Molecular characterization of two endogenous double-stranded RNAs in rice and their inheritance by interspecific hybrids

We completely sequenced 13,936 nucleotides (nt) of a double-stranded RNA (dsRNA) of wild rice (W-dsRNA). A single long open reading frame (13,719 nt) containing the conserved motifs of RNA-dependent RNA polymerase and RNA helicase was located in the coding strand. The identity between entire nucleotide sequence of W-dsRNA and that of the dsRNA of temperate japonica rice (J-dsRNA, 13,952 nt) was 75.5%. A site-specific discontinuity (nick) was identified at nt 1,197 from the 5' end of the coding strand of W-dsRNA. This nick is also located at nt 1,211 from the 5' end in the coding strand of J-dsRNA. The dsRNA copy number was increased more than 10-fold in pollen grains of both rice plants. This remarkable increase may be responsible for the highly efficient transmission of J-dsRNA via pollen that we already reported. J-dsRNA and W-dsRNA were also efficiently transmitted to interspecific F1 hybrids. Seed-mediated dsRNA transmission to F2 plants was also highly efficient when the maternal parent was wild rice. The efficiency of dsRNA transmission to F2 plants was reduced when the maternal parent was temperate japonica rice; however, the reduced rates in F2 plants were returned to high levels in F3 plants.     

Characterization of the RNA-binding domains in the replicase proteins of tomato bushy stunt virus

Tomato bushy stunt virus (TBSV), a tombusvirus with a nonsegmented, plus-stranded RNA genome, codes for two essential replicase proteins. The sequence of one of the replicase proteins, namely p33, overlaps with the N-terminal domain of p92, which contains the signature motifs of RNA-dependent RNA polymerases (RdRps) in its nonoverlapping C-terminal portion. In this work, we demonstrate that both replicase proteins bind to RNA in vitro based on gel mobility shift and surface plasmon resonance measurements. We also show evidence that the binding of p33 to single-stranded RNA (ssRNA) is stronger than binding to double-stranded RNA (dsRNA), ssDNA, or dsDNA in vitro. Competition experiments with ssRNA revealed that p33 binds to a TBSV-derived sequence with higher affinity than to other nonviral ssRNA sequences. Additional studies revealed that p33 could bind to RNA in a cooperative manner. Using deletion derivatives of the Escherichia coli-expressed recombinant proteins in gel mobility shift and Northwestern assays, we demonstrate that p33 and the overlapping domain of p92, based on its sequence identity with p33, contain an arginine- and proline-rich RNA-binding motif (termed RPR, which has the sequence RPRRRP). This motif is highly conserved among tombusviruses and related carmoviruses, and it is similar to the arginine-rich motif present in the Tat trans-activator protein of human immunodeficiency virus type 1. We also find that the nonoverlapping C-terminal domain of p92 contains additional RNA-binding regions. Interestingly, the location of one of the RNA-binding domains in p92 is similar to the RNA-binding domain of the NS5B RdRp protein of hepatitis C virus.     

Tentative identification of RNA-dependent RNA polymerases of dsRNA viruses and their relationship to positive strand RNA viral polymerases

Amino acid sequence stretches similar to the four most conserved segments of positive strand RNA viral RNA-dependent RNA polymerases have been identified in proteins of four dsRNA viruses belonging to three families, i.e. P2 protein of bacteriophage phi 6 (Cystoviridae), RNA 2 product of infectious bursa disease virus (Birnaviridae), lambda 3 protein of reovirus, and VP1 of bluetongue virus (Reoviridae). High statistical significance of the observed similarity was demonstrated, allowing identification of these proteins as likely candidates for RNA-dependent RNA polymerases. Based on these observations, and on the previously reported sequence similarity between the RNA polymerases of a yeast dsRNA virus and those of positive strand RNA viruses, a possible evolutionary relationship between the two virus classes is discussed.     

