MIR193BHG: a novel hypoxia-inducible long noncoding RNA involved in the fine-tuning of cholesterol metabolism

Wu, Xue

22 September 2016

Indiana University-Purdue University Indianapolis (IUPUI) / The human genome generates a vast number of functionally and structurally diverse noncoding transcripts, incorporated into complex networks which modulate the activity of classic pathways. Long noncoding RNAs (lncRNA) have been shown to exhibit diverse regulatory roles in various physiological and pathological processes. Hypoxia, a key feature of the tumor microenvironment, triggers adaptive responses in cancer cells that involve hundreds of genes. While the coding component of hypoxia signaling has been extensively studied, much less information is available regarding its noncoding arm. My doctoral work identified and functionally characterized a novel hypoxia-inducible lncRNAs encoded from the miR193b-host gene (MIR193BHG) locus, on chromosome 16. In the pursuit of understanding how MIR193BHG responds to hypoxia, we discovered a more complex transcriptional control of MIR193BHG by hypoxia. Ectopic expression of MIR193BHG in breast cancer cell lines in vitro and in xenografts significantly represses cell invasion, as well as the metastasis to lung and liver. Conversely, inhibition of MIR193BHG promotes cancer cell invasiveness and metastasis. RNAseq followed by pathway analysis revealed that MIR193BHG is a negative modulator of cholesterol biosynthesis pathway. MIR193BHG exerts a highly coordinated effect on the expression of cholesterol biosynthetic genes which leads to a measurable impact on the total cellular cholesterol content. The role of MIR193BHG in cholesterol metabolism also provided a mechanistic explanation for the sex maturation associated SNPs located in vicinity of this gene locus. Our work also provided preliminary insights into the functional mechanism of MIR193BHG by showing that its modulation of genes in cholesterol synthesis is predominantly at transcriptional level. Overall, my dissertation project identified a non-canonical hypoxia-inducible lncRNA, MIR193BHG, which modulates breast cancer invasion and metastasis via finetuning of cholesterol synthesis.

Cancer

Cholesterol

Hypoxia

Long noncoding RNA

Metabolism

Integrative Characterization of Human Long Non-Coding RNAs

Cabili, Nataly Moran

04 June 2015

Since its early discovery as a messenger, RNA has been shown to play a diverse set of regulatory, structural and even catalytic roles. The more recent understanding that the genome is pervasively transcribed stimulated the discovery of a new prevalent class of long non coding RNAs (lncRNAs). While these are lower abundant and relatively less conserved than other class of functional RNAs, lncRNAs are emerging as key players in different cellular processes in development and disease.

Systematic biology

Bioinformatics

Biology

lincRNA

lncRNA

long noncoding-RNA

Functional long non-coding RNA transcription in Schizosaccharomyces pombe

Ard, Ryan Anthony

January 2016

Eukaryotic genomes are pervasively transcribed and frequently generate long noncoding RNAs (lncRNAs). However, most lncRNAs remain uncharacterized. In this work, a set of positionally conserved intergenic lncRNAs in the fission yeast Schizosaccharomyces pombe genome are selected for further analysis. Deleting one of these lncRNA genes (ncRNA.1343) exhibited a clear phenotype: increased drug sensitivity. Further analyses revealed that deleting ncRNA.1343 also disrupted a previously unannotated lncRNA, termed nc-tgp1, transcribed in the opposite orientation of the predicted ncRNA.1343 gene and into the promoter of the phosphate-responsive permease gene tgp1+. Detailed analyses revealed that the act of transcribing nc-tgp1 into the tgp1+ promoter increases nucleosome density and prevents transcription factor access. Decreased nc-tgp1 transcription permits tgp1+ expression upon phosphate starvation, while nc-tgp1 loss induces tgp1+ in repressive phosphate-rich conditions. Notably, drug sensitivity results directly from tgp1+ expression in the absence of nc-tgp1 transcription. Similarly, lncRNA transcription upstream of pho1+, another phosphate-regulated gene, increases nucleosome density and prevents transcription factor binding to repress pho1+ in phosphate-replete cells. Importantly, the regulation of tgp1+ and pho1+ by upstream lncRNA transcription occurs in the absence of RNAi and heterochromatin components. Instead, the regulation of tgp1+ and pho1+ by upstream lncRNA transcription resembles examples of transcriptional interference reported in other organisms. Thus, tgp1+ and pho1+ are the first documented examples of genes regulated by transcriptional interference in S. pombe.

