Eugene I. Savenkov

Unusual Features of Pomoviral RNA Movement

Potato mop-top pomovirus (PMTV) is one of a few viruses that can move systemically in plants in the absence of the capsid protein (CP). Pomoviruses encode the triple gene block genetic module of movement proteins (TGB 1, 2, and 3) and recent research suggests that PMTV RNA is transported either as ribonucleoprotein (RNP) complexes containing TGB1 or encapsidated in virions containing TGB1. Furthermore, there are different requirements for local or systemic (long-distance) movement. Research suggests that nucleolar passage of TGB1 may be important for the long-distance movement of both RNP and virions. Moreover, and uniquely, the long-distance movement of the CP-encoding RNA requires expression of both major and minor CP subunits and is inhibited when only the major CP sub unit is expressed. This paper reviews pomovirus research and presents a current model for RNA movement.

Metacaspase-dependent programmed cell death is essential for plant embryogenesis

In plants, as in animals, programmed cell death (PCD) is a key process responsible for the elimination of unneeded structures and for overall shape remodeling during development [1]; however, the molecular mechanisms remain poorly understood. Despite the absence of canonical caspases in plants, dying plant cells show an increased proteolytic caspase-like activity [2]. Moreover, the cell death can be suppressed using synthetic [2] or natural [3] caspase inhibitors. This raises the question of whether plants have specific cysteine proteases with a role similar to metazoan caspases in the execution of PCD. Metacaspases are the best candidates to perform this role, because they contain a caspase-specific catalytic diad of histidine and cysteine as well as conserved caspase-like secondary structure [4,5]. Here we show the first experimental evidence for metacaspase function in the activation and/or execution of PCD in plants, and also demonstrate the fundamental requirement of plant metacaspase for embryogenesis. We explored the role of plant metacaspases in PCD using a model system of somatic embryogenesis of Norway spruce (Picea abies), where the pathway of embryo development (Figure 1A) resembles zygotic embryogeny, even though the embryo origin is different in each case (i.e., somatic cells in proembryogenic mass (PEM) versus zygote) [6]. In this developmental pathway autophagic PCD ablates PEMs at the time of their differentiation to embryos and then eliminates terminally differentiated embryo suspensor as the embryos enter late embryogeny [6,7] (Figure 1A). We have isolated a 1687 bp cDNA sequence from the embryogenic cell cultures (EMBL database accession number AJ534970). The encoded protein shows a significant degree of conservation with metacaspases and falls into the type II plant metacaspase subfamily (Figure S1A). The protein was named mcII-Pa. The predicted secondary structure of mcII-Pa contains conserved domains and motifs present in all members of the caspase/metacaspase/paracaspase superfamily [5] (Figure S1B). The putative mcII-Pa catalytic diad of cysteine and histidine is placed in the α α/β β fold characteristic for the caspase-hemoglobinase fold (CHF)-containing proteins [5]. The predicted mcII-Pa protein lacks both the death-effector domain and the caspase-activating recruitment domain found in classical initiator caspases, but has a p20-like domain including the active-site pentapeptide DXCHS (where X is A or S) shared by all metacaspases [5] (Figure S1B). This domain is fused to the 268 amino acid carboxy-terminal region consisting of a large insert of approximately 180 amino acids and a p10-like domain. In situ hybridization analysis has revealed restricted accumulation …

Tudor staphylococcal nuclease is an evolutionarily conserved component of the programmed cell death degradome

Programmed cell death (PCD) is executed by proteases, which cleave diverse proteins thus modulating their biochemical and cellular functions. Proteases of the caspase family and hundreds of caspase substrates constitute a major part of the PCD degradome in animals. Plants lack close homologues of caspases, but instead possess an ancestral family of cysteine proteases, metacaspases. Although metacaspases are essential for PCD, their natural substrates remain unknown. Here we show that metacaspase mcII-Pa cleaves a phylogenetically conserved protein, TSN (Tudor staphylococcal nuclease), during both developmental and stress-induced PCD. TSN knockdown leads to activation of ectopic cell death during reproduction, impairing plant fertility. Surprisingly, human TSN (also known as p100 or SND1), a multifunctional regulator of gene expression, is cleaved by caspase-3 during apoptosis. This cleavage impairs the ability of TSN to activate mRNA splicing, inhibits its ribonuclease activity and is important for the execution of apoptosis. Our results establish TSN as the first biological substrate of metacaspase and demonstrate that despite the divergence of plants and animals from a common ancestor about one billion years ago and their use of distinct PCD pathways, both have retained a common mechanism to compromise cell viability through the cleavage of the same substrate, TSN.

