Polycistronic pre-mRNAs from Caenohabditis elegans operons are processed by internal cleavage and polyadenylation to create 3' ends of mature mRNAs. This is accompanied by trans-splicing with SL2 approximately 100 nucleotides downstream of the 3' end formation sites to create the 5' ends of downstream mRNAs. SL2 trans-splicing depends on a U-rich element (Ur), located approximately 70 nucleotides upstream of the trans-splice site in the intercistronic region (ICR), as well as a functional 3' end formation signal. Here we report the existence of a novel gene-length RNA, the Ur-RNA, starting just upstream of the Ur element. The expression of Ur-RNA is dependent on 3' end formation as well as on the presence of the Ur element, but does not require a trans-splice site. The Ur-RNA is not capped, and alteration of the location of the Ur element in either the 5' or 3' direction alters the location of the 5' end of the Ur-RNA. We propose that a 5' to 3' exonuclease degrades the precursor RNA following cleavage at the poly(A) site, stopping when it reaches the Ur element, presumably attributable to a bound protein. Part of the function of this protein can be performed by the MS2 coat protein. Recruitment of coat protein to the ICR in the absence of the Ur element results in accumulation of an RNA equivalent to Ur-RNA, and restores trans-splicing. Only SL1, however, is used. Therefore, coat protein is sufficient for blocking the exonuclease and thereby allowing formation of a substrate for trans-splicing, but it lacks the ability to recruit the SL2 snRNP. Our results also demonstrate that MS2 coat protein can be used as an in vivo block to an exonuclease, which should have utility in mRNA stability studies.

The development of multicellular organisms requires precise spatiotemporal gene expression and the expression of cell/tissue specific isoforms of some genes. This task may require more efficient genome organization in Caenorhabditis elegans and other organisms with relatively small genome size. The SL1 leader sequence is trans-spliced to many mRNAs in C. elegans. We hypothesize that introns coupled to internal SL1 acceptors contain independent promoters. We identify 238 genes that have introns coupled to internal SL1 acceptors. We find that the mean length of the internal SL1-coupled introns is significantly longer than the genome mean. For twelve of the genes, evidence exists that the intronic promoter provides tissue specificity different from that of the primary promoter. We estimate that 2.7% of the genome is regulated through this two-promoter system. We propose that internal SL1-coupled introns function as independent promoters and that this two-promoter system represents a major mechanism in C. elegans, in addition to alternative splicing, that serves to promote tissue-specific expression of protein isoforms. Our finding of the frequent coupling between an internal SL1 and a large immediately upstream intron will make promoters and transcription start sites predictable.

Phospho-beta-galactosidase (P-beta-gal), the enzyme which catalyzes the first step in the metabolism of intracellular lactose phosphate, occurred at high specific activity in the cytoplasm in 12 of 13 strains of streptococcus mutans grown on lactose but not other carbon sources. The P-beta-gal from S. mutans SL1 was purified 13-fold using diethylaminoethyl-cellulose ion exchange and agarose A--0.5 M molecular exclusion column chromatography. The molecualr weight of the enzyme was estimated to be 40,000, and its pH optimum was 6.5 in three different buffer systems. P-beta-gal activity was inhibited by Co2+, Zn2+, and Cu2+, but other cations, ethylenediaminetetraacetic acid, orthophosphate, and fluoride had no effect upon enzyme activity. The kinetic response of P-beta-gal to a model substrate, o-nitrophenyl-beta-D-galactopyranoside-6-phosphate, obeyed Michaelis-Menten kinetics, and the Km for this substrate was 0.19 mM. In addition to being under genetic control, P-beta-gal activity was regulated by a number of biologically active metabolites. Enzyme activity was inhibited in a sigmoidal fashion by phosphoenolpyruvate. The M 0.5 V value for phosphoenolpyruvate was 2.8 mM, and the Hill coefficient (n) was 3. In addition, P-beta-gal exhibited strong inhibition by ATP, galactose-6-phosphate, and glucose-6-phosphate. In contrast to inhibition of P-beta-gal activity by phosphoenolpyruvate, the inhibition exerted by ATP, galactose-6-phosphate, and glucose-6-phosphate obeyed classical Michaelis-Menten kinetics; the Ki values for these inhibitors were 0.55, 1.6, and 4.0 mM, respectively.

