Project description:In this study, we discovered cytosolic and mitochondrial fragments resulting from tRNA and mt-tRNA cleavage, which may act as new regulators of cellular and metabolic functions. The so-called LP rat model consists of 22-day-old rats whose mothers have been subjected to a low protein diet during gestation and lactation. These offspring have impaired pancreatic development with reduced ß-cell mass, glucose-stimulated insulin secretion defect and are more prone to develop diabetes in adulthood. We identified hundreds of these fragments as being changed in the pancreatic islets of LP rats and compared them to chow diet (CD) exposed rats. In our analysis, we identified 6164 tRFs in the islets of LP rats, among which 256 exhibited significant changes (≥ 2 fold; adjusted p value ≤ 0.05) compared to controls. Of these, 113 tRFs showed increased levels, while 143 tRFs showed decreased levels in the LP rats. We focused our investigations on mitochondrial tRFs (mt-tRFs) that show significant alterations in both, adult pre-diabetic mice (db/db) and LP rats. We selected the mt-tRF-LeuTAA fragment for further investigation, as its level is reduced in the islets of db/db mice and LP rats, while being abundant in ß-cells. mt-tRF-LeuTAA fragment is derived from the cleavage of tRNA-LeuTAA encoded by the mitochondrial genome. We demonstrated that mt-tRF-LeuTAA acts as a key regulator of mitochondrial OXPHOS functions, mitochondrial membrane potential, the insulin secretory capacity of ß-cells, and the insulin sensitivity of myotube muscle cells.

Project description:In this study, we discovered cytosolic and mitochondrial fragments resulting from tRNA and mt-tRNA cleavage, which may act as new regulators of cellular and metabolic functions. We selected the mt-tRF-LeuTAA fragment derived from a tRNA encoded by the mitochondrial genome for further investigation, as its level is reduced in the islets of diabetes-susceptible animal models, while being abundant in ß-cells. mt-tRF-LeuTAA fragment is derived from the cleavage of tRNA-LeuTAA encoded by the mitochondrial genome. We demonstrated that mt-tRF-LeuTAA acts as a key regulator of mitochondrial OXPHOS functions, mitochondrial membrane potential, the insulin secretory capacity of ß-cells, and the insulin sensitivity of myotube muscle cells. We sought to investigate the downstream mechanisms activated by this fragment. To gain a comprehensive understanding, we conducted proteomic analyses on rat islets with silenced mt-tRF-LeuTAA for 72 hours. Inhibiting mt-tRF-LeuTAA led to significant differential expression of 642 proteins, cut-off adjusted p ≤ 0.05. To further investigate the cellular rearrangement associated with the inhibition of mt-tRF-LeuTAA, we conducted enrichment analysis using Gene Ontology Molecular Function terms on mass spectrometry data. At the protein level, there was a significant enrichment of mitochondrial pathways, such as oxidoreductase activity, ATPase activity, hydrogen transport, NADH dehydrogenase activity, cytochrome-c oxidase activity, and oxygen transport. To elucidate the mechanisms by which mt-tRF-LeuTAA operates, we also conducted pull-down experiments in insulin-secreting INS832/13 cells, followed by mass spectrometry using 3'-biotinylated mimic sequence oligonucleotides of mt-tRF-LeuTAA. Our analysis unveiled interactions between mt-tRF-LeuTAA and 24 proteins, meeting the criteria of a fold change ≥ 6 and an adjusted p-value ≤ 0.05. Notably, among these proteins, 13 are localized within the mitochondria and play significant roles in mitochondrial oxidative functions. Some of these key proteins include Suclg2, Nme3, Sdha, Lrpprc, and Ndufa12. Pathway enrichment analysis of the binding partners associated with the mitochondrial fragment mt-tRF-LeuTAA indicates an over-representation of signaling pathways crucial to maintaining mitochondrial metabolism. These pathways include oxidative phosphorylation (OXPHOS), ROS-induced stress responses, the tricarboxylic acid (TCA) cycle, calcium homeostasis regulation, lipid metabolism, RNA splicing, and mitochondrial import, which all contribute fundamentally to the maintenance of mitochondrial metabolism. These findings collectively provide insights into the essential mechanisms underlining the functionality of mitochondrially-encoded tRNA-derived fragments with the view to sustaining mitochondrial metabolism.

