In vivo uncoating and efficient expression of foreign mRNAs packaged in TMV-like particles.

The ribonucleocapsids of many plant viruses are extremely stable. The protein coat protects the RNA genome against degradation during the accumulation and spread of progeny virions. Chimeric single-stranded RNA molecules were transcribed in vitro from recombinant plasmids and later encapsidated, in vitro, into ribonucleoprotein particles (pseudoviruses) 60 nanometers long that resembled tobacco mosaic virus. Transcripts encoding an assayable enzyme, chloramphenicol acetyltransferase (CAT), were packaged into pseudovirus particles to assess the utility of this single-stranded RNA delivery system in a wide range of cell types. In all cases, packaged CAT messenger RNA was uncoated and transiently expressed. Significantly higher levels of CAT activity were detected with packaged than with naked CAT messenger RNA after inoculation of plant protoplasts in the presence of polyethylene glycol or abrasive inoculation of intact leaf surfaces. Structural events that lead to the uncoating and expression of CAT messenger RNA showed no cell specificity. This observation may support the view that the comparatively restricted host range of a true plant virus results from events that occur later during the infection cycle.

Translational efficiency is regulated by the length of the 3' untranslated region.

All polyadenylated mRNAs contain sequence of variable length between the coding region and the poly(A) tail. Little has been done to establish what role the length of the 3' untranslated region (3'UTR) plays in posttranscriptional regulation. Using firefly luciferase (luc) reporter mRNA in transiently transfected Chinese hamster ovary (CHO) cells, we observed that the addition of a poly(A) tail increased expression 97-fold when the length of the 3'UTR was 19 bases but that its stimulatory effect was only 2.3-fold when the length of the 3'UTR was increased to 156 bases. The effect of the luc 3'UTR on poly(A) tail function was orientation independent, suggesting that its length and not its primary sequence was the important factor. Increasing the length of the 3'UTR increased expression from poly(A)- mRNA but had little effect on poly(A)+ mRNA. To examine the effect of length on translational efficiency and mRNA stability, a 20-base sequence was introduced and reiterated downstream of the luc stop codon to generate a nested set of constructs in which the length of the 3'UTR increased from 4 to 104 bases. For poly(A)- reporter mRNA, translational efficiency in CHO cells increased 38-fold as the length of the 3'UTR increased from 4 to 104 bases. Increasing the length of the 3'UTR beyond 104 bases increased expression even further. Increasing the length of the 3'UTR also resulted in a 2.5-fold stabilization of the reporter mRNA. For poly(A)+ mRNA, the translational efficiency and mRNA half-life increased only marginally as the length of the 3'UTR increased from 27 to 161 bases. However, positioning the poly(A) tail only 7 bases downstream of the stop codon resulted in a 39-fold reduction in the rate of translation relative to a construct with a 27-base 3'UTR, which may be a consequence of the poly(A) tail-poly(A)-binding protein complex functioning as a steric block to translocating ribosomes as they approached the termination codon. The optimal length of the 3' noncoding region for maximal poly(A) tail-mediated stimulation of translation is approximately 27 bases. These data suggest that the length of the 3'UTR plays an important role in determining both the translational efficiency and the stability of an mRNA.

A phylogenetically conserved sequence within viral 3' untranslated RNA pseudoknots regulates translation.

Both the 68-base 5' leader (omega) and the 205-base 3' untranslated region (UTR) of tobacco mosaic virus (TMV) promote efficient translation. A 35-base region within omega is necessary and sufficient for the regulation. Within the 3' UTR, a 52-base region, composed of two RNA pseudoknots, is required for regulation. These pseudoknots are phylogenetically conserved among seven viruses from two different viral groups and one satellite virus. The pseudoknots contained significant conservation at the secondary and tertiary levels and at several positions at the primary sequence level. Mutational analysis of the sequences determined that the primary sequence in several conserved positions, particularly within the third pseudoknot, was essential for function. The higher-order structure of the pseudoknots was also required. Both the leader and the pseudoknot region were specifically recognized by, and competed for, the same proteins in extracts made from carrot cell suspension cells and wheat germ. Binding of the proteins is much stronger to omega than the pseudoknot region. Synergism was observed between the TMV 3' UTR and the cap and to a lesser extent between omega and the 3' UTR. The functional synergism and the protein binding data suggest that the cap, TMV 5' leader, and 3' UTR interact to establish an efficient level of translation.

Controlling gene expression in transgenics.

The repertoire of cis-regulatory elements has increased to a level of sophistication that offers considerable spatial and temporal control over transgene expression. Recent advances made with transgenes have revealed that the control of their expression is also influenced by factors that range from transgene copy number and arrangement to nuclear architecture and chromosomal location. These factors must now be included with the standard considerations of transcriptional and translational enhancers of gene expression during transgene design.