A number of candidate tobacco proteins that bind to cis-acting elements (SL1 RNAs) of Potato virus X (PVX) have been identified in previous studies. We further characterized TMV-MP30 binding protein 2C (MPB2C) homologous protein. We isolated NbMPB2Cb from Nicotiana benthamiana and confirmed the interaction of NbMPB2Cb with SL1 RNAs in vitro. The mRNA level of NbMPB2Cb was increased upon infection by PVX and Tobacco mosaic virus. The movement of PVX was reduced by overexpression of NbMPB2Cb and increased by silenced of NbMPB2Cb. In contrast, PVX RNA accumulation was not significantly altered in protoplasts. Protein-protein interaction assays showed that NbMPB2Cb interacts with PVX movement-associated proteins. PVX infection altered the subcellular localization of NbMPB2Cb from microtubules to endoplasmic reticulum. These data suggest that the NbMPB2Cb negatively affects PVX movement by interacting with SL1 RNAs and movement-associated proteins of PVX and by re-localizing in response to PVX infection.

Structure predictions suggest a partial conservation of RNA structure elements in coronavirus terminal genome regions. Here, we determined the structures of stem-loops (SL) 1 and 2 of two alphacoronaviruses, human coronavirus (HCoV) 229E and NL63, by RNA structure probing and studied the functional relevance of these putative cis-acting elements. HCoV-229E SL1 and SL2 mutants generated by reverse genetics were used to study the effects on viral replication of single-nucleotide substitutions predicted to destabilize the SL1 and SL2 structures. The data provide conclusive evidence for the critical role of SL1 and SL2 in HCoV-229E replication and, in some cases, revealed parallels with previously characterized betacoronavirus SL1 and SL2 elements. Also, we were able to rescue viable HCoV-229E mutants carrying replacements of SL2 with equivalent betacoronavirus structural elements. The data obtained in this study reveal a remarkable degree of structural and functional conservation of 5'-terminal RNA structural elements across coronavirus genus boundaries.

In this study, we characterize three phages (SL1 SL2, and SL4), isolated from hospital sewage with lytic activity against clinical isolates of multi-drug resistant Pseudomonas aeruginosa (MDR-PA). The host spectrum ranged from 41% to 54%, with all three phages together covering 79% of all tested clinical isolates. Genome analysis revealed that SL1 (65,849 bp, 91 open reading frames ORFs) belongs to PB1-like viruses, SL2 (279,696 bp, 354 ORFs) to phiKZ-like viruses and SL4 (44,194 bp, 65 ORFs) to LUZ24-like viruses. Planktonic cells of four of five selected MDR-PA strains were suppressed by at least one phage with multiplicities of infection (MOIs) ranging from 1 to 10-6 for 16 h without apparent regrowth of bacterial populations. While SL2 was most potent in suppressing planktonic cultures the strongest anti-biofilm activity was observed with SL4. Phages were able to rescue bacteria-infected wax moth larvae (Galleria melonella) for 24 h, whereby highest survival rates (90%) were observed with SL1. Except for the biofilm experiments, the effect of a cocktail with all three phages was comparable to the action of the best phage alone; hence, there are no synergistic but also no antagonistic effects among phages. The use of a cocktail with these phages is therefore expedient for increasing host range and minimizing the development of phage resistance.