572.8

Computational Framework for the Dissection of Cancer Genomic Architecture and its Association in Different Biomarkers / がんゲノム構造およびその複数バイオマーカーの関連を解明するための計算論的アプローチ

Sohiya, Yotsukura

23 September 2016

京都大学 / 0048 / 新制・課程博士 / 博士(薬科学) / 甲第19974号 / 薬科博第65号 / 新制||薬科||7(附属図書館) / 33070 / 京都大学大学院薬学研究科医薬創成情報科学専攻 / (主査)教授 馬見塚 拓, 教授 緒方 博之, 教授 掛谷 秀昭 / 学位規則第4条第1項該当 / Doctor of Pharmaceutical Sciences / Kyoto University / DFAM

long-noncoding RNA

mutations

bioinformatics

algorithms

machine learning

499.3

Elucidating the role of the long noncoding RNA, Gtl2, in rodent models of cardiac disease

Hook, Heather

31 July 2017

Recently, the discovery of noncoding RNAs (ncRNAs), such as long noncoding RNAs (lncRNAs) has altered the traditional view of gene regulation. Sequencing of genomes has brought to light the vast stretches of non-protein coding DNA regions that transcribe non-protein coding RNA. LncRNAs are multifunctional and extremely diverse. They can act as signals, decoys, scaffolds, guides, or enhancers. Several lncRNAs, such as Fendrr and Bvht, have been found to have important regulatory functions in cardiac disease and development. The Glt2-Dio3 locus, which is enriched in cardiac muscle, harbors two long intragenic RNAs, MEG3 and MEG8, and harbors one of the largest mammalian miRNA clusters. MEG3, which is termed Gtl2 in rat and mouse, contain 10 exons that are alternatively spliced and give rise to several variants. Gtl2 is conserved across human, rat, and mouse, which makes it an ideal candidate for research and a possible target for therapies. Based on the growing evidence for lncRNAs playing a role in cardiac muscle and our research on the Gtl2-Dio3 microRNAs (miRNAs), I focused on investigating the Gtl2 lncRNA in the heart. Antisense oligonucleotides (GapmeRs) were used to knockdown Gtl2 lncRNA expression levels in cultured, primary neonatal cardiomyocytes in basal and hypertrophic conditions. Although Gtl2 was effectively knocked down in basal conditions I was unable to achieve efficient knockdown in hypertrophic cardiomyocytes induced by phenylephrine treatment. Consequently, I did not observe any modulation of hypertrophy as determined by changes in the expression of Nppa and Nppb, established markers of cardiomyocyte hypertrophy.. Next, I utilized short hairpin RNA (shRNA) to knockdown Gtl2 lncRNA expression levels and obtained robust knockdown. Lastly, I designed a cardiac tropic adeno-associated virus 9 (AAV9) encoding MEG3 DNA for in vivo overexpression experiments as well as an adenovirus encoding MEG3 for in vitro overexpression experiments. These reagents will provide valuable resources for dissecting the functions of the Gtl2 lncRNA. Studies investigating the roles of Gtl2 in the diseased heart my lead to the development of other potential therapies to treat cardiac disease.