Evolution of Tertiary Structure of Viral RNA Dependent Polymerases

Viral RNA dependent polymerases (vRdPs) are present in all RNA viruses; unfortunately, their sequence similarity is too low for phylogenetic studies. Nevertheless, vRdP protein structures are remarkably conserved. In this study, we used the structural similarity of vRdPs to reconstruct their evolutionary history. The major strength of this work is in unifying sequence and structural data into a single quantitative phylogenetic analysis, using powerful a Bayesian approach.The resulting phylogram of vRdPs demonstrates that RNA-dependent DNA polymerases (RdDPs) of viruses within Retroviridae family cluster in a clearly separated group of vRdPs, while RNA-dependent RNA polymerases (RdRPs) of dsRNA and +ssRNA viruses are mixed together. This evidence supports the hypothesis that RdRPs replicating +ssRNA viruses evolved multiple times from RdRPs replicating +dsRNA viruses, and vice versa. Moreover, our phylogram may be presented as a scheme for RNA virus evolution. The results are in concordance with the actual concept of RNA virus evolution. Finally, the methods used in our work provide a new direction for studying ancient virus evolution.     

Particle and naked RNA mycoviruses in industrially cultivated mushroom Pleurotus ostreatus in China

Many cultivated mushroom strains, such as Pleurotus ostreatus TD300, displayed symptoms of degeneration. A spherical virus POSV and four dsRNA segments were extracted from mycelium of P. ostreatus TD300. POSV had a diameter of 23 nm and encapsidated a 2.5kb dsRNA segment with coat proteins whose molecular weights were 39 kDa and 30 kDa. Four dsRNA segments were 8.2 kb, 2.5 kb, 2.0 kb, and 1.1 kb in size, respectively. The 1.1 kb dsRNA segment often escaped detection. The cDNA and the amino acid sequences of the 8.2 kb dsRNA were homologous to those of RNA-dependent RNA polymerases (RDRP) of ssRNA oyster mushroom spherical virus (OMSV), and contained conserved motifs A to D which were almost identical to those in RDRP of OMSV. The cDNA and amino acid sequences of the 2.5 kb and 2.0 kb dsRNA segments were homologous to that of RDRP and capsid protein of dsRNA virus P. ostreatus virus 1 (PoV1), respectively. In particular, the amino acid sequence of 2.5 kb dsRNA segment had high identity with the conserved motifs A to C in RDRP of PoV1, a Partiviridae virus. After eliminating the viruses in P. ostreatus TD300, the symptoms of degeneration completely disappeared. The results reveal that P. ostreatus TD300 was at least infected by a particle virus POSV, and two naked viruses, one was a dsRNA virus with a 2.0 kb dsRNA segment, the other was an ssRNA virus whose replicating form of genome was an 8.2 kb dsRNA segment. Mycoviruses infection is a causative agent of mushroom strain degeneration.     

A closely related group of RNA-dependent RNA polymerases from double-stranded RNA viruses.

Probably one of the first proteinaceous enzymes was an RNA-dependent RNA polymerase (RDRP). Although there are several conserved motifs present in the RDRPs of most positive and double-stranded RNA (dsRNA) viruses, the RDRPs of the dsRNA viruses show no detectable sequence similarity outside the conserved motifs. There is now, however, a group of dsRNA viruses of lower eucaryotes whose RDRPs are detectably similar. The origin of this sequence similarity appears to be common descent from one or more noninfectious viruses of a progenitor cell, an origin that predates the differentiation of protozoans and fungi. The cause of this preservation of sequence appears to be constraints placed on the RDRP by the life-style of these viruses--the maintenance of a stable, persistent, noninfectious state.     

Recognition of double-stranded RNA by proteins and small molecules

Molecular recognition of double-stranded RNA (dsRNA) is a key event for numerous biological pathways including the trafficking, editing, and maturation of cellular RNA, the interferon antiviral response, and RNA interference. Over the past several years, our laboratory has studied proteins and small molecules that bind dsRNA with the goal of understanding and controlling the binding selectivity. In this review, we discuss members of the dsRBM class of proteins that bind dsRNA. The dsRBM is an approximately 70 amino acid sequence motif found in a variety of dsRNA-binding proteins. Recent results have led to a new appreciation of the ability of these proteins to bind selectivity to certain sites on dsRNA. This property is discussed in light of the RNA selectivity observed in the function of two proteins that contain dsRBMs, the RNA-dependent protein kinase (PKR) and an adenosine deaminase that acts on dsRNA (ADAR2). In addition, we introduce peptide-acridine conjugates (PACs), small molecules designed to control dsRBM-RNA interactions. These intercalating molecules bear variable peptide appendages at opposite edges of an acridine heterocycle. This design imparts the potential to exploit differences in groove characteristics and/or base-pair dynamics at binding sites to achieve selective binding.     