SARS-CoV-2 is the cause of the ongoing Coronavirus disease 19 (COVID-19) pandemic around the world causing pneumonia and lower respiratory tract infections. In understanding the SARS-CoV-2 pathogenicity and mechanism of action, it is essential to depict the full repertoire of expressed viral proteins. The recent biological studies have highlighted the leader protein Nsp1 of SARS-CoV-2 importance in shutting down the host protein production. Besides, it still enigmatic how Nsp1 regulates for translation. Here we report the novel structure of Nsp1 from SARS-CoV-2 in complex with the SL1 region of 5'UTR of SARS-CoV-2, and its factual interaction is corroborated with enzyme kinetics and experimental binding affinity studies. The studies also address how leader protein Nsp1 of SARS-CoV-2 recognizes its self RNA toward translational regulation by further recruitment of the 40S ribosome. With the aid of molecular dynamics and simulations, we also demonstrated the real-time stability and functional dynamics of the Nsp1/SL1 complex. The studies also report the potential inhibitors and their mode of action to block viral protein/RNA complex formation. This enhance our understanding of the mechanism of the first viral protein Nsp1 synthesized in the human cell to regulate the translation of self and host. Understanding the structure and mechanism of SARS-CoV-2 Nsp1 and its interplay with the viral RNA and ribosome will open the arena for exploring the development of live attenuated vaccines and effective therapeutic targets for this disease.

Flavivirus gene expression is modulated by RNA secondary structure elements at the terminal ends of the viral RNA molecule. For tick-borne encephalitis virus (TBEV), four stem-loop (SL) elements have been predicted in the first 180 nucleotides of the viral genome: 5'-SL1, 5'-SL2, 5'-SL3 and 5'-SL4. The last three of these appear to be unique to tick-borne flaviviruses. Here, we report their characterization by mutagenesis in a TBEV luciferase reporter system. By manipulating their thermodynamic properties, we found that an optimal stability of the 5'-SL2 is required for efficient RNA replication. 5'-SL3 formation is also important for viral RNA replication, but although it contains the viral start codon, its formation is dispensable for RNA translation. 5'-SL4 appears to facilitate both RNA translation and replication. Our data suggest that maintenance of the balanced thermodynamic stability of these SL elements is important for temporal regulation of its different functions.

OBJECTIVE

Extracorporeal shock wave therapy (ESWT) for Peyronie's disease is still a topic of debate. We evaluated the effects of ESWT in a large series of patients with Peyronie's disease via a prospective approach.

METHODS

In a prospective study 114 patients with Peyronie's disease were treated with ESWT. Baseline and followup examinations included ultrasound, and measurement of plaque size and curvature. Symptomatology was evaluated based on a standardized interview. A Minilith SL1 (Storz Medical AG, Kreuzlingen, Switzerland) lithotriptor was used with 4,000 shock waves at a maximum energy level of 0.17 mJ/mm2 applied per session.

RESULTS

A total of 96 patients were available for followup. Considering the total study group no significant changes in penile curvature, plaque size or sexual function were observed despite significant improvements in patients with a curvature of 31 to 60 degrees. Penile pain ceased in 76% of the affected patients.

CONCLUSIONS

According to our data ESWT does not appear to be significantly effective for decreasing penile curvature and plaque size or improving sexual function in the total population of patients with Peyronie's disease despite improvements in individuals. Penile pain seems to resolve earlier than during the natural course. Regarding the results of this study and previous reports with exact documentation of the clinical findings it can be concluded that ESWT cannot be recommended as a standard procedure for Peyronie's disease. To evaluate the exact efficacy of ESWT a controlled, single-blind, multicenter study with exact documentation of symptoms is urgently required.

SmY RNAs are a family of approximately 70-90 nt small nuclear RNAs found in nematodes. In C. elegans, SmY RNAs copurify in a small ribonucleoprotein (snRNP) complex related to the SL1 and SL2 snRNPs that are involved in nematode mRNA trans-splicing. Here we describe a comprehensive computational analysis of SmY RNA homologs found in the currently available genome sequences. We identify homologs in all sequenced nematode genomes in class Chromadorea. We are unable to identify homologs in a more distantly related nematode species, Trichinella spiralis (class: Dorylaimia), and in representatives of non-nematode phyla that use trans-splicing. Using comparative RNA sequence analysis, we infer a conserved consensus SmY RNA secondary structure consisting of two stems flanking a consensus Sm protein binding site. A representative seed alignment of the SmY RNA family, annotated with the inferred consensus secondary structure, has been deposited with the Rfam RNA families database.

