Using Pan RNA-Seq Analysis to Reveal the Ubiquitous Existence of 5′ and 3′ End Small RNAs

Abstract: In this study, we used pan RNA-seq analysis to reveal the ubiquitous existence of both 5′ and 3′ end small RNAs (5′ and 3′ sRNAs). 5′ and 3′ sRNAs alone can be used to annotate nuclear non-coding and mitochondrial genes at 1-bp resolution and identify new steady RNAs, which are usually transcribed from functional genes. Then, we provided a simple and cost effective way for the annotation of nuclear non-coding and mitochondrial genes and the identification of new steady RNAs, particularly long non-coding RNAs (… Show more

“…One of tRNA Ser s(mtDNA: 5713:5769) and tRNA Cys ( Figure 2B) had no D-arms, whereas tRNA Ala ( Figure 2B), tRNA Glu , tRNA Tyr and tRNA Phe had unstable T-arms. Another new nding was that the intergenic regions between tick mt tRNA genes are longer than those in mammalian except a novel 31-nt ncRNA [4], which was generated in the gene order rearrangement of mammalian mt tRNA genes. Although these intergenic regions in ticks were cleaved between their neighbouring tRNAs to form small RNAs (sRNAs) shorter than 10 bp, they are not likely to have biological functions, in our view.…”

“…Based on these ndings, we proposed the uninterrupted transcription of mammal mt genomes [3]. In addition, we proposed that long antisense transcripts degrade quickly as transient RNAs, making them unlikely to perform speci c functions [4], although all antisense transcripts are processed from two primary transcripts. The second contribution concerned the use 5′ and 3′ end small RNAs (5′ and 3′ sRNAs) [4] to annotate mt genes to a resolution of 1 bp, subsequently dubbed "precise annotation" [5].…”

“…In addition, we proposed that long antisense transcripts degrade quickly as transient RNAs, making them unlikely to perform speci c functions [4], although all antisense transcripts are processed from two primary transcripts. The second contribution concerned the use 5′ and 3′ end small RNAs (5′ and 3′ sRNAs) [4] to annotate mt genes to a resolution of 1 bp, subsequently dubbed "precise annotation" [5]. Precise annotation of these accurate genomes led us to discover a novel 31-nt ncRNA in mammalian mt DNA [4] and that the copy numbers of tandem repeats exhibit great diversity within an E. fullo individual [5].…”

“…The second contribution concerned the use 5′ and 3′ end small RNAs (5′ and 3′ sRNAs) [4] to annotate mt genes to a resolution of 1 bp, subsequently dubbed "precise annotation" [5]. Precise annotation of these accurate genomes led us to discover a novel 31-nt ncRNA in mammalian mt DNA [4] and that the copy numbers of tandem repeats exhibit great diversity within an E. fullo individual [5]. Recently, precise annotation of human, chimpanzee, rhesus macaque and mouse mt genomes has been performed to study ve Conserved Sequence Blocks (CSBs) in the mt D-loop region [6]; this ultimately led to a deep understanding of the mechanisms involved in the RNA-DNA transition and even the functions of the D-loop.…”

Precise annotation of tick mitochondrial genomes reveals multiple copy number variation of short tandem repeats and one transposon-like element

“…One of tRNA Ser s(mtDNA: 5713:5769) and tRNA Cys ( Figure 2B) had no D-arms, whereas tRNA Ala ( Figure 2B), tRNA Glu , tRNA Tyr and tRNA Phe had unstable T-arms. Another new nding was that the intergenic regions between tick mt tRNA genes are longer than those in mammalian except a novel 31-nt ncRNA [4], which was generated in the gene order rearrangement of mammalian mt tRNA genes. Although these intergenic regions in ticks were cleaved between their neighbouring tRNAs to form small RNAs (sRNAs) shorter than 10 bp, they are not likely to have biological functions, in our view.…”

“…Based on these ndings, we proposed the uninterrupted transcription of mammal mt genomes [3]. In addition, we proposed that long antisense transcripts degrade quickly as transient RNAs, making them unlikely to perform speci c functions [4], although all antisense transcripts are processed from two primary transcripts. The second contribution concerned the use 5′ and 3′ end small RNAs (5′ and 3′ sRNAs) [4] to annotate mt genes to a resolution of 1 bp, subsequently dubbed "precise annotation" [5].…”

“…In addition, we proposed that long antisense transcripts degrade quickly as transient RNAs, making them unlikely to perform speci c functions [4], although all antisense transcripts are processed from two primary transcripts. The second contribution concerned the use 5′ and 3′ end small RNAs (5′ and 3′ sRNAs) [4] to annotate mt genes to a resolution of 1 bp, subsequently dubbed "precise annotation" [5]. Precise annotation of these accurate genomes led us to discover a novel 31-nt ncRNA in mammalian mt DNA [4] and that the copy numbers of tandem repeats exhibit great diversity within an E. fullo individual [5].…”

“…The second contribution concerned the use 5′ and 3′ end small RNAs (5′ and 3′ sRNAs) [4] to annotate mt genes to a resolution of 1 bp, subsequently dubbed "precise annotation" [5]. Precise annotation of these accurate genomes led us to discover a novel 31-nt ncRNA in mammalian mt DNA [4] and that the copy numbers of tandem repeats exhibit great diversity within an E. fullo individual [5]. Recently, precise annotation of human, chimpanzee, rhesus macaque and mouse mt genomes has been performed to study ve Conserved Sequence Blocks (CSBs) in the mt D-loop region [6]; this ultimately led to a deep understanding of the mechanisms involved in the RNA-DNA transition and even the functions of the D-loop.…”

Precise annotation of tick mitochondrial genomes reveals multiple copy number variation of short tandem repeats and one transposon-like element

“…The genomic RNA, as a positive-sense RNA [gRNA(+)], is used as a template for the translation of ORF1a and ORF1b, and the replication and transcription of the SARS-CoV-2 genome. Recently, the translation of 10 other proteins (S, E, M, N, ORF3a, 6, 7a, 7b, 8 and 10) of SARS-CoV-2 has been reported in a study [2] that directly validates the prevailing "leader-to-body fusion" model using Nanopore RNA-seq-a direct RNA sequencing method [3]. In the model validated in that study (Figure 1A with varied length is located immediately upstream of ORFs except ORF1a and 1b ( Figure 1A).…”

A negative feedback model to explain regulation of SARS-CoV-2 replication and transcription

Complete mitochondrial genome of a blue-tailed skink Plestiodon capito (Reptilia, Squamata, Scincidae) and comparison with other Scincidae lizards