Wheat eukaryotic initiation factor 4B organizes assembly of RNA and eIFiso4G, eIF4A, and poly(A)-binding protein

The eukaryotic translation initiation factor (eIF) 4B promotes the RNA-dependent ATP hydrolysis activity and ATP-dependent RNA helicase activity of eIF4A and eIF4F during translation initiation. Although this function is conserved among plants, animals, and yeast, eIF4B is one of the least conserved of initiation factors at the sequence level. To gain insight into its functional conservation, the organization of the functional domains of eIF4B from wheat has been investigated. Plant eIF4B contains three RNA binding domains, one more than reported for mammalian or yeast eIF4B, and each domain exhibits a preference for purine-rich RNA. In addition to a conserved RNA recognition motif and a C-terminal RNA binding domain, wheat eIF4B contains a novel N-terminal RNA binding domain that requires a short, lysine-rich containing sequence. Both the lysine-rich motif and an adjacent, C-proximal motif are conserved with an N-proximal sequence in human and yeast eIF4B. The C-proximal motif within the N-terminal RNA binding domain in wheat eIF4B is required for interaction with eIFiso4G, an interaction not reported for other eIF4B proteins. Moreover, each RNA binding domain requires dimerization for binding activity. Two binding sites for the poly(A)-binding protein were mapped to a region within each of two conserved 41-amino acid repeat domains on either side of the C-terminal RNA binding domain. eIF4A bound to an adjacent region within each repeat, supporting a central role for these conserved eIF4B domains in facilitating interaction with other components of the translational machinery. These results support the notion that eIF4B functions by organizing multiple components of the translation initiation machinery and RNA.     

Activation of the protein kinase PKR by short double-stranded RNAs with single-stranded tails

The human RNA-activated protein kinase PKR is an interferon-induced protein that is part of the innate immune response and inhibits viral replication. The action of PKR involves RNA-dependent autophosphorylation leading to inhibition of translation. PKR has an N-terminal dsRNA-binding domain that can interact non-sequence specifically with long (>33 bp) stretches of dsRNA leading to activation. In addition, certain viral and cellular RNAs containing non-Watson-Crick structures and multiple, shorter dsRNA sections can regulate PKR. In an effort to identify novel binders and possible activators of PKR, we carried out selections on a partially structured dsRNA library using truncated and full-length versions of PKR. A library with 10(11) sequences was constructed and aptamers that bound to His6-tagged proteins were isolated. Characterization revealed a novel minimal RNA motif for activation of PKR with the following unified structural characteristics: a hairpin with a nonconserved imperfect 16-bp dsRNA stem flanked by 10-15-nt single-stranded tails, herein termed a "ss-dsRNA motif." Boundary experiments revealed that the single-stranded tails flanking the dsRNA core provide the critical determinant for activation. The ss-dsRNA motif occurs in a variety of cellular and viral RNAs, suggesting possible novel functions for PKR in nature.     

Significance in replication of the terminal nucleotides of the flavivirus genome

Point mutations that resulted in a substitution of the conserved 3'-penultimate cytidine in genomic RNA or the RNA negative strand of the self-amplifying replicon of the Flavivirus Kunjin virus completely blocked in vivo replication. Similarly, substitutions of the conserved 3'-terminal uridine in the RNA negative or positive strand completely blocked replication or caused much-reduced replication, respectively. The same preference for cytidine in the 3'-terminal dinucleotide was noted in reports of the in vitro activity of the RNA-dependent RNA polymerase (RdRp) for the other genera of Flaviviridae that also employ a double-stranded RNA (dsRNA) template to initiate asymmetric semiconservative RNA positive-strand synthesis. The Kunjin virus replicon results were interpreted in the context of a proposed model for initiation of RNA synthesis based on the solved crystal structure of the RdRp of phi6 bacteriophage, which also replicates efficiently using a dsRNA template with conserved 3'-penultimate cytidines and a 3'-terminal pyrimidine. A previously untested substitution of the conserved pentanucleotide at the top of the 3'-terminal stem-loop of all Flavivirus species also blocked detectable in vivo replication of the Kunjin virus replicon RNA.     