Different DNA extraction protocols were evaluated on a reference soil. A wide difference was found in the total extractable DNA as derived from different extraction protocols. Concerning the DNA yield phenol-chloroform-isomyl alcohol extraction resulted in high DNA yield but also in a remarkable co-extraction of contaminants making PCR from undiluted DNA extracts impossible. By comparison of two different extraction kits, the Macherey&Nagel SoilExtract II kit resulted in the highest DNA yields when buffer SL1 and the enhancer solution were applied. The enhancer solution not only significantly increased the DNA yield but also the amount of co-extracted contaminates, whereas additional disintegration strategies did not. Although a three times repeated DNA extraction increased the total amount of extracted DNA, microbial fingerprints were merely affected. However, with the 5th extraction this changed. A reduction of total DGGE band numbers was observed for archaea and fungi, whereas for bacteria the diversity increased. The application of ethidium monoazide (EMA) or propidium monoazide (PMA) treatment aiming on the selective removal of soil DNA derived from cells lacking cell wall integrity resulted in a significant reduction of total extracted DNA, however, the hypothesized effect on microbial fingerprints failed to appear indicating the need for further investigations.

BACKGROUND

Genomic RNA dimerization is an important process in the formation of an infectious lentiviral particle. One of the signals involved is the stem-loop 1 (SL1) element located in the leader region of lentiviral genomic RNAs which also plays a role in encapsidation and reverse transcription. Recent studies revealed that HIV types 1 and 2 leader RNAs adopt different conformations that influence the presentation of RNA signals such as SL1. To determine whether common mechanisms of SL1 regulation exist among divergent lentiviral leader RNAs, here we compare the dimerization properties of SIVmac239, HIV-1, and HIV-2 leader RNA fragments using homologous constructs and experimental conditions. Prior studies from several groups have employed a variety of constructs and experimental conditions.

RESULTS

Although some idiosyncratic differences in the dimerization details were observed, we find unifying principles in the regulation strategies of the three viral RNAs through long- and short-range base pairing interactions. Presentation and efficacy of dimerization through SL1 depends strongly upon the formation or dissolution of the lower stem of SL1 called stem B. SL1 usage may also be down-regulated by long-range interactions involving sequences between SL1 and the first codons of the gag gene.

CONCLUSIONS

Despite their sequence differences, all three lentiviral RNAs tested in this study showed a local regulation of dimerization through the stabilization of SL1.

In Caenorhabditis elegans, the transcripts of many genes are trans-spliced to an SL1 spliced leader, a process that removes the RNA extending from the transcription start site to the trans-splice site, thereby making it difficult to determine the position of the promoter. Here we use RT-PCR to identify promoters of trans-spliced genes. Many genes in C. elegans are organized in operons where genes are closely clustered, typically separated by only ~100 nucleotides, and transcribed by an upstream promoter. The transcripts of downstream genes are trans-spliced to an SL2 spliced leader. The polycistronic precursor RNA is processed into individual transcripts by 3' end formation and trans-splicing. Although the SL2 spliced leader does not appear to be used for other gene arrangements, there is a relatively small number of genes whose transcripts are processed by SL2 but are not close to another gene in the same orientation. Although these genes do not appear to be members of classical C. elegans operons, we investigated whether these might represent unusual operons with long spacing or a different, nonoperon mechanism for specifying SL2 trans-splicing. We show transcription of the entire region between the SL2 trans-spliced gene and the next upstream gene, sometimes several kilobases distant, suggesting that these represent exceptional operons. We also report a second type of atypical "alternative" operon, in which 3' end formation and trans-splicing by SL2 occur within an intron. In this case, the processing sometimes results in a single transcript, and sometimes in two separate mRNAs.

