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. 2021 Jul 2;26:161–173. doi: 10.1016/j.omtn.2021.06.023

Table 1.

Functions of various tRNA-derived RNA fragments in human diseases

Types of disease Types of tRFs, tsRNAs, and tiRNAs Parent tRNA Functions of tRFs, tsRNAs and tiRNAs References
Cancer 3′-tRF-1001 tRNA-SerTGA promote prostate cancer cell proliferation 34
tRF-544 tRNA-PheGAA significantly downregulated and associated with aggressive tumor growth 5,6
tRF-315 tRNA-LysCTT
3′-CCA-tRF (CU1276) tRNA-Gly gene silencing and post-transcriptional regulation in lymphoma cell lines 29
tRF-19 tRNA-ArgACG differentially expressed in mammary epithelium and malignant breast tumors in response to deregulation of RUNX1 35
tRF-29 tRNA-TyrGTA
tRF-46 tRNA-HisGTG
tRF-112 tRNA-SerGCT
tRF-Glu tRNA-GluYTC these tRFs interact with YBX1 protein and displace multiple oncogenic transcripts, which results in their instability and finally the suppression of breast cancer 36
tRF-Asp tRNA-AspGTC
tRF-Gly tRNA-GlyTCC
ts-4521 3′ ends of pre-tRNAs of serine and 3′ ends of pre-tRNAs of threonine these tRFs interacts with Ago and Piwi-like proteins, which supports cancer cell proliferation in lungs 37,38
ts-3676
tRF AS-tDR-000064 tRNA-LeuAAG displayed abundant differential expression in pancreatic cancer cells compared to adjacent normal tissues 39
tRF AS-tDR-000069 tRNA-GlnCTG
tRF AS-tDR-000102 tRNA-AlaCGC
tRF AS-tDR-001391 tRNA-ProCGG
tRF AS-tDR-000064 tRNA-LeuAAG qPCR data validated their upregulation in pancreatic cancer 39
tRF AS-tDR-000069 tRNA-GlnCTG
tRF AS-tDR-000102 tRNA-AlaCGC
AS-tDR-001391 tRNA-ProCGG qPCR data validated its downregulation in pancreatic cancer 39
5′-tRF-His tRNA-His inhibits the proliferation of breast cancer by regulating CKAP2 40
tRF-Glu-CTC-003 tRNA-GluCTC functions are not characterized; however, these can be used as a biomarker in early breast cancer detection 41
tRF-Gly-CCC-007 tRF-Gly-CCC-008 tRF-Leu-CAA-003 tRNA-GlyCCC
tRF-Ser-TGA-001 tRNA-LeuCAA
tRF-Ser-TGA-002 tRNA-SerTGA
tRNA-SerTGA
5′-tRNA-Val-CAC-2-1 half tRNA-ValCAC negatively regulates G1/S transition of mitotic cell cycle 42,43
3′-tsRNA-CAGLeu tRNA-LeuCAG this 3′-tsRNA interacts with mRNA of ribosomal proteins RPS28 and RPS15, which results in translation promotion and finally leads to proliferation of hepatocellular carcinoma cells 44
tRF-3017A tRNA-Val TAC tRF-3017A regulates the NELL2 tumor suppressor gene and thus promotes metastasis in gastric cancer 45
Infectious disease tRNA-GluCTC tRNAGlu represses the target mRNA in the cytoplasm and facilitates RSV replication 46,47
tRF5-GlyCCC tRNA-GlyCCC promote RSV replication 46
tRF5-LysCTT tRNA-LysCTT
tRF5-GluCTC tRNAGlu suppresses APOER2 mRNA and facilitates RSV replication 47
tRFs binds with reverse transcriptase of human T cell leukemia virus-1 and alters replication 48
tRF-3019 tRNAPro
tRNAThr 3′ half (this tRF is produced in human pathogenic protozoa, Trypanosoma brucei) tRNAThr binds with ribosome and stimulates protein biosynthesis during the stress recovery phase 49
5′ and 3′ half of tRNAs (these tRFs are produced in human pathogenic fungus) produced by endonucleolytic cleavage within the anticodon loop during conidiogenesis in Aspergillus fumigatus protein synthesis is downregulated 50
5′-tsRNAAsp tRNAAsp these tsRNAs interact with macrophages and support Leishmania donovani and Leishmania braziliensis to seek entry into cell cytoplasm 23
5′-tsRNAGln tRNAGln
3′-tRF-AlaUGC (includes 3′-CCA) tRNA-AlaUGC this tRF stimulates TLRs and thus Thp1- and CTL1-mediated immune responses 51
3′-tRF-SerTGA tRNA-SerTGA this 3′-tRF interacts with La/SSB proteins and resists IRES-mediated translation during HCV infection 52
Neurodegenerative diseases 5′-tiRNA-Ala and 5′-tiRNA-Cys tRNAAla and tRNACys these interact with YB-1 protein and induce the assembly of stress granules (SGs), which further generates a neuroprotective response 53
5′-tiRNAAsp, tiRNAGlu, tiRNAGly, tiRNAHis, tiRNALys, tiRNAVal tRNAAsp, tRNAGlu, tRNAGly, tRNAHis, tRNALys, tRNAVal these 5′-tRNA halves accumulate as a result of Nsun2 and Dnmt2 methyltransferase mutation, which results in reduced translation and action of apoptotic and stress pathways; this further leads to reduced cell size of hippocampal, cortical. and striatal neurons 54
3′- and 5′-tRNA halves derived from different isoacceptor tRNAs such as tyrosine, leucine, and isoleucine CLP1 protein deficiency in the case of pontocerebellar hypoplasia (PCH) results in unspliced pre-tRNA, which results in accumulation of 5′- and 3′-tRNA halves in the cells 17,55,56
Development and inheritance 5′-tRNA halves derived from tRNA-GlyGCC, tRNA-ValCAC, tRNA-GlnCTG, tRNA-GluTTC, tRNA-LysTTT these interact with IGF2BP1 and regulate the translation of cMyc, which further regulates cell proliferation and metabolism 42
5′-tRFGlyGCC tRNA-GlyGCC this targets MERVL an endogenous retroelement, which affects placentation and finally culminates in altered development of the offspring 57
Metabolic disease tRF-3001b tRNA-AsnGTT this interacts with Prkaa1 and inhibits autophagy, which stimulates NAFLD development 58
Gly-tRFs tRNAGly involved in the progression of liver steatosis 59
Immunity tRF5-AlaCGC tRNA-AlaCGC tRF5-AlaCGC induces IL-8 production by stimulating p65 60
5′-tiRNA-GluCTC tRNA-GluCTC this tRF induces chemokine and cytokine production 47
tRF-LysAAA tRNA-LysAAA involved in immunity regulation 61
tRF-AspGAY tRNA-AspGAY
Aging tRF-3003a tRNA-CysGCA regulates OA pathogenesis by repressing the Janus kinase 3 (JAK3) pathway 62
tiRNA-5035-GluCTC both derived from tRNA-GluCTC differential expression studies showed the downregulation of these tRFs in metacarpophalangeal joints of old horses 63
tiRNA-5031-GluCTC-1
5′-tRNA halves derived from tRNA-AsnGTT, tRNA-IleAAT, and tRNA-AspGTC downregulation of these tRFs was observed in rheumatoid arthritis patients, which suggests its use as a putative biomarker 64