The role of 5'-leader length, secondary structure and PABP concentration on cap and poly(A) tail function during translation in Xenopus oocytes.

The 5'-cap structure and poly(A) tail of eukaryotic mRNAs function synergistically to promote translation initiation through a physical interaction between the proteins that bind to these regulatory elements. In this study, we have examined the effect of leader length and the presence of secondary structure on the translational competence and the function of the cap and poly(A) tail for mRNAs microinjected into Xenopus oocytes. Increasing the length of the 5'-leader from 17 to 144 nt resulted in a 2- to 4-fold increase in expression from an mRNA containing an unstructured leader but increased expression up to 20-fold for an mRNA containing 5'-proximal structure. Consequently, the presence of secondary structure was less inhibitory for those mRNAs with a longer 5'-leader. Co-injection of poly(A)-binding protein (PABP) mRNA increased the function of the cap and poly(A) tail in promoting translation from poly(A)(+) but not poly(A)(-) mRNAs, particularly for mRNAs containing secondary structure. In the absence of an internal ribosome entry site, expression from the distal cistron of a dicistronic mRNA increased as a function of the length of the intercistronic region and the concentration of PABP. The inhibitory effect of intercistronic located secondary structure on translation was position-dependent. Indeed, the effect of secondary structure was abolished if positioned 134 nt upstream of the distal cistron. These data suggest that the length of a leader, the presence of secondary structure and the concentration of PABP determine the extent to which the cap and poly(A) tail regulate translation.

Agrobacterium tumefaciens pTAR parA promoter region involved in autoregulation, incompatibility and plasmid partitioning.

The locus responsible for directing proper plasmid partitioning of Agrobacterium tumefaciens pTAR is contained within a 1259 base-pair region. Insertions or deletions within this locus can result in the loss of the plasmid's ability to partition properly. One protein product (parA), approximately 25,000 Mr, is expressed from the par locus in Escherichia coli and A. tumefaciens protein analysis systems in vitro. DNA sequence analysis of the locus revealed a single 23,500 Mr open reading frame, confirming the protein data. A 248 base-pair region immediately upstream from the 23,500 Mr open reading frame, containing an array of 12 seven-base-pair palindromic repeats each of which are separated by exactly ten base-pairs of A + T-rich (75%) sequence, not only serves to provide the promoter but is also involved in parA autoregulation. In addition, this region containing a set of 12 seven-base-pair palindromic repeats, is responsible for plasmid-associated incompatibility within Inc Ag-1 and also functions as the cis-acting recognition site at which parA interacts to bring about partitioning. Transcriptional analysis indicated that only the DNA strand responsible for parA is actively transcribed, and that active transcription of the opposite strand of par can inhibit the production of parA, resulting in plasmid destabilization. The presence of the par locus in a plasmid results in stable inheritance within a wide range of members of Rhizobiaceae. Segregation rates of par-defective derivatives can be influenced by the host.

RNase Activity Decreases following a Heat Shock in Wheat Leaves and Correlates with Its Posttranslational Modification.

Heat shock results in a coordinate loss of translational efficiency and an increase in mRNA stability in plants. The thermally mediated increase in mRNA half-life could be a result of decreased expression and/or regulation of intracellular RNase enzyme activity. We have examined the fate of both acidic and neutral RNases in wheat seedlings that were subjected to a thermal stress. We observed that the activity of all detectable RNases decreased following a heat shock, which was a function of both the temperature and length of the heat shock. In contrast, no reduction in nuclease activity was observed following any heat-shock treatment. Antibodies raised against one of the major RNases was used in western analysis to demonstrate that the RNase protein level did not decrease following a heat shock, and the data suggest that the observed decrease in RNase activity in heat-shocked leaves may be due to modification of the protein. Two-dimensional gel/western analysis of this RNase revealed three isoforms. The most acidic isoform predominated in control leaves, whereas the most basic isoform predominated in leaves following a heat shock and correlated with the heat-shock-induced reduction in RNase activity and increase in mRNA half-life. These data suggest that RNase activity may be regulated posttranslationally following heat shock as a means to reduce RNA turnover until recovery ensues.

Heat Shock Disrupts Cap and Poly(A) Tail Function during Translation and Increases mRNA Stability of Introduced Reporter mRNA.

The effect of heat shock on translational efficiency and message stability of a reporter mRNA was examined in carrot (Daucus carota). Heat shock of short duration resulted in an increase in protein yield, whereas repression was observed following extended exposure to the stress. Regardless of the duration of the heat shock, a loss in the function of the 5[prime] cap [m7G(5[prime])ppp(5[prime])N, where N represents any nucleotide] and the 3[prime] poly(A) tail, two regulatory elements that work in concert to establish an efficient level of translation, was observed. This apparent paradox was resolved upon examination of the mRNA half-life following thermal stress, in which increases up to 10-fold were observed. Message stability increased as a function of the severity of the heat shock so that following a mild to moderate stress the increase in message stability more than compensated for the reduction in cap and poly(A) tail function. Following a severe heat shock, the increased mRNA half-life was not sufficient to overcome the virtual loss in cap and poly(A) tail function. No stimulation of protein synthesis was observed following a heat shock in Chinese hamster ovary cells, data suggesting that the heat-induced increases in mRNA stability may be unique to the heat-shock response in plants.

