Using Bioinformatic Tools to Identify Genes and microRNAs Associated with mild Traumatic Brain Injury Outcomes

Tajik, Mahnaz

January 2023

A mild traumatic brain injury (mTBI), commonly referred to as a concussion, is when the brain experiences an abrupt acceleration and/or deceleration that sends shock waves through the brain tissue, upsetting its structure and function. A mTBI is a heterogeneous condition with acute and chronic outcomes for patients. The chronic form of mTBI can lead to a wide range of neurological, behavioral, and cognitive symptoms. Critically, this injury is not defined by a simple process or pathophysiological event but rather biomechanical and neurological brain damage that can trigger highly complex physiological cascades. These further lead to a wide range of cellular, molecular, and functional changes that alter genes and associated metabolites. These changes, if specifically characterized, could be used to predict a patient’s outcome and recovery timeline. Recently, genetic studies showed that specific genotypes could increase an individual’s risk of more severe injury and impaired recovery following mTBI. Consequently, an improved understanding of gene alteration and genetic changes is necessary to develop personalized diagnostic approaches which can guide the design of novel treatments. The current study proposes utilizing bioinformatic tools, biological networks, and databases to identify potential genes and microRNAs associated with the mTBI in order to aid the early diagnosis of mTBI and track recovery for individual patients. With bioinformatic techniques, we were able to identify and compare genetic and epigenetic data associated with mTBI, as well as understand the various aspects of molecular changes after brain injury. Ultimately, we analyzed and cataloged the biological pathways and networks associated with this injury. A critical search of online bioinformatics databases was performed to determine interactions between mTBI-related genes, and relevant molecular processes. The major finding was that APOE, S100B, GFAP, BDNF, AQP4, COMT, MBP, UCHL1, DRD2, ASIC1, and CACNA1A genes were significantly associated with mTBI outcome. Those genes are primarily involved in different neurological tasks and neurological pathways such as neuron projection regeneration, regulation of neuronal synaptic plasticity, cognition, memory function, neuronal cell death and the dopaminergic pathway. This study predicted specific miRNAs linked to mTBI outcomes and candidate genes (hsa-miR-204-5p, hsa-miR-16-5p, hsa-miR-10a-5p, has-miR-218-5p, has-miR-34a-5p), and RNA-seq analysis on the GSE123336 data revealed that one miRNA found (hsa-miR-10a-5p) matched our predictions related to mTBI outcomes. Pathway analysis revealed that the predicted miRNA targets were mainly engaged in nervous system signaling, neuron projection and cell differentiation. These findings may contribute to developing diagnostic procedures and treatments for mTBI patients who are still experiencing symptoms, but validation of these genetic markers for mTBI assessment requires patient participation and correlation with advanced personalized MRI methods that show concussion related changes. / Thesis / Master of Applied Science (MASc) / Traumatic brain injury (TBI) is a highly prevalent neurological injury affecting millions of individuals globally. Mild TBI (mTBI), sometimes called concussion, makes up over 85% of TBI cases. A mTBI is a heterogeneous condition with acute and chronic outcomes for patients and involves complex cascades of cellular and molecular events that can lead to functional changes in genes and associated metabolites. In recent genetic studies, it has been shown that certain genotypes are associated with a higher risk of experiencing a more serious injury and a slower recovery after mTBI. These genes can be utilized as crucial biomarkers to predict how long it will take for a person to recover from a concussion. The purpose of this study was to find potential biomarkers that could help in the early detection of mTBI and the monitoring of individual patients’ recovery. It was hypothesized that genes and miRNAs (and their associated proteins) involved in neuronal body, axonal and myelin integrity and regeneration would be identified as important markers of severity.

Discovery and evolutionary dynamics of RBPs and circular RNAs in mammalian transcriptomes