Molecular biology

Cardiac disease

Long noncoding RNA

Translation

Characterization of a transcript found within the HBS1L-MYB intergenic region and its role in hemoglobin regulation in erythroid cells

Morrison, Tasha Alease

01 November 2017

Sickle cell disease (SCD) is one of the most common hemoglobinopathies worldwide. It is caused by a homozygous mutation in codon 6 of the beta globin gene (HBB), which leads to polymerization of the variant hemoglobin and sickled red blood cells that obstruct blood vessels and reduce oxygen delivery to tissues. Patients with SCD have multiple clinical problems, including pain crises, anemia and organ damage. However, not all patients with SCD display all these clinical manifestations. One major factor for reduced occurrences of symptoms is fetal hemoglobin (HbF). HbF is the main hemoglobin in the fetus, and declines one year after birth to less than one percent of total hemoglobin. Nevertheless, there are individuals who continue to have high levels of HbF into adulthood, which is beneficial for an individual with SCD because HbF reduces the amount of sickle polymer in red blood cells. There are three major quantitative trait loci (QTL) associated with high HbF. However, these QTL account for 20-45% of HbF variance. Therefore, further investigation is required to fully understand how HbF is regulated. The HBS1L-MYB intergenic polymorphism (HMIP) on chromosome 6q23 is one of the major QTL associated with high HbF. This region is also known to regulate other erythroid-specific traits due to an enhancer element that promotes the expression of the downstream gene, MYB, which controls hemoglobin expression and erythroid proliferation and maturation. The presence of RNA polymerase II binding and a 50-bp transcript suggested that a long noncoding RNA (lncRNA) is transcribed from this region. LncRNAs are non-protein-coding transcripts greater than 200 nucleotides and are involved in gene regulation. Therefore, it was hypothesized that a lncRNA is transcribed from the enhancer of MYB and regulates hemoglobin expression. I characterized a novel lncRNA, 1283 bp in length that was differentially expressed among various tissue types, among erythroid progenitor cells with different hemoglobin makeup, and also during erythroid differentiation. Furthermore, knockdown of this lncRNA, named the HBS1L-MYB intergenic long noncoding RNA (HMI-LNCRNA), significantly increased HbF. Taken together, these observations suggest that HMI-LNCRNA can be a possible therapeutic target to increase HbF expression in patients with SCD and β-thalassemia. / 2018-05-01T00:00:00Z

Molecular biology

Fetal hemoglobin

Long noncoding RNA

Sickle cell disease

Molecular characterization and functional analysis of a novel long noncoding RNA in the mouse

Joshi, Parth Devesh

25 February 2019

No description available.

570

Biologie (PPN619462639)

ANTISENSE AFP TRANSCRIPTS IN MOUSE LIVER AND THEIR POTENTIAL ROLE IN AFP GENE REGULATION

Dixon, Maria S.