Long-Distance Movement, Virulence, and RNA Silencing Suppression Controlled by a Single Protein in Hordei- and Potyviruses: Complementary Functions between Virus Families

ABSTRACT RNA silencing is a natural defense mechanism against genetic stress factors, including viruses. A mutant hordeivirus (Barley stripe mosaic virus [BSMV]) lacking the γb gene was confined to inoculated leaves in Nicotiana benthamiana, but systemic infection was observed in transgenic N. benthamiana expressing the potyviral silencing suppressor protein HCpro, suggesting that the γb protein may be a long-distance movement factor and have antisilencing activity. This was shown for γb proteins of both BSMV and Poa semilatent virus (PSLV), a related hordeivirus. Besides the functions in RNA silencing suppression, γb and HCpro had analogous effects on symptoms induced by the hordeiviruses. Severe BSMV-induced symptoms were correlated with high HCpro concentrations in the HCpro-transgenic plants, and substitution of the γb cistron of BSMV with that of PSLV led to greatly increased symptom severity and an altered pattern of viral gene expression. The efficient systemic infection with the chimera was followed by the development of dark green islands (localized recovery from infection) in leaves and exemption of new developing leaves from infection. Recovery and the accumulation of short RNAs diagnostic of RNA silencing in the recovered tissues in wild-type N. benthamiana were suppressed in HCpro-transgenic plants. These results provide evidence that potyviral HCpro and hordeivirus γb proteins contribute to systemic viral infection, symptom severity, and RNA silencing suppression. HCpros ability to suppress the recovery of plants from viral infection emphasizes recovery as a manifestation of RNA silencing.

The photoreversible fluorescent protein iLOV outperforms GFP as a reporter of plant virus infection

Fluorescent proteins (FPs) based on green fluorescent protein (GFP) are widely used throughout cell biology to study protein dynamics, and have extensive use as reporters of virus infection and spread. However, FP-tagging of viruses is limited by the constraints of viral genome size resulting in FP loss through recombination events. To overcome this, we have engineered a smaller (≈10 kDa) flavin-based alternative to GFP (≈25 kDa) derived from the light, oxygen or voltage-sensing (LOV) domain of the plant blue light receptor, phototropin. Molecular evolution and Tobacco mosaic virus (TMV)-based expression screening produced LOV variants with improved fluorescence and photostability in planta. One variant in particular, designated iLOV, possessed photophysical properties that made it ideally suited as a reporter of subcellular protein localization in both plant and mammalian cells. Moreover, iLOV fluorescence was found to recover spontaneously after photobleaching and displayed an intrinsic photochemistry conferring advantages over GFP-based FPs. When expressed either as a cytosolic protein or as a viral protein fusion, iLOV functioned as a superior reporter to GFP for monitoring local and systemic infections of plant RNA viruses. iLOV, therefore, offers greater utility in FP-tagging of viral gene products and represents a viable alternative where functional protein expression is limited by steric constraints or genome size.

Viral Class 1 RNase III Involved in Suppression of RNA Silencing

ABSTRACT Double-stranded RNA (dsRNA)-specific endonucleases belonging to RNase III classes 3 and 2 process dsRNA precursors to small interfering RNA (siRNA) or microRNA, respectively, thereby initiating and amplifying RNA silencing-based antiviral defense and gene regulation in eukaryotic cells. However, we now provide evidence that a class 1 RNase III is involved in suppression of RNA silencing. The single-stranded RNA genome of sweet potato chlorotic stunt virus (SPCSV) encodes an RNase III (RNase3) homologous to putative class 1 RNase IIIs of unknown function in rice and Arabidopsis. We show that RNase3 has dsRNA-specific endonuclease activity that enhances the RNA-silencing suppression activity of another protein (p22) encoded by SPCSV. RNase3 and p22 coexpression reduced siRNA accumulation more efficiently than p22 alone in Nicotiana benthamiana leaves expressing a strong silencing inducer (i.e., dsRNA). RNase3 did not cause intracellular silencing suppression or reduce accumulation of siRNA in the absence of p22 or enhance silencing suppression activity of a protein encoded by a heterologous virus. No other known RNA virus encodes an RNase III or uses two independent proteins cooperatively for RNA silencing suppression.