Transcription of ribosomal genes requires, in addition to RNA polymerase I, the trans-acting factors UBF and Rib1 in Xenopus or SL1 in humans. RNA polymerase I transcription is remarkably species specific. Between closely related species SL1 is the sole determinant of this specificity. Between more distantly related species, however, UBF is also a component of this species specificity. Xenopus UBF cannot function in human RNA polymerase I transcription and human UBF cannot function in Xenopus RNA polymerase I transcription. Xenopus and human UBFs are remarkably similar at the amino acid sequence level, both containing multiple HMG box DNA binding motifs. The only major difference between xUBF and hUBF is the lack of a HMG box 4 equivalent in xUBF. Utilizing a series of hybrid UBF molecules we have identified HMG box 4 as the principal determinant of species specificity. Addition of human HMG box 4 to xUBF converts it to a form that functions in human RNA polymerase I transcription. Deletion of HMG box 4 from hUBF converts it to a form that functions in Xenopus RNA polymerase I transcription. Furthermore, mutations within Xenopus UBF demonstrate that UBF requires a precise arrangement and number of HMG boxes to function in RNA polymerase I transcription.

RNA loop-loop interactions are essential for genomic RNA dimerization and regulation of gene expression. In this article, a statistical mechanics-based computational method that predicts the structures and thermodynamic stabilities of RNA complexes with loop-loop kissing interactions is described. The method accounts for the entropy changes for the formation of loop-loop interactions, which is a notable advancement that other computational models have neglected. Benchmark tests with several experimentally validated systems show that the inclusion of the entropy parameters can indeed improve predictions for RNA complexes. Furthermore, the method can predict not only the native structures of RNA/RNA complexes but also alternative metastable structures. For instance, the model predicts that the SL1 domain of HIV-1 RNA can form two different dimer structures with similar stabilities. The prediction is consistent with experimental observation. In addition, the model predicts two different binding sites for hTR dimerization: One binding site has been experimentally proposed, and the other structure, which has a higher stability, is structurally feasible and needs further experimental validation.

The process of trans-splicing involves the transfer of a short spliced leader (SL) RNA sequence to a consensus acceptor site on a separate pre-mRNA transcript. In this study, the first stem loop of the SL1 RNA from the nematode Caenorhabditis elegans was examined by homonuclear and heteronuclear NMR. Results of enzymatic cleavage patterns established that the first 36 nucleotides (which includes the splice site and a complementary base-paired region surrounding a nine-nucleotide hairpin loop) remain structurally independent of the rest of the 100-nucleotide full-length transcript. A comparison of exchangeable and non-exchangeable proton chemical shifts in the region of the splice site and loop between the native sequence and a modified 26-nucleotide fragment from which an asymmetric internal loop had been deleted was made. There was no significant difference between the resonance locations of the equivalent protons in the two molecules, establishing that there was no tertiary interaction between the hairpin and internal loops. Full chemical shift assignments of 1H, 13C, and 15N chemical shifts were obtained for the modified fragment by multidimensional homonuclear and heteronuclear NMR spectroscopy. The stem adopts an A-form helix typical of RNA. The A-type helical conformation of the stem appears to continue for the first three nucleotides of the 5' side of the loop, followed by a guanosine residue in a syn conformation about the glycosidic bond. Base stacking is not seen on the 3' side of the loop. There was no evidence for formation of Watson-Crick base-pairs within the loop, but several long distance NOEs indicated cross-loop contacts, indicative of a structured loop. The final loop residues, an adenine which is conserved among all known nematode SL RNA sequences, adopts an extrahelical conformation.