01 January 2017

Hepatocellular carcinoma (HCC) is the most common form of primary liver cancer, ranking the sixth most common cancer and third most common cause of cancer mortality worldwide. Alpha-fetoprotein (AFP) is a plasma protein that is highly expressed in the fetal liver and shut off after birth. AFP expression is elevated in regenerating adult liver and HCC and has been used extensively as a diagnostic marker of liver cancer. We have been studying mouse liver gene regulation to better understand mechanisms by which changes in gene expression contribute to liver development, homeostasis and disease. Zinc Fingers and Homeoboxes 2 (Zhx2) has been identified as a repressor of AFP, but the mechanism of this regulation remains unknown. Interestingly, all targets of Zhx2 that have been identified to date, including H19, Glypican 3, Elovl3 and Cytochrome P450 (CYP) genes, are also known to be misregulated in HCC. Thus, a better understanding of the mechanism by which these genes are regulated by Zhx2 will likely lead to new insights into gene regulation during HCC progression. Antisense transcripts belong to a diverse class of long noncoding RNA molecules > 200 nucleotides in length that often structurally resemble mRNAs, but do not encode proteins. While studying AFP mRNA regulation by Zhx2 in the mouse, our lab identified novel antisense AFP (asAFP) RNA transcripts that partially overlap the 3’ half of the mouse AFP gene. ENCODE tracks of ChIP-seq data for histone modifications in mouse liver show that the genomic region around the 5’ end of asAFP RNA has peaks for marks associated with promoters and enhancers. To better understand asAFP regulation, I identified the asAFP RNA 5’ end and the promoter elements that drive transcription. asAFP RNAs are ~5kb alternatively spliced, mainly cytoplasmic transcripts containing 2-4 exons. These transcripts were also detected in adult mouse liver RNA-seq data. asAFP is likely a noncoding RNA because it contains several small open reading frames that are 98 aa or smaller with no known functional domains or homology to known proteins. There is no evidence for similar transcripts in human liver. The abundance of asAFP RNA inversely correlates with AFP mRNA levels during postnatal liver development. Normally, asAFP RNA levels are high and AFP mRNA levels are low in the adult mouse liver. However, in the absence of Zhx2, AFP mRNA levels are higher and asAFP RNA levels are reduced, suggesting asAFP may be involved in the developmental regulation of AFP. Antisense transcripts function through a variety of mechanisms to positively or negatively regulate the expression of target genes. To explore the role of asAFP RNA in AFP gene regulation, I expressed segments of asAFP RNA in a mouse liver cell line and measured endogenous AFP mRNA levels. My data revealed that all segments of asAFP repressed endogenous AFP mRNA in trans. To determine the mechanism by which asAFP RNA regulates AFP, I expressed asAFP segments that overlapped only with exons or introns of AFP. The asAFP segments that overlap with the exons showed greater repression of endogenous AFP mRNA levels than those overlapping with intronic sequences. Additionally, I considered whether asAFP RNA repression of AFP mRNA may involve RNA editing by Adenosine deaminase acting on RNA (ADAR). ADARs convert adenosine to inosine in double-stranded RNAs that results in RNA degradation. My data indicate that AFP and asAFP dsRNA is not extensively edited, suggesting ADAR mediated decay is not involved in the regulation of AFP mRNA expression. However, further studies are required to determine the mechanism of cytoplasmic AFP mRNA degradation. Together, my data characterizes the transcriptional regulation of novel mouse asAFP transcripts and provides a model system to investigate how these transcripts regulate AFP mRNA through RNA-RNA interaction.

Long noncoding RNA

gene regulation

asAFP

AFP

RNA-RNA interaction

Molecular Genetics

Lionheart LincRNA alleviates cardiac systolic dysfunction under pressure overload / 長鎖非コードRNA Lionheartは圧負荷による心機能低下を緩和する

Tsuji, Shuhei

23 March 2021

京都大学 / 新制・課程博士 / 博士(医学) / 甲第23060号 / 医博第4687号 / 新制||医||1048(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 齊藤 博英, 教授 湊谷 謙司, 教授 萩原 正敏 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

long noncoding RNA

heart failure

cardiac hypertrophy

pressure overload

myosin heavy chain

490

O gene Aire pode controlar mRNAs bem como os lncRNAs em células tímicas epiteliais medulares como evidenciado pela edição do genoma por CRISPR-Cas9 / Aire gene can control mRNAs as well as lncRNAs in medullary thymic epitelial cells as evidentiated by genome editing by CRISPR-Cas9