Badve, Abhijit

30 March 2015

Indiana University-Purdue University Indianapolis (IUPUI) / RNA-binding proteins (RBPs) are vital post-transcriptional regulatory molecules in transcriptome of mammalian species. It necessitates studying their expression dynamics to extract how post-transcriptional networks work in various mammalian tissues. RNA binding proteins (RBPs) play important roles in controlling the post-transcriptional fate of RNA molecules, yet their evolutionary dynamics remains largely unknown. As expression profiles of genes encoding for RBPs can yield insights about their evolutionary trajectories on the post-transcriptional regulatory networks across species, we performed a comparative analyses of RBP expression profiles across 8 tissues (brain, cerebellum, heart, lung, liver, lung, skeletal muscle, testis) in 11 mammals (human, chimpanzee, gorilla, orangutan, macaque, rat, mouse, platypus, opossum, cow) and chicken & frog (evolutionary outgroups). Noticeably, orthologous gene expression profiles suggest a significantly higher expression level for RBPs than their non-RBP gene counterparts, which include other protein-coding and non-coding genes, across all the mammalian tissues studied here. This trend is significant irrespective of the tissue and species being compared, though RBP gene expression distribution patterns were found to be generally diverse in nature. Our analysis also shows that RBPs are expressed at a significantly lower level in human and mouse tissues compared to their expression levels in equivalent tissues in other mammals: chimpanzee, orangutan, rat, etc., which are all likely exposed to diverse natural habitats and ecological settings compared to more stable ecological environment humans and mice might have been exposed, thus reducing the need for complex and extensive post-transcriptional control. Further analysis of the similarity of orthologous RBP expression profiles between all pairs of tissue-mammal combinations clearly showed the grouping of RBP expression profiles across tissues in a given mammal, in contrast to the clustering of expression profiles for non-RBPs, which frequently grouped equivalent tissues across diverse mammalian species together, suggesting a significant evolution of RBPs expression after speciation events. Calculation of species specificity indices (SSIs) for RBPs across various tissues, to identify those that exhibited restricted expression to few mammals, revealed that about 30% of the RBPs are species-specific in at least one tissue studied here, with lung, liver, kidney & testis exhibiting a significantly higher proportion of species specifically expressed RBPs. We conducted a differential expression analysis of RBPs in human, mouse and chicken tissues to study the evolution of expression levels in recently evolved species (i.e., humans and mice) than evolutionarily-distant species (i.e., chickens). We identified more than 50% of the orthologous RBPs to be differentially expressed in at least one tissue, compared between human and mouse, but not so between human and an outgroup chicken, in which RBP expression levels are relatively conserved. Among the studied tissues (brain, liver and kidney) showed a higher fraction of differentially expressed RBPs, which may suggest hyper- regulatory activities by RBPs in these tissues with species evolution. Overall, this study forms a foundation for understanding the evolution of expression levels of RBPs in mammals, facilitating a snapshot of the wiring patterns of post-transcriptional regulatory networks in mammalian genomes. In our second study, we focused on elucidating novel features of post-transcriptional regulatory molecules called as circRNA from LongPolyA RNA-sequence data. The debate over presence of nonlinear exon splicing such as exon-shuffling or formation of circularized forms has finally come to an end as numerous repertoires have shown of their occurrence and presence through transcriptomic analyses. It is evident from previous studies that along with consensus-site splicing non-consensus site splicing is robustly occurring in the cell. Also, in spite of applying different high-throughput approaches (both computational and experimental) to determine their abundance, the signal is consistent and strongly conforming the plausible circularization mechanisms. Earlier studies hypothesized and hence focused on the ribo-minus non-polyA RNA-sequence data to identify circular RNA structures in cell and compared their abundance levels with their linear counterparts. Thus far, the studies show their conserved nature across tissues and species also that they are not translated and preferentially are without poly (A) tail, with one to five exons long. Much of this initial work has been performed using non-polyA sequencing thus probably underestimates the abundance of circular RNAs originating from long poly (A) RNA isoforms. Our hypothesis is if the circular RNA events are not the artifact of random events, but has a structured and defined mechanism for their formation, then there would not be biases on preferential selection / leaving of polyA tails, while forming the circularized isoforms. We have applied an existing computational pipeline from earlier studies by Memczack et. al., on ENCODE cell-lines long poly (A) RNA-sequence data. With the same pipeline, we achieve a significant number of circular RNA isoforms in the data, some of which are overlapping with known circular RNA isoforms from the literature. We identified an approach and worked upon to identify the precise structure of circular RNA, which is not plausible from the existing computational approaches. We aim to study their expression profiles in normal and cancer cell-lines, and see if there exists any pattern and functional significance based on their abundance levels in the cell.

RNA-protein interactions -- Research

Evolutionary genetics -- Research

Genomics -- Research

Gene expression -- Research

Genetic regulation -- Research

Computational biology -- Research

Genetic translation -- Research

Bioinformatics -- Research

Genetic transcription -- Regulation

RNA splicing

Nucleotide sequence -- Research