Development of a species-specific PCR assay for detection of Leishmania donovani in clinical samples from patients with kala-azar and post-kala-azar dermal leishmaniasis.

We have developed a PCR assay that is capable of amplifying kinetoplast DNA (kDNA) of Leishmania donovani in a species-specific manner among Old World leishmanias. With Indian strains and isolates of L. donovani the assay was sensitive enough to detect kDNA in an amount equivalent to a single parasite or less. The extreme sensitivity of the assay was reflected in its ability to detect parasite DNA from small volumes of peripheral blood of patients with kala-azar (KA) and from skin lesions from patients with post-KA dermal leishmaniasis (PKDL). A total of 107 clinical leishmaniasis samples were analyzed. Of these 102 (95.3%) were positive by PCR. The test provided a diagnosis of KA with 96% sensitivity using patient whole-blood samples instead of bone marrow or spleen aspirates that are obtained by invasive procedures. The assay was also successful in the diagnosis of 45 of 48 PKDL cases (93.8%). Cross-reactions with pathogens prevalent in the area of endemicity, viz., Mycobacterium tuberculosis, Mycobacterium leprae, and Plasmodium spp., could be ruled out. Eighty-one control samples, including dermal scrapings from healthy portions of skin from patients with PKDL were all negative. Two of twenty controls from the area of endemicity were found positive by PCR assay; however, there was a good possibility that these two were asymptomatic carriers since they were serologically positive for KA. Thus, this PCR assay represents a tool for the diagnosis of KA and PKDL in Indian patients in a noninvasive manner, with simultaneous species identification of parasites in clinical samples.

Heterologous sequences greatly affect foreign gene expression in tobacco mosaic virus-based vectors.

A series of tobacco mosaic virus (TMV)-based hybrid vectors for transient gene expression were constructed with similar designs but differing in the source of heterologous tobamovirus sequence: Odontoglossum ringspot virus, tobacco mild green mosaic virus variants U2 and U5, tomato mosaic virus, and sunn-hemp mosaic virus. These vectors contained a heterologous coat protein subgenomic mRNA promoter and coat protein open reading frame (ORF) and either TMV or heterologous 3' nontranslated region. The foreign ORF, from the jellyfish green fluorescent protein (GFP) gene, was transcribed from the native TMV coat protein subgenomic mRNA promoter, which extended into the coat protein ORF. The presence of an in-frame stop codon within the GFP mRNA leader and the choice of sequence of GFP ORFs substantially affected translational efficiency. However, the major regulatory component of gene expression in these vectors appeared to be transcriptional rather than translational. There was an inverse relationship between expression of GFP and the heterologous coat protein genes that was reflected in accumulation of the respective mRNAs and proteins. The most effective vector in this series (30B) contained sequences encoding the coat protein subgenomic mRNA promoter, coat protein ORF, and 3' nontranslated region from tobacco mild green mosaic virus U5. Expressed from 30B, GFP accumulated up to 10% of total soluble protein in leaves.

Implications of calreticulin function in parasite biology.

Calreticulin (CR) is a Ca(2+)-binding, multifunctional protein. The amazing array of CR-associated functions range from intracellular activities in secondary messenger release, protein folding and the modulation of gene expression to potential interactions with host receptors and signaling machinery and recognition by the host immune system. The multifunctional nature of CR may impact upon the ability of cells to recognize extracellular stimuli and coordinate appropriate responses. Identification of CR isolated from parasites and the conservation of its functions suggests that investigations into the contributions of CR to various aspects of parasite biology should be undertaken because it may reveal information regarding parasite interaction with the host and how the parasite may modulate its response to the host.

Conservation of low-copy gene loci in Old World leishmanias identifies mechanisms of parasite evolution and diagnostic markers.

Genome plasticity has been hypothesized to be a driving force behind parasite speciation. We have evaluated divergence in single and low-copy genes in terms of locus organization, chromosomal localization and gene expression in Leishmania infantum, L. major, L. tropica and three widely divergent geographic isolates of L. donovani. Seventeen genes of low to moderate copy number (1-4 copies/haploid genome) were analyzed to identify restriction fragment length polymorphisms (RFLPs) providing heritable markers distinguishing Old World (OW) leishmanias. These RFLP markers were conserved in parasite isolates from primary infections demonstrating their utility as diagnostic tools. The species designations established by RFLP analysis of field isolates was confirmed by use of monoclonal antibodies. All 17 genes were present in each OW leishmania analyzed except LSIP (A45), which was absent from L. infantum. The 17 genes were found to be distributed among 9 distinct chromosomes. However, in spite of variations in chromosome karyotypes among the various OW leishmanias, individual gene probes localized to a similar sized chromosome from each isolate. These observations coupled with a molecular tree derived from RFLP data suggest that the OW leishmanias comprise a monophyletic lineage, with species associated with cutaneous disease exhibiting the greatest level of divergence. Data from this study supports previous observations that species causing cutaneous and visceral disease have diverged primarily by nucleotide substitutions. Such nucleotide divergence may not only lead to changes in protein function and antigenicity, but may also alter gene regulation programs as exemplified by the finding that the LdI-9-5 and LdE-6-1 genes were expressed only in visceralizing leishmanias.

