ICTV Virus Taxonomy Profile: Solemoviridae 2021

The family Solemoviridae includes viruses with icosahedral particles (26–34 nm in diameter) assembled on T=3 symmetry with a 4–6 kb positive-sense, monopartite, polycistronic RNA genome. Transmission of members of the genera Sobemovirus and Polemovirus occurs via mechanical wounding, vegetative propagation, insect vectors or abiotically through soil; members of the genera Polerovirus and Enamovirus are transmitted by specific aphids. Most solemoviruses have a narrow host range. This is a summary of the International Committee on Taxonomy of Viruses (ICTV) Report on the family Solemoviridae, which is available at ictv.global/report/solemoviridae.

Deep evolutionary origin of nematode SL2 trans-splicing revealed by genome-wide analysis of the Trichinella spiralis transcriptome

ABSTRACTSpliced leader trans-splicing is intimately associated with the presence of eukaryotic operons, allowing the processing of polycistronic RNAs into individual mRNAs. Most of our understanding of spliced leader trans-splicing as it relates to operon gene expression comes from studies in C. elegans. In this organism, two distinct spliced leader trans-splicing events are recognised: SL1, which is used to replace the 5’ ends of pre-mRNAs that have a nascent monomethyl guanosine cap; and SL2, which provides the 5’ end to uncapped pre-mRNAs derived from polycistronic RNAs. Limited data on operons and spliced leader trans-splicing in other nematodes suggested that SL2-type trans-splicing is a relatively recent innovation, associated with increased efficiency of polycistronic processing, and confined to only one of the five major nematode clades, Clade V. We have conducted the first transcriptome-wide analysis of spliced leader trans-splicing in a nematode species, Trichinella spiralis, which belongs to a clade distantly related to Clade V. Our work identifies a set of T. spiralis SL2-type spliced leaders that are specifically used to process polycistronic RNAs, the first examples of specialised spliced leaders that have been found outside of Clade V. These T. spiralis spliced leader RNAs possess a perfectly conserved stem-loop motif previously shown to be essential for polycistronic RNA processing in C. elegans. We show that this motif is found in specific sets of spliced leader RNAs broadly distributed across the nematode phylum. This work substantially revises our understanding of the evolution of nematode spliced leader trans-splicing, showing that the machinery for SL2 trans-splicing evolved much earlier during nematode evolution than was previously appreciated, and has been conserved throughout the radiation of the nematode phylum.

Epigenetics and transcriptional control in African trypanosomes

The African trypanosome Trypanosoma brucei is a unicellular parasite which causes African sleeping sickness. Transcription in African trypanosomes displays some unusual features, as most of the trypanosome genome is transcribed as extensive polycistronic RNA Pol II (polymerase II) transcription units that are not transcriptionally regulated. In addition, RNA Pol I is used for transcription of a small subset of protein coding genes in addition to the rDNA (ribosomal DNA). These Pol I-transcribed protein coding genes include the VSG (variant surface glycoprotein) genes. Although a single trypanosome has many hundreds of VSG genes, the active VSG is transcribed in a strictly monoalleleic fashion from one of approx. 15 telomeric VSG ESs (expression sites). Originally, it was thought that chromatin was not involved in the transcriptional control of ESs; however, this view is now being re-evaluated. It has since been shown that the active ES is depleted of nucleosomes compared with silent ESs. In addition, a number of proteins involved in chromatin remodelling or histone modification and which play a role in ES silencing {including TbISWI [T. brucei ISWI (imitation-switch protein)] and DOT1B} have recently been identified. Lastly, the telomere-binding protein TbRAP1 (T. brucei RAP1) has been shown to establish a repressive gradient extending from the ES telomere end up to the ES promoter. We still need to determine which epigenetic factors are involved in ‘marking’ the active ES as part of the counting mechanism of monoallelic exclusion. The challenge will come in determining how these multiple regulatory layers contribute to ES control.

Control of translation reinitiation on the cauliflower mosaic virus (CaMV) polycistronic RNA

Translation of the polycistronic 35S RNA of CaMV (cauliflower mosaic virus) occurs via a reinitiation mechanism, which requires TAV (transactivator/viroplasmin). To allow translation reinitiation of the major open reading frames on the polycistronic RNA, TAV interacts with the host translational machinery via eIF3 (eukaryotic initiation factor 3) and the 60S ribosome. Accumulation of TAV and eIF3 in the polysomal fraction isolated from CaMV-infected cells suggested that TAV prevents loss of eIF3 from the translating ribosomes during the first initiation event. The TAV–eIF3–80S complex could be detected in vitro by sucrose-gradient-sedimentation analysis. The question is whether TAV interacts directly with the 48S preinitiation complex or enters polysomes after the first initiation event. eIF4B, a component of the 48S initiation complex, can preclude formation of the TAV–eIF3 complex via competition with TAV for eIF3 binding; the eIF4B- and TAV-binding sites on eIF3g overlap. eIF4B out-competes TAV for binding to eIF3 and to the eIF3–40S complex. Transient overexpression of eIF4B in plant protoplasts specifically inhibits TAV-mediated transactivation of polycistronic translation. Our results thus indicate that eIF4B precludes TAV–eIF3–40S complex formation during the first initiation event. Consequently, overexpression of TAV in plant protoplasts affects only the second and subsequent initiation events. We propose a model in which TAV enters the host translational machinery at the eIF4B-removal step to stabilize eIF3 within polysomes.