The nature of specific RNA-RNA and protein-RNA interactions involved in the process of genome dimerization and isomerization in HIV-1, which is mediated in vitro by stemloop 1 (SL1) of the packaging signal and by the nucleocapsid (NC) domain of the viral Gag polyprotein, was investigated by using archetypical nucleic acid ligands as noncovalent probes. Small-molecule ligands make contact with their target substrates through complex combinations of H-bonds, salt bridges, and hydrophobic interactions. Therefore, their binding patterns assessed by electrospray ionization mass spectrometry can provide valuable insights into the factors determining specific recognition between species involved in biopolymer assemblies. In the case of SL1, dimerization and isomerization create unique structural features capable of sustaining stable interactions with classic nucleic acid ligands. The binding modes exhibited by intercalators and minor groove binders were adversely affected by the significant distortion of the duplex formed by palindrome annealing in the kissing-loop (KL) dimer, whereas the modes observed for the corresponding extended duplex (ED) confirmed a more regular helical structure. Consistent with the ability to establish electrostatic interactions with highly negative pockets typical of helix anomalies, polycationic aminoglycosides bound to the stem-bulge motif conserved in all SL1 conformers, to the unpaired nucleotides located at the hinge between kissing hairpins in KL, and to the exposed bases flanking the palindrome duplex in ED. The patterns afforded by intercalators and minor groove binders did not display detectable variations when the corresponding NC-SL1 complexes were submitted to probing. In contrast, aminoglycosides displayed the ability to compete with the protein for overlapping sites, producing opposite effects on the isomerization process. Indeed, displacing NC from the stem-bulges of the KL dimer induced inhibition of stem melting and decreased the efficiency of isomerization. Competition for the hinge region, instead, eliminated the NC stabilization of a grip motif formed by nucleobases of opposite strands, thus facilitating the strand-exchange required for isomerization. These noncovalent probes provided further evidence that the structural context of the actual binding sites has significant influence on the chaperone activities of NC, which should be taken in account when developing potential drug candidates aimed at disrupting genome dimerization and isomerization in HIV-1.

High altitude (HA)-induced diuresis is associated with marked changes in sodium and water regulating hormones, particularly the renin-angiotensin-aldosterone system (RAAS) and atrial natriuretic hormone (ANH). These hormones are also strongly stimulated by physical exercise, which is a major component of daily activity at HA. In spite of the numerous studies in literature, a clear relationship between hormonal changes, HA diuresis, and physical exercise has not yet been established. We therefore evaluated the response of sodium regulating hormones to exhaustive exercise in a group of seven males exposed to prolonged HA hypoxia. The study was divided into four phases: sea level (SL1), after 7 (P1) and after 21 (P2) days at 5050 m (Italian National Research Council Pyramid Laboratory, Nepal), and back at sea level (SL2). At each phase plasma hematocrit (Ht), total body water (TBW), 24-hr sodium excretion (uNa), and urinary volume (uV) were evaluated together with PRA, plasma aldosterone, and ANH, in samples drawn basally from patients in upright position, and at the end of graded step-wise (30 W/2 min) maximal exercise. Levels of uNa and uV were raised at P1 and then declined at P2, with a parallel decrease in TBW and an increase in Ht. Basal PRA and aldosterone levels were suppressed both at P1 and P2 (from 1.9 +/- 0.4 to 0.08 +/- 0.03 and 0.5 +/- 0.1 ng/mL/3 h, and from 7.9 +/- 1.8 to 3.9 +/- 0.4 and 4.5 +/- 0.4 ng/dL, respectively; P < .05). Exhaustive exercise at HA did not induce any significant response in PRA and aldosterone, unlike SL1. Otherwise at P1 ANH levels remained unchanged both basally and during exercise, while at P2 they decreased significantly vs. SL1, both basally and after exercise (from 13.3 +/- 5.7 to 3.5 +/- 1.2 and from 40.2 +/- 10.2 to 17.5 +/- 8.3, respectively; P < .05). Our data show that PRA and aldosterone levels were constantly suppressed at HA and were unresponsive to exercise, whereas the ANH response was significantly stimulated during acute HA exposure, but not during chronic exposure. This suggests that hypoxia-induced chemoreceptor stimulation may cause the natriuretic phenomenon through direct suppression of the RAAS.