Isolation and characterization of Leishmania donovani calreticulin gene and its conservation of the RNA binding activity.

Calreticulin has been implicated in multiple cell functions. Recently, we have shown that both human and simian calreticulin are RNA binding proteins and that their binding activity is due to phosphorylation. To demonstrate that the RNA binding property of calreticulin is an intrinsic part of this multi-functional molecule and is evolutionarily conserved, we isolated and characterized the calreticulin gene from the unicellular parasite, Leishmania donovani. Amino acid sequence homology between human and Leishmania calreticulin (L. d. cal) is limited, but like the human homologue, L. d. cal binds Ca+2, can be phosphorylated in vitro and binds certain RNA sequences in a phosphorylation-dependent manner. Unlike human calreticulin, L. d. cal is glycosylated and its binding to endogenous Leishmania RNA is phosphorylation-independent. The binding of L. d. cal to Leishmania RNA suggests that the RNA binding activity of calreticulin has remained evolutionarily conserved.

Autoantigens interact with cis-acting elements of rubella virus RNA.

Rubella virus (RV) infections in adult women can be associated with acute and chronic arthritic symptoms. In many autoimmune individuals, antibodies are found targeting endogenous proteins, called autoantigens, contained in ribonucleoprotein complexes (RNPs). In order to understand the molecular mechanisms involved in the RV-associated pathology, we investigated the nature of cellular factors binding RV RNA and whether such RNPs were recognized by antibodies in infected individuals. Previously, we noted that cellular proteins associated with the RV 5'(+) stem-loop (SL) RNA are recognized by serum with Ro reactivity. To better understand the nature of the autoantigens binding RV cis-acting elements, serum samples from individuals with various autoimmune diseases were tested for their ability to immunoprecipitate RNPs containing labeled RV RNAs. A subset of serum samples recognizing autoantigen La, or Ro and La, immunoprecipitated both the RV 5'(+)SL and 3'(+)SL RNA-protein complexes. Autoantigens binding the RV 5'(+)SL and 3'(+)SL RNAs differed in molecular mass, specificities for respective RNA binding substrates, and sensitivity to alkaline phosphatase treatment. The La autoantigen was found to interact with the RV 5'(+)SL RNA as determined by immunological techniques and binding reactions with mixtures containing recombinant La protein. To test whether there is a correlation between La binding to an RV RNA element and the appearance of an anti-La response, we measured anti-La titers in RV-infected individuals. Significant anti-La activity was detected in approximately one-third of RV-infected individuals 2 years postinfection.

Identification of differentially expressed Leishmania donovani genes using arbitrarily primed polymerase chain reactions.

Arbitrarily primed polymerase chain reactions (AP-PCR) were used to amplify polymorphic DNA fragments from the genomes of a variety of geographic isolates of Leishmania donovani (Ld). From the latter, five polymorphic DNA fragments were cloned and sequence analysis identified 15 unique clones. Northern blot analysis showed that 13 of the 15 clones hybridized to transcribed RNAs isolated from Ld. Eight of these 13 AP-PCR clones specifically hybridized to Ld RNAs that were differentially expressed in promastigote and 'amastigote' cells. Comparative Northern analysis of four differentially expressed AP-PCR clones indicated that two clones, LdS-14-14 and LdI-9-7, were expressed in Ld and several other Leishmania species. However, RNAs corresponding to two other AP-PCR clones, LdE-6-1 and LdI-9-5, were detected only in members of the Ld complex, and not in L. major (Lm) or L. tropica (Lt). Comparative Southern blot analysis of the LdS-14-14 locus revealed numerous restriction-fragment length polymorphisms (RFLP) distinguishing Lm and Lt from the Ld isolates and L. infantum. However, the LdS-14-14 loci were mapped to similar-sized chromosomes observed among all Old World Leishmania species tested, indicating that localized nucleotide divergence, not chromosomal rearrangement, was responsible for altered Southern blot patterns. These results demonstrate that AP-PCR is a very useful method for identifying expressed gene sequences in organisms of relatively low-complexity genomes. Interestingly, the majority of these sequences identified in this study correspond to differentially expressed genes.(ABSTRACT TRUNCATED AT 250 WORDS)

Identification of intra- and interspecific Leishmania genetic polymorphisms by arbitrary primed polymerase chain reactions and use of polymorphic DNA to identify differentially regulated genes.