Project description:In this study, we discovered cytosolic and mitochondrial fragments resulting from tRNA and mt-tRNA cleavage, which may act as new regulators of cellular and metabolic functions. We analyzed hundreds of these fragments in the pancreatic islets of db/db mice and compared them to heterozygous control db/+ mice. At 16 weeks of age, db/db mice exhibit obesity, insulin resistance, and glucose intolerance. In our analysis, we identified 3858 tRFs in the islets of db/db mice, among which 342 exhibited significant changes (≥ 2 fold; adjusted p value ≤ 0.05) compared to controls. Of these, 199 tRFs showed increased levels, while 170 tRFs showed decreased levels in the pre-diabetic mice. Notably, a striking majority (147 out of 170) of the tRFs with reduced abundance in the islets of db/db mice were derived from the cleavage of tRNAs encoded by the mitochondrial genome. Our findings reveal a significant reshaping of mitochondrial tRFs in pre-diabetic conditions, coinciding with a well-established mitochondrial metabolic defect under these conditions. Specifically, we demonstrated that a fragment (named mt-tRF-LeuTAA) resulting from the cleavage of mt-tRNA-LeuTAA, encoded by the mitochondrial genome and found to be reduced in the islets of db/db mice, acts as a key regulator of mitochondrial OXPHOS functions, mitochondrial membrane potential, the insulin secretory capacity of ß-cells, and the insulin sensitivity of myotube muscle cells.

Project description:Silencing of mt-tRF-LeuTAA fragment in pancreatic rat islets and investigation by RNA-sequencing of the downstream mechanisms activated by this fragment

Project description:Small RNAs derived from mature tRNAs, referred to as tRNA fragments or “tRFs”, are an emerging class of regulatory RNAs with poorly understood functions in cellular regulation. We recently identified a role for one specific tRF – 5’ tRF-Gly-GCC, or tRF-GG – in repression of genes associated with the endogenous retroelement MERVL, but the mechanistic basis for this regulation was unknown. Here, we show that tRF-GG plays a role in production of a wide variety of noncoding RNAs normally synthesized in Cajal bodies. Among these noncoding RNAs, tRF-GG regulation of the U7 snRNA modulates heterochromatin-mediated transcriptional repression of MERVL elements by supporting an adequate supply of histone proteins. Importantly, the effects of inhibiting tRF-GG on histone mRNA levels, activity of a histone 3’ UTR reporter, and ultimately on MERVL regulation could all be suppressed by the U7 RNA. We show that the related RNA-binding proteins hnRNPF and H bind directly to tRF-GG, and are required for Cajal body biogenesis. Together, our data reveal a conserved mechanism for 5’ tRNA fragment control of noncoding RNA biogenesis and, consequently, in global chromatin organization.

Project description:Background: As couples struggle with infertility and livestock producers wish to rapidly improve genetic merit in their herd, assisted reproductive technologies (ART) have become increasingly popular in human medicine as well as the livestock industry. Utilizing ART can cause an increased risk of congenital overgrowth syndromes, such as Large Offspring Syndrome (LOS) in ruminants. A dysregulation of transcripts has been observed in bovine fetuses with LOS, which is suggested to be a cause of the phenotype. Our recent study identified variations in tRNA expression in LOS individuals, leading us to hypothesize that variations in tRNA expression can influence the availability of their processed regulatory products, tRNA-derived fragments (tRFs). Due to their resemblance in size to microRNAs, studies suggest that tRFs target mRNA transcripts and regulate gene expression. Thus, we have sequenced small RNA isolated from skeletal muscle and liver of day 105 bovine fetuses to elucidate the mechanisms contributing to LOS. Moreover, we have utilized our previously generated tRNA sequencing data to analyze the contribution of tRNA availability to tRF abundance. Results: 22,289 and 7,737 unique tRFs were predicted in the liver and muscle tissue respectively. The greatest number of reads originated from 5′ tRFs in muscle and 5′ halves in liver. In addition, mitochondrial (MT) and nuclear derived tRF expression was tissue-specific with most MT-tRFs and nuclear tRFs derived from LysUUU and iMetCAU in muscle, and AsnGUU and GlyGCC in liver. Despite variation in tRF abundance within treatment groups, we identified differentially expressed (DE) tRFs across Control-AI, ART-Normal, and ART-LOS groups with the most DE tRFs between ART-Normal and ART-LOS groups. Many DE tRFs target transcripts enriched in pathways related to growth and development in the muscle and tumor development in the liver. Finally, we found positive correlation coefficients between tRNA availability and tRF expression in muscle (R = 0.47) and liver (0.6). Conclusion: Our results highlight the dysregulation of tRF expression and its regulatory roles in LOS. These tRFs were found to target both imprinted and non-imprinted genes in muscle as well as genes linked to tumor development in the liver. Furthermore, we found that tRNA transcription is a highly modulated event that plays a part in the biogenesis of tRFs. This study is the first to investigate the relationship between tRNA and tRF expression in combination with ART-induced LOS.