Duarte, Max Jordan de Souza

26 November 2018

O timo é um órgão linfoide primário essencial para a manutenção da tolerância central através da seleção e eliminação de células T autoreativas. Precursores de células T, oriundas da medula óssea, chegam ao timo e migram do córtex para região da medula. As células epiteliais medulares tímicas (mTECs) expressam em sua superfície antígenos de tecidos periféricos (em inglês tissue-restricted antigens ou TRAs) que representam autoantígenos de todos os tecidos do corpo. Atuando como um fator de transcrição não clássico em células mTEC, o gene Autoimmune Regulator (Aire) desempenha um papel na expressão dos TRAs, cuja proteína codificada libera a RNA polimerase II (RNA Pol II) ancorada na cromatina e regula a expressão de mRNAs na glândula timo. A função biológica deste gene está ligada à indução de tolerância imunológica central impedindo o aparecimento de doenças autoimunes. Isso é resultado da seleção negativa de timócitos (precursores de células T) autoreativos que interagem fisicamente com as mTECs. Os timócitos autoreativos que reconhecem os TRAs como elementos estranhos são eliminados por apoptose. O co-cultivo de mTECs com timócitos representa um sistema-modelo in vitro adequado para se aproximar da interação celular que ocorre dentro do timo. Os resultados anteriores do nosso laboratório demonstraram que além do controle de mRNA de TRAs, o gene Aire também participa da modulação de miRNAs em mTECs uma vez que estas espécies de RNA são transcritas pela RNA Pol II. Continuando com essa linha de estudos, neste trabalho nós demonstramos pela primeira vez que Aire também modula a expressão de long noncoding RNAs (lncRNAs) em mTECs. Para isto fizemos uso da estratégia da perda de função analisando a expressão dessa espécie de RNA, assim como de mRNAs, em células mTEC Aire +/+ e mTEC Aire nocautes (KO Aire -/-) obtidas pela edição gênica por Crispr-Cas9. O transcriptoma dessas células que passaram ou não por adesão com timócitos, foi então analisado por hibridizações com microarrays. Isso evidenciou que Aire e adesão celular influenciam a expressão tanto de mRNAs como de lncRNAs. A reconstrução de redes de interação lncRNAs-mRNAs possibilitou evidenciar uma nova via de regulação pós-transcricional em células mTEC. / The thymus is a primary lymphoid organ essential for the maintenance of central tolerance through the selection and elimination of autoreactive T cells. Precursors of T cells, originating from the bone marrow, reach the thymus and migrate from the thymic cortex to the medullary region. Thymic medullary epithelial cells (mTECs) express on their surface tissue-restricted antigens (TRAs) that represent autoantigens of all tissues in the body. Acting as a non-classical transcription factor in mTEC cells, the Autoimmune regulator (Aire) gene plays a role in the expression of TRAs, whose encoded protein releases the RNA polymerase II (RNA Pol II) anchored in the chromatin and regulates the expression of mRNAs in the thymus gland. The biological function of this gene is associated to the induction of central immune tolerance preventing the onset of autoimmune diseases. This is a result of negative selection of autoreactive thymocytes (T cell precursors) that interact physically with mTECs. Self-reactive thymocytes that recognize TRAs as foreign elements are eliminated by apoptosis. The co-culture of mTECs with thymocytes represents an appropriate in vitro model system to approximate the cellular interaction that occurs within the thymus. Previous results from our laboratory demonstrated that in addition to the control of TRA mRNAs, Aire also participates in the modulation of miRNAs in mTECs since these RNA species are transcribed by RNA Pol II. Continuing with this line of studies, in this study we demonstrate for the first time that Aire also modulates the expression of long non-coding RNAs (lncRNAs) in mTECs. For this, we used the loss-of-function strategy to analyze the expression of this RNA species, as well as mRNAs in mTEC Aire + / + or Aire knockout mTEC cells (KO Aire - / -) obtained by the gene editing by Crispr-Cas9. The transcriptome of these cells, whether or not adhered to thymocytes, was then analyzed by microarray hybridizations. This demonstrated that Aire and cell adhesion influence the expression of both mRNAs and lncRNAs. The reconstruction of lncRNAs-mRNAs interaction networks made possible to evidence a new post-transcriptional regulation pathway in mTEC cells.

Adesão Celular

Autoimmune Regulator (AIRE)

Cell adhesion

CRISPR-Cas9

CRISPRCas9

Expressão Gênica

Gene Autoimmune Regulator (Aire)

Gene expression

Long noncoding RNA

Long noncoding RNA