Arbitrary primed polymerase chain reactions (AP-PCR) were used to amplify different polymorphic genomic DNA fragments from various Old World Leishmania species. Using four 10-mer AP primers, geographic isolates of L. donovani and various Old World species of Leishmania could be readily distinguished from one another by the pattern of amplified DNA products. Our studies confirmed two important characteristics of AP-PCR: its abilities to amplify a consistent pattern of DNA fragments from the genomes of different isolates of a single species and to identify genetic polymorphisms between the species isolates. We selected three polymorphic DNA fragments that differentiate L. donovani geographic isolates for further analysis. Sequence analysis of the clones derived from these three polymorphic fragments revealed eight unique sequences. Six of eight unique clones hybridized to distinct RNAs upon Northern-blot analysis. Three of these six clones hybridized to RNAs expressed differentially in in vitro grown L. donovani pro- and "amastigotes." One of the differentially expressed clones, LdE-6-1, exhibited restriction length polymorphisms that distinguished L. donovani from L. tropica and L. major. Comparative Northern blotting revealed that LdE-6-1 was differentially expressed in some members of the L. donovani species complex but not in L. major or L. tropica. These results demonstrate that AP-PCR can be used to generate products reflecting particular genes in organisms with low-complexity genomes.

Common replication strategies emerging from the study of diverse groups of positive-strand RNA viruses.

Studies using brome mosaic virus (BMV), Sindbis virus and poliovirus have provided evidence that disparate groups of plant and animal positive strand RNA viruses have remarkably similar replication strategies. The conservation of several functional domains within virus-encoded nonstructural proteins implies that, although the precise character of these and interacting host components varies for each virus, they employ similar mechanisms for RNA replication. For (+) strand replication, similarities in cis-acting sequence motifs and RNA secondary structures within 5' termini of genomic (+) strands have been identified and have been shown to participate in binding of host factors. The model presented for replication of BMV RNA suggests that binding of these factors to internal control region (ICR) sequence motifs in the double-stranded replication intermediate releases a single-stranded 3' terminus on the (-) strand that may be essential for initiation of genomic (+) strand synthesis. ICR sequences internal to the BMV genome were also found to be required for efficient replication. Asymmetric production of excess genomic (+) over (-) strand RNA, characteristic of all (+) strand viruses, may be accomplished through transition of the replicase from competence for (-) to (+) strand synthesis by the recruitment of additional host factors.

Identification and characterization of host factor interactions with cis-acting elements of rubella virus RNA.

We have analyzed the function of cis-acting elements of rubella virus RNA and the components which interact with these elements in viral RNA replication. We demonstrated that the 5'- and 3'-terminal sequences from RV RNA promote translation and negative-strand RNA synthesis of chimeric chloroamphenicol acetyltransferase (CAT) RNAs. These sequences have a potential to form stem-loop (SL) structures and bind cellular proteins specifically in RNA gel-shift and UV cross-linking assays. The 5' end binding proteins were identified to be Ro/SSA-associated antigens by virtue of being recognized in an RNA complex by an autoimmune patient serum with Ro antigen type specificity. Purification and sequence analysis of the 3' end binding protein revealed that it is a homologue of human calreticulin. The role of host protein in RV replication is discussed.

5' sequences of rubella virus RNA stimulate translation of chimeric RNAs and specifically interact with two host-encoded proteins.