Project description:tRNA fragments (tRFs) are a novel class of small RNAs comparable to the size and function of miRNAs. We and others have shown that tRFs are generally Dicer independent, can be found in abundance in the miRNA effector protein Ago, and can repress expression of specific genes that have complementarity to their 5’ seed-sequences. Given that this greatly expands the repertoire of small RNAs capable of post-transcriptional gene expression, it is important to predict tRF targets with confidence. Some attempts have been made to predict tRF targets, but are limited in the scope of tRF classes used in prediction or limited in feature selection. We hypothesized that established miRNA target prediction features applied to tRFs through a random forest machine learning algorithm will immensely improve tRF target prediction. Using this approach, we show significant improvements in tRF target prediction for all classes of tRFs and validate our predictions in two independent cell lines. Finally, using Gene Ontology analysis, we provide evidence that tRF-3009a targets may be involved in neural development. These improvements to tRF target prediction further our understanding of tRF function broadly across species and tRF types, and provide avenues for testing novel roles for tRFs in biology.

Project description:Argonaute/Piwi proteins associate with small RNAs that typically provide sequence specificity for RNP function in gene and genome regulation. Here we show that Twi12, a Tetrahymena Piwi protein essential for growth, is loaded with mature tRNA fragments. The tightly bound ~18-22 nt tRNA 3’ fragments are biochemically distinct from the tRNA halves produced transiently in response to stress. Notably, the end positions of Twi12-bound tRNA 3' fragments precisely match RNAs detected in total small RNA of mouse embryonic stem cells and human cancer cells. Our studies demonstrate unanticipated evolutionary conservation of mature tRNA processing to tRNA-fragment small RNAs.

Project description:Argonaute/Piwi proteins associate with small RNAs that typically provide sequence specificity for RNP function in gene and genome regulation. Here we show that Twi12, a Tetrahymena Piwi protein essential for growth, is loaded with mature tRNA fragments. The tightly bound ~18-22 nt tRNA 3M-bM-^@M-^Y fragments are biochemically distinct from the tRNA halves produced transiently in response to stress. Notably, the end positions of Twi12-bound tRNA 3' fragments precisely match RNAs detected in total small RNA of mouse embryonic stem cells and human cancer cells. Our studies demonstrate unanticipated evolutionary conservation of mature tRNA processing to tRNA-fragment small RNAs. Two libraries are analyzed here: sRNAs associated with slightly overexpressed ZZ-tagged Twi12 purified under native conditions (size range 15-34nt), and those associated after formaldehyde crosslinking (15-22nt).

Project description:We investigated the changes in the abundance of reads across the entire mitochondrial transcriptome, we found an increase in the regions that span gene boundaries, where RNA processing is required to release individual mitochondrial RNAs from the precursor transcripts. These data confirm an impairment of mt-tRNA processing efficiency without severe effects on mature mt-mRNA or mt-tRNA steady-state levels. Strand-specific coverage profiles were generated in bedGraph format and normalised to library size (RPM; reads per million mapped).