Detection of Alu Exonization Events in Human Frontal Cortex From RNA-Seq Data

Retrotransposon SINEs in age-related diseases: Mechanisms and therapeutic implications

Retrotransposons are self-replicating genomic elements that move from one genomic location to another using a "copy-and-paste" method involving RNA intermediaries. One family of retrotransposon that has garnered considerable attention for its association with age-related diseases and anti-aging interventions is the short interspersed nuclear elements (SINEs). This review summarizes current knowledge on the roles of SINEs in aging processes and therapies. To underscore the significant research on the involvement of SINEs in aging-related diseases, we commence by outlining compelling evidence on the classification and mechanism, highlighting implications in age-related phenomena. The intricate relationship between SINEs and diseases such as neurodegenerative disorders, heart failure, high blood pressure, atherosclerosis, type 2 diabetes mellitus, osteoporosis, visual system dysfunctions, and cancer is explored, emphasizing their roles in various age-related diseases. Recent investigations into the anti-aging potential of SINE-targeted treatments are examined, with particular attention to how SINE antisense RNA mitigate age-related alterations at the cellular and molecular levels, offering insights into potential therapeutic targets for age-related pathologies. This review aims to compile the most recent advances on the multifaceted roles of SINE retrotransposons in age-related diseases and anti-aging interventions, providing valuable insights into underlying mechanisms and therapeutic avenues for promoting healthy aging.

The role of transposable elements in human evolution and methods for their functional analysis: current status and future perspectives

Transposable elements (TEs) are mobile DNA sequences that can insert themselves into various locations within the genome, causing mutations that may provide advantages or disadvantages to individuals and species. The insertion of TEs can result in genetic variation that may affect a wide range of human traits including genetic disorders. Understanding the role of TEs in human biology is crucial for both evolutionary and medical research. This review discusses the involvement of TEs in human traits and disease susceptibility, as well as methods for functional analysis of TEs.

Predicting Alu exonization in the human genome with a deep learning model

Alu exonization, or the recruitment of intronic Alu elements into gene sequences, has contributed to functional diversification; however, its extent and the ways in which it influences gene regulation are not fully understood. We developed an unbiased approach to predict Alu exonization events from genomic sequences implemented in a deep learning model, eXAlu, that overcomes the limitations of tissue or condition specificity and the computational burden of RNA-seq analysis. The model captures previously reported characteristics of exonized Alu sequences and can predict sequence elements important for Alu exonization. Using eXAlu, we estimate the number of Alu elements in the human genome undergoing exonization to be between 55-110K, 11-21 fold more than represented in the GENCODE gene database. Using RT-PCR we were able to validate selected predicted Alu exonization events, supporting the accuracy of our method. Lastly, we highlight a potential application of our method to identify polymorphic Alu insertion exonizations in individuals and in the population from whole genome sequencing data.

Regulation of human interferon signaling by transposon exonization

Innate immune signaling is essential for clearing pathogens and damaged cells, and must be tightly regulated to avoid excessive inflammation or autoimmunity. Here, we found that the alternative splicing of exons derived from transposable elements is a key mechanism controlling immune signaling in human cells. By analyzing long-read transcriptome datasets, we identified numerous transposon exonization events predicted to generate functional protein variants of immune genes, including the type I interferon receptor IFNAR2. We demonstrated that the transposon-derived isoform of IFNAR2 is more highly expressed than the canonical isoform in almost all tissues, and functions as a decoy receptor that potently inhibits interferon signaling including in cells infected with SARS-CoV-2. Our findings uncover a primate-specific axis controlling interferon signaling and show how a transposon exonization event can be co-opted for immune regulation.

Alu-minating the Mechanisms Underlying Primate Cortex Evolution

The higher-order cognitive functions observed in primates correlate with the evolutionary enhancement of cortical volume and folding, which in turn are driven by the primate-specific expansion of cellular diversity in the developing cortex. Underlying these changes is the diversification of molecular features including the creation of human and/or primate-specific genes, the activation of specific molecular pathways, and the interplay of diverse layers of gene regulation. We review and discuss evidence for connections between Alu elements and primate brain evolution, the evolutionary milestones of which are known to coincide along primate lineages. Alus are repetitive elements that contribute extensively to the acquisition of novel genes and the expansion of diverse gene regulatory layers, including enhancers, alternative splicing, RNA editing, and microRNA pathways. By reviewing the impact of Alus on molecular features linked to cortical expansions or gyrification or implications in cognitive deficits, we suggest that future research focusing on the role of Alu-derived molecular events in the context of brain development may greatly advance our understanding of higher-order cognitive functions and neurologic disorders.