Sequences at the 5' and 3' ends of the rubella virus (RV) genomic RNA can potentially form stable stem-loop (SL) structures that are postulated to be involved in virus replication. We have analyzed the function of these putative SL structures in RNA translation by constructing chimeric chloramphenicol acetyltransferase (CAT) RNAs, flanked either by both 5'- and 3'-terminal sequence domains from the RV genome or several deletion derivatives of the same sequences. After in vitro transcription of chimeric RNAs, the translational efficiencies of these RNAs were compared by the rabbit reticulocyte lysate translation system. For in vivo translation studies, the level of CAT activity was measured for chimeric RV/CAT RNAs expressed in transfected cells by the adenovirus major late promoter. Both in vivo and in vitro translation activities of the chimeric RNAs revealed that the presence of 5' and 3' SL sequences of RV RNA, in correct (+) orientation and context [5'(+)SL and 3'(+)SL, respectively] was necessary for efficient translation of chimeric RV/CAT RNAs. The presence of the RV 5'(+)SL sequence had the primary enhancing effect on translation. To identify host proteins which interact with the 5'(+)SL which may be involved in RV RNA translation, RNA gel-shift and UV cross-linking assays were employed. Two host proteins 59 and 52 kDa in size, present in cytosolic extracts from both uninfected and RV-infected cells, specifically interacted with the RV 5'(+)SL RNA. Direct binding comparisons between wild-type and mutant 5'(+)SL RNAs demonstrated that sequences in and around the bulge region of the terminal stem domain of this structure constituted a protein binding determinant. Human serum, qualified for anti-Ro/SS-A antigen specificity, immunoprecipitated 59- and 52-kDa protein-RNA complexes containing the RV 5'(+)SL RNA. However, poly- and monoclonal antisera raised against the recombinant 60- and 52-kDa Ro proteins failed to precipitate complexes containing the 5'(+)SL RNA. The identity of the proteins binding this RV cis-acting element remains to be determined; however, their role in RV translation is discussed.

Requirement for ICR-like sequences in the replication of brome mosaic virus genomic RNA.

Previous studies using a brome mosaic virus (BMV) RNA-2 deletion mutant (pRNA-2 M/S) and additional derivatives as reporters established that viral sequences resembling internal control regions (ICRs) 1 and 2 of tRNA gene promoters are vital to (+)-strand replication in protoplasts. Transfer of these mutations to genomic RNA-2 and functional analysis in protoplast, local lesion, and systemic infections revealed a sequence-specific requirement for bases within the ICR2-like motif. Despite the low (generally less than 20% of wild-type) and sometimes undetectable levels of replication of these RNA-2 mutants, sufficient p2a protein was produced to support at least modest levels of RNA-1, -3 and -4 replication in protoplasts. However, only those RNA-2 ICR2 mutants supporting substantial replication of the viral genome in protoplasts were capable of establishing local lesions in Chenopodium hybridum and systemic infections in barley, further establishing the essential role of the ICR-like sequences in viral infectivity. Upon passage through a second set of barley plants, accumulation patterns for progeny from inocula containing certain RNA-2 mutants paralleled those from wild-type inocula, indicating repair of the introduced mutations. RNA stability and translatability were shown to be unaffected by the introduced mutations. BMV RNA-3 contains several ICR-like sequences, each of which was individually deleted. Whereas deletion of the 5'-terminal ICR2-like motif had little effect on RNA-3 accumulation in protoplasts or local lesion formation, it debilitated systemic spread in barley. Deletion of an internal ICR2-like motif at position 1100 decreased (+):(-) strand asymmetry from greater than 100:1 to 14:1, reduced RNA-3 replication in protoplasts to less than 15% of wild-type, and abolished local lesion and systemic infectivity.

The requirement for a 5' stem-loop structure in brome mosaic virus replication supports a new model for viral positive-strand RNA initiation.

Sequences with strong similarity to internal control regions 1 and 2 (ICR1 and -2; A and B boxes) of tRNA genes are found at the 5' termini of the genomic RNAs of brome mosaic virus (BMV) and other plant viruses. The functionality of these motifs was studied by introducing point mutations into the ICR2-like sequence of pRNA-2 M/S, a BMV RNA-2 deletion mutant that replicates in the presence of RNAs-1 and -2 but does not encode a functional viral protein. The accumulation of positive-strand progeny from pRNAs bearing single and double base substitutions was 70 to 91% lower than that of the wild type, while the addition of single bases at position 8 of this motif reduced replication by 80%. These dramatic decreases in positive-strand synthesis paralleled decreases in transcription seen (C. Traboni, G. Ciliberto, and R. Cortese, Cell 36:179-187, 1984) from a tRNAPro gene containing similar mutations, suggesting comparable functions for the ICR regions in protein factor binding and demonstrating that a wild-type composition of the virus ICR2-like motif is required for proper RNA replication. Substitutions introduced at bases surrounding the ICR2 motif yielded levels of pRNA replication that differed, depending on the maintenance of a putative 5' stem-loop structure in the positive strand of the viral genome. Mutations disrupting this positive-strand stem-loop while maintaining the integrity of the complementary negative-strand structure reduced pRNA replication by 85 to 97%. In contrast, disruption of the negative-strand structure while maintaining the positive-strand stem-loop did not reduce pRNA replication. Similar positive-strand structures can be predicted to form from 5' sequences of cucumber mosaic virus (strain Q) and cowpea chlorotic mottle virus RNAs-1 and -2, supporting the concept that such structures comprise an integral part of virus genomic positive-strand promoters. The requirement of a stem-loop structure present on the positive-strand provided the basis for a new model describing how these sequence and structural elements act in the production of virus positive-strand RNA.