Citrus tristeza virus (CTV), a member of the Closteroviridae, has a 19.3-kb messenger-sense RNA genome consisting of 12 open reading frames with nontranslated regions (NTR) at the 5' and 3' termini. The 273 nucleotide (nt) 3'-NTR is highly conserved ( approximately 95%) among the sequenced CTV isolates in contrast to the highly diverse 5'-NTR sequences. The 3' replication signals were mapped to the 3' 234 nts within the NTR. This region of CTV does not contain a poly-A tract nor does it appear to fold as a tRNA-mimic. Instead, a computer-predicted thermodynamically stable secondary structure comprised of 10 stem-and-loop (SL) structures, referred to as <em>SL1</em> to <em>SL1</em>0 (5' to 3'), was common to all CTV isolates. This putative structure was used as a guide to examine the 3' requirements for replication in vivo. The resulting data suggest that a complex 3' structure is required for those functions that provide for efficient replication of CTV in vivo such as minus-strand initiation, regulation of strand asymmetry, effective translation of the myriad of viral mRNAs, or stability of RNAs. Deletions into the 3'-NTR, up to 66 nts from the 5' direction and 11 nts from the 3' direction, deleting or disrupting putative <em>SL1</em>, SL2 and SL3, or <em>SL1</em>0, resulted in continued replication, suggesting that these sequences are not essential for basal-level replication, but are required for efficient replication. Predicted stem loops 3 through 10 were examined by mutations designed to alter the primary structures while preserving the secondary structures. Mutations designed to disrupt the predicted stems of SL3, SL5, SL7, SL9, or <em>SL1</em>0 resulted in substantially reduced levels of replication, while compensatory mutations resulted in partial restorations of replication, suggesting that these predicted secondary structures are involved in replication. Also, the putative loop sequences of SL5, SL6, SL7, and SL9 tolerated mutagenesis with continued but reduced levels of replication. In contrast, all mutations introduced into putative SL4, SL8, and the stem of SL6 prevented replication, suggesting that the primary structure of these regions make up the core of the 3' replication signal. The 3' triplet, CCA, was shown to be necessary for efficient replication, but deletion of eleven nts to expose an internal CCA resulted in continued replication.

Plant viruses must interact with host cellular components to replicate and move from cell to cell. In the case of Potato virus X (PVX), it carries stem-loop 1 (SL1) RNA essential for viral replication and movement. Using two-dimensional electrophoresis northwestern blot analysis, we previously identified several host proteins that bind to SL1 RNA. Of those, we further characterized a DnaJ-like protein from Nicotiana benthamiana named NbDnaJ. An electrophoretic mobility shift assay confirmed that NbDnaJ binds only to SL1 minus-strand RNA, and bimolecular fluorescence complementation (BiFC) indicated that NbDnaJ interacts with PVX capsid protein (CP). Using a series of deletion mutants, the C-terminal region of NbDnaJ was found to be essential for the interaction with PVX CP. The expression of NbDnaJ significantly changed upon infection with different plant viruses such as PVX, Tobacco mosaic virus, and Cucumber mosaic virus, but varied depending on the viral species. In transient experiments, both PVX replication and movement were inhibited in plants that over-expressed NbDnaJ but accelerated in plants in which NbDnaJ was silenced. In summary, we suggest that the newly identified NbDnaJ plays a role in PVX replication and movement by interacting with SL1(-) RNA and PVX CP.

The 72nt 3' non-translated region (NTR) of potato virus X (PVX) RNA is identical in all sequenced PVX strains and contains sequences that are conserved among all potexviruses. Computer folding of the 3' NTR sequence predicted three stem-loop structures (SL1, SL2, and SL3 in the 3' to 5' direction), which generally were supported by solution structure analyses. The importance of these sequence and/or structural elements to PVX RNA accumulation was further analyzed by inoculation of Nicotiana tabacum (NT-1) protoplasts with PVX transcripts containing mutations in the 3' NTR. Analyses of RNA accumulation by S(1) nuclease protection indicated that multiple sequence elements throughout the 3' NTR were important for minus-strand RNA accumulation. Formation of SL3 was required for accumulation of minus-strand RNA, whereas SL1 and SL2 formation were less important. However, sequences within all of these predicted structures were required for minus-strand RNA accumulation, including a conserved hexanucleotide sequence element in the loop of SL3, and the CU nucleotide in a U-rich sequence within SL2. In contrast, 13 nucleotides that were predicted to reside in SL1 could be deleted without any significant reduction in minus or plus-strand RNA levels. Potential polyadenylation signals (near upstream elements; NUEs) in the 3' NTR of PVX RNA were more important for plus-strand RNA accumulation than for minus-strand RNA accumulation. In addition, one of these NUEs overlapped with other sequence required for optimal minus-strand RNA levels. These data indicate that the PVX 3' NTR contains multiple, overlapping elements that influence accumulation of both minus and plus-strand RNA.

