iPSCs) and differentiated them into hippocampal neuronal progenitors, hippocampal CA3 neurons and cerebral organoids.  Our goals were to i) investigate the transcriptional networks altered in the AD lines at the different developmental stages (progenitors, neurons, organoids), ii) link the altered gene regulatory networks to aberrant AP-1 activity, and iii) to profile TEs aberrantly active in the AD lines, with the goal of identifying a mechanism for TE derepression and to unveil the consequences that this process has on neuronal physiology.  With these experiments, we demonstrate that many of the genes differentially expressed between the AD lines the healthy controls are c-JUN targets.  Further, we find that most of the aberrantly de-repressed TEs harbor the AP-1 binding motif, and that aberrant TE mobilization leads to cytoplasmic accumulation of RNA-DNA hybrids, observed both in the progenitors and in the organoids. Importantly this phenomenon elicits cGAS-STING activation and ultimately cell-death.  Notably, by using a c-JUN peptide that inhibits c-JUN phosphorylation, we demonstrate that c-JUN inhibition in the AD lines is sufficient to rescue the expression of many differentially expressed genes, and to significantly reduce aberrant TE mobilization, cytoplasmic RNA-DNA accumulation, cGAS-STING activation and cell death.  

Project description:Numerous studies over the past decade have elucidated a substantial set of long intergenic noncoding RNAs (lincRNAs). It has since become clear that lincRNAs constitute an important layer of genome regulation across a wide spectrum of species. Yet, the factors governing their evolution and origins remain relatively unexplored. One possible factor that may have shaped lincRNA biology are transposable elements (TEs). Here we set out to comprehensively characterize the TE content of lincRNAs relative to genomic averages and protein coding transcripts. Our analysis of the TE composition across 9241 human lincRNAs revealed that, in sharp contrast to protein coding genes, a striking majority (83%) of lincRNAs contain a TE, and TEs comprise 42% of lincRNA transcript sequences. LincRNA TE composition varies significantly from genomic averages, being depleted of LI and Alu elements and enriched for a broad class of endogenous retroviruses (ERVs). Furthermore, specific TE families occur in biased positions and orientations within lincRNAs, particularly at their transcription start sites, suggesting a role in the origin of those lincRNAs. Finally, we find that TEs can drive gene expression regulation of lincRNAs—we observed a dramatic correlation between lincRNAs containing HERVH elements and almost exclusive expression in pluripotent cells. Conversely, those lincRNAs that are devoid of TEs are more highly expressed in testis. Collectively, TEs pervade lincRNAs and have shaped lincRNA evolution and function via bestowing tissue-specific expression from donated transcriptional regulatory signals. We extracted profiled the transcriptome expression polyadenylated mRNA-Seq. We then used these to reconstruct the transcriptome using de-novo assemblers and identify long non coding RNAs and their expression.

Project description:CRISPR/Cas systems have gained prominence as powerful tools for genome engineering. Recent investigations into the crucial role of transposable elements (TEs) have stimulated research interest in manipulating TEs to elucidate their functions. Nevertheless, designing single guide RNAs (sgRNAs) that are both specific and efficient for TE manipulation presents a formidable challenge, considering the repetitive nature and high copy numbers of TEs. Although various sgRNA design tools have been developed for gene editing, an optimized sgRNA designer explicitly for TE manipulation has yet to be established. To bridge this gap, we presented CRISPR-TE, a web-based application featuring an accessible graphical user interface, available at https://www.crisprte.cn. CRISPR-TE could identify all potential sgRNAs for TEs and offers a comprehensive solution for efficient TE targeting at both the single duplicate and subfamily levels. We also demonstrated that young TEs can be targeted with higher coverage at the subfamily level. Finally, we validated the overexpression of SVAD, a human-specific TE, using dCas9-VP64 activator incorporated with three sgRNAs designed by our tool. Collectively, our findings suggest that CRISPR-TE may serve as a versatile framework for designing sgRNAs aimed at TE targeting.