Association of Sat-a and Alu methylation status with HCV-induced chronic liver disease and hepatocellular carcinoma

BACKGROUND

The combination of epigenetic and genetic abnormalities contributes together to the development of liver cancer. The methylation status of the repetitive elements (REs) in DNA has been investigated in a variety of human illnesses. However, the methylation patterns of Sat-α and Alu REs in chronic liver disease (CLD) and hepatocellular carcinoma (HCC) caused by hepatitis C virus (HCV) have never been studied before.

METHODOLOGY

In this study, 3 groups of participants including 50 patients having HCV-induced CLD, 50 patients having HCV-induced HCC, and 46 healthy subjects were subjected to measurement of Sat-α and Alu methylation using the quantitative MethyLight assay.

RESULTS

Sat-α and Alu methylation percentages decreased significantly in both CLD and HCC, compared to control. Also, a significant Sat-α hypomethylation was detected in HCC, compared to CLD. In addition, Sat-α and Alu methylation showed a significant decline as lesion size grew. However, only Sat-α hypomethylation was significantly increased in association with portal vein thrombosis and the MELD score. Sat-α methylation percentage had the highest sensitivity and specificity for diagnosing HCC (100% and 84.4%) followed by α-fetoprotein (80% and 84.4%) and Alu methylation (66% and 61.5%). Furthermore, there was a strong positive correlation between Sat-α and Alu methylation.

CONCLUSIONS

Measuring Sat-α and Alu methylation provides us with a new tool for early detecting HCV-induced CLD and hepatocarcinogenesis. Sat-α has the potential to be utilized as an independent predictive parameter for HCC development and progression because of its ability to distinguish between CLD and HCC with their different MELD scores.

ExoPLOT: Representation of alternative splicing in human tissues and developmental stages with transposed element (TE) involvement

Advances in RNA high-throughput sequencing and large-scale functional assays yield new insights into the multifaceted activities of transposed elements (TE) and many other previously undiscovered sequence elements. Currently, no tool for easy access, analysis, quantification, and visualization of alternatively spliced exons across multiple tissues or developmental stages is available. Also, analysis pipelines demand computational skills or hardware requirements, which often are hard to meet by wet-lab scientists. We developed ExoPLOT to enable simplified access to massive RNA high throughput sequencing datasets to facilitate the analysis of alternative splicing across many biological samples. To demonstrate the functonality of ExoPLOT, we analyzed the contributon of exonized TEs to human coding sequences (CDS). mRNA splice variants containing the TE-derived exon were quantified and compared to expression levels of TE-free splice variants. For analysis, we utilized 313 human cerebrum, cerebellum, heart, kidney, liver, ovary, and testis transcriptomes, representing various pre- and postnatal developmental stages. ExoPLOT visualizes the relative expression levels of alternative transcripts, e.g., caused by the insertion of new TE-derived exons, across different developmental stages of and among multiple tissues. This tool also provides a unique link between evolution and function during exonization (gain of a new exon) and exaptation (recruitment/co-optation) of a new exon. As input for analysis, we derived a database of 1151 repeat-masked, exonized TEs, representing all prominent families of transposons in the human genome and the collection of human consensus coding sequences (CCDS). ExoPLOT screened preprocessed RNA high-throughput sequencing datasets from seven human tissues to quantify and visualize the dynamics in RNA splicing for these 1151 TE-derived exons during the entire human organ development. In addition, we successfully mapped and analyzed 993 recently described exonized sequences from the human frontal cortex onto these 313 transcriptome libraries. ExoPLOT's approach to preprocessing RNA deep sequencing datasets facilitates alternative splicing analysis and significantly reduces processing times. In addition, ExoPLOT's design allows studying alternative RNA isoforms other than TE-derived in a customized - coordinate-based manner and is available at http://retrogenomics3.uni-muenster.de:3838/exz-plot-d/.

Comprehensive In Silico Analysis of Retrotransposon Insertions within the Survival Motor Neuron Genes Involved in Spinal Muscular Atrophy

Transposable elements (TEs) are interspersed repetitive and mobile DNA sequences within the genome. Better tools for evaluating TE-derived sequences have provided insights into the contribution of TEs to human development and disease. Spinal muscular atrophy (SMA) is an autosomal recessive motor neuron disease that is caused by deletions or mutations in the Survival Motor Neuron 1 (SMN1) gene but retention of its nearly perfect orthologue SMN2. Both genes are highly enriched in TEs. To establish a link between TEs and SMA, we conducted a comprehensive, in silico analysis of TE insertions within the SMN1/2 loci of SMA, carrier and healthy genomes. We found an Alu insertion in the promoter region and one L1 element in the 3'UTR that may play an important role in alternative promoter as well as in alternative transcriptional termination. Additionally, several intronic Alu repeats may influence alternative splicing via RNA circularization and causes the presence of new alternative exons. These Alu repeats present throughout the genes are also prone to recombination events that could lead to SMN1 exons deletions and, ultimately, SMA. TE characterization of the SMA genomic region could provide for a better understanding of the implications of TEs on human disease and genomic evolution.