Non-replicating deletion mutants of brome mosaic virus RNA-2 interfere with viral replication.

Naturally occurring defective interfering RNAs (DI-RNAs) and satellite RNAs greatly reduce the accumulation of their helper virus in vivo, but often modulate symptom expression in an unpredictable manner. Deletion mutants Nc/S, Na/M and Sa/Nc + M/S, derived from brome mosaic virus (BMV) RNA-2, failed to replicate when co-inoculated with BMV RNAs-1 and -2 to barley protoplasts. However, the inoculum RNA corresponding to these deletion mutants was extremely stable and could have been mistaken for plus-strand progeny had minus-strand progeny analysis been omitted. These results accentuate the need for such tests in evaluating the ability of mutant viral sequences to replicate. One of the mutants, Nc/S, effectively interfered with the accumulation of BMV RNAs-1 and -2 in barley protoplasts. This non-replicating interfering RNA was termed NRI RNA-2 Nc/S. When present with RNAs-1 and -2 at low inoculum amounts (1 microgram), NRI RNA-2 Nc/S reduced replication of RNA-2, the parental RNA, by 63% and preferentially interfered with minus-strand RNA accumulation. At higher levels (4 micrograms), it completely displaced replication of both RNAs-1 and -2. Mutations eliminating translation of a truncated p2a protein from NRI RNA-2 Nc/S did not alleviate the interference effect, demonstrating that a defective replicase protein was not responsible for the decreased accumulation of genomic RNA. At an NRI RNA: genomic RNA inoculum molar ratio of 1:1, NRI RNA-2 Nc/S reduced the accumulation of all helper virus RNAs by 55%. Since this reduction was seen for both wild-type RNA-3 and delta SGP RNA-3, a deletion mutant of RNA-3 that lacks the subgenomic promoter necessary for coat protein expression, it was evident that the effective interference mediated by NRI RNA-2 Nc/S was not mitigated by encapsidation. The ability of the NRI RNAs to mimic satellite DI RNAs in depressing helper virus replication suggests that their expression in transgenic plants may provide a new and widely applicable approach for inducing resistance to viral infection.

Artificial defective interfering RNAs derived from brome mosaic virus.

Naturally occurring defective interfering RNAs (DI-RNAs) greatly reduce the accumulation of their helper virus in vivo, but are rarely associated with plant positive-strand RNA viruses. Deletion mutants pRNA-2 M/S and pRNA-2 E/S, derived from brome mosaic virus (BMV) genomic RNA-2, replicated in a manner dependent on BMV RNA-1 and -2, and effectively interfered with their accumulation in barley protoplasts. Based on their mode of replication, these mutant RNAs have been termed parasitic RNAs (pRNAs). When present with RNA-1 and -2 at low inoculum amounts, pRNA-2 M/S and pRNA-2 E/S reduced the level of replication of RNA-2, the parental RNA, by 37% and 64%, respectively. Greater amounts of pRNA in the inoculum completely eliminated the replication of both RNA-1 and -2. Mutations that prevented translation of truncated proteins from the pRNAs did not affect interference, but those that reduced pRNA replication decreased their ability to interfere with genomic RNA replication. At a molar pRNA: genomic RNA inoculum ratio of 1.5:1, pRNA-2 E/S reduced the accumulation of all helper virus RNAs by greater than 60%. This occurred in the presence of wild-type RNA-3 or delta SGP RNA-3, a deletion mutant of RNA-3 that lacks the subgenomic promoter necessary for coat protein expression, demonstrating that the interference mediated by the pRNAs was not effected by encapsidation. These data indicate that the expression of pRNAs that function as artificial DI-RNAs in transgenic plants may be an approach for inducing resistance to virus infection which is applicable to a wide range of plant viruses.

Regulation of (+):(-)-strand asymmetry in replication of brome mosaic virus RNA.