Complete Genome Sequence and Analyses of the Subgenomic RNAs of Sweet Potato Chlorotic Stunt Virus Reveal Several New Features for the Genus Crinivirus

ABSTRACT The complete nucleotide sequences of genomic RNA1 (9,407 nucleotides [nt]) and RNA2 (8,223 nt) of Sweet potato chlorotic stunt virus (SPCSV; genus Crinivirus, family Closteroviridae) were determined, revealing that SPCSV possesses the second largest identified positive-strand single-stranded RNA genome among plant viruses after Citrus tristeza virus. RNA1 contains two overlapping open reading frames (ORFs) that encode the replication module, consisting of the putative papain-like cysteine proteinase, methyltransferase, helicase, and polymerase domains. RNA2 contains the Closteroviridae hallmark gene array represented by a heat shock protein homologue (Hsp70h), a protein of 50 to 60 kDa depending on the virus, the major coat protein, and a divergent copy of the coat protein. This grouping resembles the genome organization of Lettuce infectious yellows virus (LIYV), the only other crinivirus for which the whole genomic sequence is available. However, in striking contrast to LIYV, the two genomic RNAs of SPCSV contained nearly identical 208-nt-long 3′ terminal sequences, and the ORF for a putative small hydrophobic protein present in LIYV RNA2 was found at a novel position in SPCSV RNA1. Furthermore, unlike any other plant or animal virus, SPCSV carried an ORF for a putative RNase III-like protein (ORF2 on RNA1). Several subgenomic RNAs (sgRNAs) were detected in SPCSV-infected plants, indicating that the sgRNAs formed from RNA1 accumulated earlier in infection than those of RNA2. The 5′ ends of seven sgRNAs were cloned and sequenced by an approach that provided compelling evidence that the sgRNAs are capped in infected plants, a novel finding for members of the Closteroviridae.

Autophagy and metacaspase determine the mode of cell death in plants.

Metacaspase-dependent autophagy in plants promotes cell disassembly during vacuolar cell death and inhibits necrosis.

The readthrough region of Potato mop-top virus (PMTV) coat protein encoding RNA, the second largest RNA of PMTV genome, undergoes structural changes in naturally infected and experimentally inoculated plants.

Summary. Molecular data on Potato mop-top virus (PMTV), genus Pomovirus, is currently mostly based on analysis of two Scottish isolates, PMTV-S and PMTV-T. Here we report the complete sequence of “the coat protein (CP) encoding RNA” of an isolate of PMTV obtained from the field in Sweden. Our data show that this RNA (3134 nt) is the second largest of the three RNA species in the tripartite PMTV genome, and it should, therefore, be referred to as RNA 2. This nomenclature is consistent with other pomoviruses. The sequence of the readthrough domain (RT) of RNA 2 was determined also in two additional field isolates of PMTV from Finland and Denmark. All three isolates contained a novel, 109 nucleotides long sequence at the 3′-end of the RT, which has not been found in PMTV-S and PMTV-T. Hence, our data suggest that the RNA 2 sequences previously described for the isolates PMTV-T and PMTV-S may represent deletion derivatives. The C-proximal half of RT contained many amino acid (aa) differences among the isolates, in contrast to only few aa differences in the N-proximal part of RT. Deletion variants of RNA 2 were generated from the Nordic isolates in potato tubers infected in the field, and in the mechanically inoculated test plants. All deletions started within a short region (18 nt) and removed 558–940 nt from the 3′-end of RT region. This study for the first time describes the full-length sequence of the “CP-encoding RNA” (RNA2) of PMTV, and reveals considerable aa variability and occurrence of deletion variants of RT in the field isolates of PMTV.

The N-terminal domain of PMTV TGB1 movement protein is required for nucleolar localization, microtubule association, and long-distance movement.

The triple-gene-block (TGB)1 protein of Potato mop-top virus (PMTV) was fused to fluorescent proteins and expressed in epidermal cells of Nicotiana benthamiana under the control of the 35S promoter. TGB1 fluorescence was observed in the cytoplasm, nucleus, and nucleolus and occasionally associated with microtubules. When expressed from a modified virus (PMTV.YFP-TGB1) which formed local lesions but was not competent for systemic movement, yellow fluorescent protein (YFP)-TGB1 labeled plasmodesmata in cells at the leading edge of the lesion and plasmodesmata, microtubules, nuclei, and nucleoli in cells immediately behind the leading edge. Deletion of 84 amino acids from the N-terminus of unlabeled TGB1 within the PMTV genome abolished movement of viral RNA to noninoculated leaves. When the same deletion was introduced into PMTV.YFP-TGB1, labeling of microtubules and nucleoli was abolished. The N-terminal 84 amino acids of TGB1 were fused to green fluorescent protein (GFP) and expressed in epidermal cells where GFP localized strongly to the nucleolus (not seen with unfused GFP), indicating that these amino acids contain a nucleolar localization signal; the fusion protein did not label microtubules. This is the first report of nucleolar and microtubule association of a TGB movement protein. The results suggest that PMTV TGB1 requires interaction with nuclear components and, possibly, microtubules for long-distance movement of viral RNA.