The ubiquitous enzymes peptidyl prolyl cis-trans isomerase (PPI, EC 5.2.1.8) and protein disulfide isomerase (PDI, EC 5.3.4.1) are important rate-limiting catalysts of protein-folding events in the cell. In the free-living nematode Caenorhabditis elegans, two genes encoding these enzymes (cyp-9 and pdi-1, respectively) are clustered together on chromosome III. In work described elsewhere, the encoded enzymes have been expressed as recombinant proteins and have been determined to possess in vitro PPI and PDI activity. Taken together, this organization of the two genes and the related functions of their transcripts indicate that they may be cotranscribed as a polycistronic unit, similar to bacterial operons. This study details the very close linkage of pdi-1 and cyp-9, which are in the same orientation. pdi-1 is the upstream gene, and the putative polyadenylation cleavage signal of this gene is separated from the trans-splice acceptor site of cyp-9 by only 103 bp. pdi-1 is trans-spliced by the ubiquitous nematode trans-spliced leader SL1, whereas cyp-9 was found to be predominantly trans-spliced by the "operon-specific" trans-spliced leader SL2. Similar trends in relative transcript abundance were demonstrated with synchronously produced mRNA for both genes during larval development, supporting the contention that the genes are co-expressed. Finally, reporter gene analysis provides strong evidence that both genes are controlled by a single upstream regulatory element, which directs expression of both enzymes in the hypodermal cells that synthesize the cuticle.

The gene (odc-1) encoding ornithine decarboxylase, a key enzyme in polyamine biosynthesis, was cloned and characterized. Two introns interrupt the coding sequence of the gene. The deduced protein contains 422 amino acids and is homologous to ornithine decarboxylases of other eukaryotic species. In vitro translation of a transcript of the cDNA yielded an enzymatically active product. The mRNA is 1.5 kb in size and is formed by trans-splicing to SL1, a common 5' RNA segment. odc-1 maps to the middle of LG V, between dpy-11 and unc-42 and near a breakpoint of the nDf32 deficiency strain. Enzymatic activity is low in starved stage 1 (L1) larva and, after feeding, rises progressively as the worms develop. Targeted gene disruption was used to create a null allele. Homozygous mutants are normally viable and show no apparent defects, with the exception of a somewhat reduced brood size. In vitro assays for ornithine decarboxylase activity, however, show no detectable enzymatic activity, suggesting that ornithine decarboxylase is dispensible for nematode growth in the laboratory.

Gametocidal (Gc) genes in Aegilops species are known to cause gamete abortion and chromosome breakage when they are introduced into the wheat genetic background. Interactions of five Gc genes so far identified were investigated by analysis of wheat hybrids among lines carrying different gametocidal genes. As a result, the genes were classified into three functional groups. The first group includes two Gc genes of Ae. speltoides (Gc1a and Gc1b) and one gene (Gc-Sl3) on chromosome 2S1 of Ae. sharonensis. These genes were hypostatic to the genes (Gc-Sl1, Gc-Sl2) on chromosome 4S1 of Ae. longissima and Ae. sharonensis, which constitute the second group. In addition, plants carrying Gc genes of both the first and the second group produced progeny with higher frequencies of chromosome breakage than those found in the progeny of single gene carriers. It was concluded that there were specific interactions between these genes to enhance chromosome breakage. On the other hand, there was no interaction between the Gc gene (Gc-C) of Ae. triuncialis, the third group, and Gc genes belonging to the former two groups. These functional groups might be a reflection of the mechanisms by which Gc genes induce gamete abortion and chromosome breakage. Based on functional and local relationships, the symbols of the Gc genes were systematically redesignated.