Transfection of barley protoplasts with brome mosaic virus (BMV) RNAs 1 + 2 in the absence of RNA-3 yielded a molar ratio for (+):(-)-strand progeny at 24 hr postinoculation near unity, whereas over 100-fold more (+)- than (-)-strand progeny accumulated in its presence. The presence of RNA-3 enhanced total (+)-strand RNA production 205-fold and that of RNAs 1 + 2 by 29-fold. In contrast, total (-)-strand RNA accumulation decreased by 68% and that for (-)RNAs 1 + 2 by 79% in the presence of RNA-3. Transfections containing an RNA-3 mutant (Gsgi----U RNA-3) that is incapable of yielding RNA-4 as a result of a single nucleotide substitution at the subgenomic RNA initiation site yielded only 66% of the (+):(-) asymmetry seen in the presence of wild-type RNA-3. Only 1.8-fold excess of (+)-over (-)-strand production was obtained for transfections that included delta SGP RNA-3, a deletion that includes the subgenomic promoter core and extends 43 nt into the RNA-4 sequence. Transfections containing RNA-3 mutants bearing frameshifts or deletions in the coat protein cistron yielded levels of asymmetry similar to those seen for Gsgi----U RNA-3. These findings implicate the subgenomic promoter and other sequences in the intercistronic region of RNA-3 as the primary determinants of asymmetric replication, although the coat protein may be an additional factor enhancing the accumulation of (+)-strand RNA.

Point mutations in the ICR2 motif of brome mosaic virus RNAs debilitate (+)-strand replication.

Sequences at the 5' termini of the genomic RNAs of brome mosaic virus (BMV) and other (+)-stranded RNA viruses have been shown (L.E. Marsh and T.C. Hall, 1987, Cold Spring Harbor Symp. Quant. Biol. 52, 331-341) to resemble the ICRs 1 and 2 (A and B boxes) of tRNA genes, with the complementary sequences at the 3' termini of the (-) strands resembling the ICR2 motif of methionine initiator tRNA genes (L.E. Marsh, G.P. Pogue, and T.C. Hall, 1989, Virology 172, 415-427). In order to examine the role of these sequences in viral replication, point mutations have been introduced into the ICR2-like sequence of a BMV RNA-2 deletion mutant, pRNA delta M/S (parasitic RNA), that does not encode a functional viral protein but replicates in the presence of genomic RNA-1 and -2. Single-base substitutions introduced at positions A7 or T8 of the (+)-sense ICR2-like motif reduced pRNA delta M/S replication by 70-82%, the primary effect being shown by kinetic analyses to be debilitation of (+)-strand synthesis. Whether these motifs act in their (+)-sense orientation in a manner analogous to tRNA genes or through the tRNA(Meti)-like sequence on the 3' (-) strand remains to be determined, but the data clearly demonstrate that the base composition within the ICR-like region of BMV RNAs contributes greatly to (+)-strand promoter function.

Similarities among plant virus (+) and (-) RNA termini imply a common ancestry with promoters of eukaryotic tRNAs.

The 5' ends of brome mosaic virus (BMV) RNAs contain sequences similar to the consensus internal control region (ICR) of pol III promoters in tRNA genes. Comparison of BMV (+)RNA 5' termini with BMV (-)RNA termini revealed the presence of two (tandem) repeats of some 30 nucleotides, the more internal containing a region of 73% similarity to the tRNA consensus ICR2 (downstream) region of the ICR. Tandem repeats containing motifs similar to the ICR2 consensus were found at the 5' termini of (-)RNAs of cucumo-, tobamo-, and tymoviruses whose 3' (+)RNAs have aminoacylatable tRNA-like structures. Single regions of homology to the BMV(+)RNA 5' terminus, containing an ICR2-like motif, were detected for several tobravirus RNAs, and for satellite tobacco necrosis virus RNA. The (+)-stranded genomes of these viruses have not been shown to be capable of amino acid esterification. The ICR2 consensus (GGUUCGANUCC) is nearly palindromic, and is contained with the T psi C loop of tRNAs and viral analogs. Consequently, tRNA promoter-like motifs can be seen at both termini of (+) and (-) RNAs of bromoviruses and other viruses. The presence of ICR1 and ICR2-like sequences in BMV genomic 5' (+)RNAs and the tobamovirus 5' (-)RNAs may reflect promoter arrangements of primordial genomic RNAs ancestral to both modern plant viruses and eukaryotic tRNAs. Several derivative concepts related to genome evolution are discussed, including the origin of asymmetric strand synthesis of RNAs.