Mechanism of interaction of the double-stranded RNA (dsRNA) binding domain of protein kinase R with short dsRNA sequences

The dsRNA-activated protein kinase (PKR) plays a major role in the cellular response to viral infection. PKR contains an N-terminal dsRNA binding domain (dsRBD) and a C-terminal kinase domain. The dsRBD consists of two tandem copies of a conserved double-stranded RNA binding motif, dsRBM1 and dsRBM2. dsRNA binding is believed to activate PKR by inducing dimerization and subsequent autophosphorylation reactions. We have characterized the function of the dsRBD by assessing the binding of dsRBM1 and dsRBD to a series of dsRNA sequences ranging from 15 to 45 bp. For dsRBM1, the binding stoichiometries agree with an overlapping ligand binding model where the motif binds to multiple faces of the dsRNA duplex and overlaps along the helical axis. Similar behavior is observed for a dsRBD containing both dsRBM1 and dsRBM2 for sequences up to 30 bp; however, the binding affinity is enhanced 30-fold. Longer dsRNA sequences exhibit lower-than-expected stoichiometries, indicating a change in binding mode. NMR spectroscopy was used to define the regions of the dsRBD that interact with dsRNA. dsRNA binding induces exchange broadening of cross-peaks in 1H-15N HSQC spectra. For a 20 bp dsRNA, the resonances most affected map to the known dsRNA binding regions of dsRBM1 as well as the N-terminus of dsRBM2. For a longer 40 bp sequence, additional regions of dsRBM2 exhibit enhanced broadening. These data support a model in which dsRBM1 plays the dominant role in binding short dsRNA sequences and dsRBM2 makes additional interactions with the longer sequences capable of activating PKR.     

A cryptic RNA-binding domain in the Pol region of the L-A double-stranded RNA virus Gag-Pol fusion protein.

The Pol region of the Gag-Pol fusion protein of the L-A double-stranded (ds) RNA virus of Saccharomyces cerevisiae has (i) a domain essential for packaging viral positive strands, (ii) consensus amino acid sequence patterns typical of RNA-dependent RNA polymerases, and (iii) two single-stranded RNA binding domains. We describe here a third single-stranded RNA binding domain (Pol residues 374 to 432), which is unique in being cryptic. Its activity is revealed only after deletion of an inhibitory region C terminal to the binding domain itself. This cryptic RNA binding domain is necessary for propagation of M1 satellite dsRNA, but it is not necessary for viral particle assembly or for packaging of viral positive-strand single-stranded RNA. The cryptic RNA binding domain includes a sequence pattern common among positive-strand single-stranded RNA and dsRNA viral RNA-dependent RNA polymerases, suggesting that it has a role in RNA polymerase activity.     

The palm subdomain-based active site is internally permuted in viral RNA-dependent RNA polymerases of an ancient lineage

Template-dependent polynucleotide synthesis is catalyzed by enzymes whose core component includes a ubiquitous alphabeta palm subdomain comprising A, B and C sequence motifs crucial for catalysis. Due to its unique, universal conservation in all RNA viruses, the palm subdomain of RNA-dependent RNA polymerases (RdRps) is widely used for evolutionary and taxonomic inferences. We report here the results of elaborated computer-assisted analysis of newly sequenced replicases from Thosea asigna virus (TaV) and the closely related Euprosterna elaeasa virus (EeV), insect-specific ssRNA+ viruses, which revise a capsid-based classification of these viruses with tetraviruses, an Alphavirus-like family. The replicases of TaV and EeV do not have characteristic methyltransferase and helicase domains, and include a putative RdRp with a unique C-A-B motif arrangement in the palm subdomain that is also found in two dsRNA birnaviruses. This circular motif rearrangement is a result of migration of approximately 22 amino acid (aa) residues encompassing motif C between two internal positions, separated by approximately 110 aa, in a conserved region of approximately 550 aa. Protein modeling shows that the canonical palm subdomain architecture of poliovirus (ssRNA+) RdRp could accommodate the identified sequence permutation through changes in backbone connectivity of the major structural elements in three loop regions underlying the active site. This permutation transforms the ferredoxin-like beta1alphaAbeta2beta3alphaBbeta4 fold of the palm subdomain into the beta2beta3beta1alphaAalphaBbeta4 structure and brings beta-strands carrying two principal catalytic Asp residues into sequential proximity such that unique structural properties and, ultimately, unique functionality of the permuted RdRps may result. The permuted enzymes show unprecedented interclass sequence conservation between RdRps of true ssRNA+ and dsRNA viruses and form a minor, deeply separated cluster in the RdRp tree, implying that other, as yet unidentified, viruses may employ this type of RdRp. The structural diversification of the palm subdomain might be a major event in the evolution of template-dependent polynucleotide polymerases in the RNA-protein world.     

Unusual inheritance of evolutionarily-related double-stranded RNAs in interspecific hybrid between rice plants Oryza sativa and Oryza rufipogon

Endogenous, 14 kb double-stranded RNAs (dsRNAs) have been found in two ecospecies of cultivated rice (temperate japonica rice and tropical japonica rice, Oryza sativa L.) and in wild rice (O. rufipogon, an ancestor of O. sativa). A comparison of the nucleotide and deduced amino acid sequences of the core regions of the RNA-dependent RNA polymerase domains found in these three dsRNAs suggested that these dsRNAs probably evolved independently within each host plant from a common ancestor. These dsRNAs were introduced into F1 hybrids by crossing cultivated rice and wild rice. Unusual cytoplasmic inheritance of these dsRNAs was observed in some F1 hybrids; the evolutionarily related dsRNAs were incompatible for each other, and the resident dsRNA of an egg cell from cultivated rice was excluded by the incoming dsRNA of a pollen cell from wild rice. Coexisting dsRNAs in the F1 hybrids segregated away from each other in the F2 plants. However, the total amount of these dsRNAs in the host cells remained constant (ca. 100 copies/cell). The stringent regulation of the dsRNA copy number may be responsible for their unusual inheritance.     

Selective binding by the RNA binding domain of PKR revealed by affinity cleavage

The RNA-dependent protein kinase (PKR) is regulated by the binding of double-stranded RNA (dsRNA) or single-stranded RNAs with extensive duplex secondary structure. PKR has an RNA binding domain (RBD) composed of two copies of the dsRNA binding motif (dsRBM). The dsRBM is an alpha-beta-beta-beta-alpha structure present in a number of proteins that bind RNA, and the selectivity demonstrated by these proteins is currently not well understood. We have used affinity cleavage to study the binding of PKR's RBD to RNA. In this study, we site-specifically modified the first dsRBM of PKR's RBD at two different amino acid positions with the hydroxyl radical generator EDTA.Fe. Cleavage by these proteins of a synthetic stem-loop ligand of PKR indicates that PKR's dsRBMI binds the RNA in a preferred orientation, placing the loop between strands beta1 and beta2 near the single-stranded RNA loop. Additional cleavage experiments demonstrated that defects in the RNA stem, such as an A bulge and two GA mismatches, do not dictate dsRBMI's binding orientation preference. Cleavage of VA(I) RNA, an adenoviral RNA inhibitor of PKR, indicates that dsRBMI is bound near the loop of the apical stem of this RNA in the same orientation as observed with the synthetic stem-loop RNA ligands. This work, along with an NMR study of the binding of a dsRBM derived from the Drosophila protein Staufen, indicates that dsRBMs can bind stem-loop RNAs in distinct ways. In addition, the successful application of the affinity cleavage technique to localizing dsRBMI of PKR on stem-loop RNAs and defining its orientation suggests this approach could be applied to dsRBMs found in other proteins.     

Mutational analysis of a DEAD box RNA helicase: the mammalian translation initiation factor eIF-4A.

eIF-4A is a translation initiation factor that exhibits bidirectional RNA unwinding activity in vitro in the presence of another translation initiation factor, eIF-4B and ATP. This activity is thought to be responsible for the melting of secondary structure in the 5' untranslated region of eukaryotic mRNAs to facilitate ribosome binding. eIF-4A is a member of a fast growing family of proteins termed the DEAD family. These proteins are believed to be RNA helicases, based on the demonstrated in vitro RNA helicase activity of two members (eIF-4A and p68) and their homology in eight amino acid regions. Several related biochemical activities were attributed to eIF-4A: (i) ATP binding, (ii) RNA-dependent ATPase and (iii) RNA helicase. To determine the contribution of the highly conserved regions to these activities, we performed site-directed mutagenesis. First we show that recombinant eIF-4A, together with recombinant eIF-4B, exhibit RNA helicase activity in vitro. Mutations in the ATPase A motif (AXXXXGKT) affect ATP binding, whereas mutations in the predicted ATPase B motif (DEAD) affect ATP hydrolysis. We report here that the DEAD region couples the ATPase with the RNA helicase activity. Furthermore, two other regions, whose functions were unknown, have also been characterized. We report that the first residue in the HRIGRXXR region is involved in ATP hydrolysis and that the SAT region is essential for RNA unwinding. Our results suggest that the highly conserved regions in the DEAD box family are critical for RNA helicase activity.     

Relationships among the positive strand and double-strand RNA viruses as viewed through their RNA-dependent RNA polymerases.

The sequences of 50 RNA-dependent RNA polymerases (RDRPs) from 43 positive strand and 7 double strand RNA (dsRNA) viruses have been compared. The alignment permitted calculation of distances among the 50 viruses and a resultant dendrogram based on every amino acid, rather than just those amino acids in the conserved motifs. Remarkably, a large subgroup of these viruses, including vertebrate, plant, and insect viruses, forms a single cluster whose only common characteristic is exploitation of insect hosts or vectors. This similarity may be due to molecular constraints associated with a present and/or past ability to infect insects and/or to common descent from insect viruses. If common descent is important, as it appears to be, all the positive strand RNA viruses of eucaryotes except for the picornaviruses may have evolved from an ancestral dsRNA virus. Viral RDRPs appear to be inherited as modules rather than as portions of single RNA segments, implying that RNA recombination has played an important role in their dissemination.     

Molecular characterization of a dsRNA mycovirus, Fusarium graminearum virus-DK21, which is phylogenetically related to hypoviruses but has a genome organization and gene expression strategy resembling those of plant potex-like viruses

Fusarium graminearum causes a serious scab disease of small grains in Korea. The nucleotide sequence of the genomic RNA of a double-stranded RNA (dsRNA) virus, Fusarium graminearum virus-DK21 (FgV-DK21), from F. graminearum strain DK21, which is associated with hypovirulence in F. graminearum, was determined and compared to the genome sequences of other mycoviruses, including Cryponectria hypoviruses. The FgV-DK21 dsRNA consists of 6,624 nucleotides, excluding the 3'-terminal poly(A) tail. The viral genome has 53- and 46-nucleotide 5' and 3' untranslated regions (UTRs), respectively, and five putative open reading frames. A phylogenetic analysis of the deduced amino acid sequence of ORF1, which encodes a putative RNA-dependent RNA polymerase, and those of other mycoviruses revealed that this organism forms a distinct virus clade with other hypoviruses, and is more distantly related to other mycoviruses (3.8 to 24.0% identity). However, pairwise sequence comparisons of the nucleotide and deduced amino acid sequences of ORFs 2 through 5 revealed no close relationships to other protein sequences currently available in GenBank. Analyses of RNA accumulation by Northern blot and primer extension indicated that these putative gene products are expressed from at least two different subgenomic RNAs (sgRNAs), in contrast to the cases in other hypoviruses. This study suggests the existence of a new, as yet unassigned, genus of mycoviruses that exhibits a potex-like genome organization and sgRNA accumulation.     

NMR solution structure of a dsRNA binding domain from Drosophila staufen protein reveals homology to the N-terminal domain of ribosomal protein S5.

The double-stranded RNA binding domain (dsRBD) is an approximately 65 amino acid motif that is found in a variety of proteins that interact with double-stranded (ds) RNA, such as Escherichia coli RNase III and the dsRNA-dependent kinase, PKR. Drosophila staufen protein contains five copies of this motif, and the third of these binds dsRNA in vitro. Using multinuclear/multidimensional NMR methods, we have determined that staufen dsRBD3 forms a compact protein domain with an alpha-beta-beta-beta-alpha structure in which the two alpha-helices lie on one face of a three-stranded anti-parallel beta-sheet. This structure is very similar to that of the N-terminal domain of a prokaryotic ribosomal protein S5. Furthermore, the consensus derived from all known S5p family sequences shares several conserved residues with the dsRBD consensus sequence, indicating that the two domains share a common evolutionary origin. Using in vitro mutagenesis, we have identified several surface residues which are important for the RNA binding of the dsRBD, and these all lie on the same side of the domain. Two residues that are essential for RNA binding, F32 and K50, are also conserved in the S5 protein family, suggesting that the two domains interact with RNA in a similar way.