Ethylene-Mediated Programmed Cell Death during Maize Endosperm Development of Wild-Type and shrunken2 Genotypes.

We characterized the progression of programmed cell death during maize (Zea mays L.) endosperm development of starchy (Su; wild-type) and shrunken2 (sh2) genotypes and tested the involve ment of ethylene in mediating this process. Histological and viability staining demonstrated that endosperm cell death was initiated earlier and progressed more rapidly in sh2 endosperm compared with Su endosperm. Internucleosomal DNA fragmentation accompanied endosperm cell death and occurred more extensively in sh2 endosperm. 1-Aminocyclopropane-1-carboxylic acid levels peaked approximately 16 d after pollination (dap) in Su endosperm and gradually decreased during subsequent development, whereas two large 1-aminocyclopropane-1-carboxylic acid peaks were observed in sh2 endosperm, the first between 16 and 20 dap and the second at 36 dap. Ethylene levels were elevated in sh2 kernels compared with Su kernels, with an initial peak 20 dap approximately 3-fold higher than in Su kernels and a second peak 36 dap approximately 5-fold higher than that in Su kernels. Ethylene treatment of Su kernels resulted in earlier and more extensive endosperm cell death and DNA fragmentation. Aminoethoxyvinylglycine treatment of sh2 kernels reduced the extent of DNA fragmentation. We conclude that ethylene is involved in triggering programmed cell death in developing maize endosperm and is responsible for the aberrant phenotype of sh2 kernels.

A tale of two termini: a functional interaction between the termini of an mRNA is a prerequisite for efficient translation initiation.

A quarter of century following the prediction that mRNAs are translated in a circular form, recent biochemical and genetic evidence has accumulated to support the idea that communication between the termini of an mRNA is necessary to promote translation initiation. The poly(A)-binding protein (PABP) interacts with the cap-associated eukaryotic initiation factor (eIF) 4G (in yeast and plants) and eIF4B (in plants), a functional consequence of which is to increase the affinity of PABP for poly(A) and to increase the affinity of the cap-binding complex, eIF4F (of which eIF4G is a subunit) for the 5' cap structure. In mammals, PABP interacts with a novel PABP-interacting protein that also binds eIF4A. The interaction between PABP and those initiation factors associated with the 5' terminus of an mRNA may also explain the role of PABP during mRNA turnover, as it protects the 5' cap from attack by Dcp1p, the decapping enzyme. Several of those mRNAs that have evolved functional equivalents to a cap or a poly(A) tail nevertheless require a functional interaction between terminal regulatory elements similar to that observed between the 5' cap and poly(A) tail, suggesting that efficient translation is predicated on communication between largely-separated regulatory elements within an mRNA.

The role of the 3'-untranslated region of non-polyadenylated plant viral mRNAs in regulating translational efficiency.

Tobacco mosaic virus (TMV) is a positive-sense RNA virus in which the single genomic RNA functions as a messenger RNA. It is a member of a class of plant viral RNAs that are the only known non-polyadenylated mRNAs in plants. The 3'-untranslated region (UTR) of TMV genomic RNA is the functional equivalent of a poly(A) tail in that it increases mRNA stability and regulates translational efficiency. To determine whether the 3'-UTR of other non-polyadenylated plant viral mRNAs regulate translation, those from turnip yellow mosaic (TYMV), brome mosaic (BMV), and alfalfa mosaic (AlMV) viruses were investigated. Chimeric gene constructs were made in which the viral 3'-UTRs were introduced immediately downstream from the reporter genes encoding beta-glucuronidase (GUS) and luciferase (LUC), and were translated in plant protoplasts following delivery of the mRNA using electroporation. The 3'-UTR from BMV RNA3 regulated reporter gene expression in vivo to an extent comparable to that observed for the TMV 3'-UTR. The BMV 3'-UTR increased both message stability and translational efficiency. As regulators of translation, the BMV and TMV 3'-UTR were dependent on the presence of a cap at the 5' terminus for function. The 3' UTR of TYMV or AlMV RNA4 had little impact on translation or transcript stability. These data suggest that although the TMV 3'-UTR is not unique in regulating translation, the 3'-UTR of plant viral mRNAs do vary in their regulatory ability.

The tobacco etch viral 5' leader and poly(A) tail are functionally synergistic regulators of translation.

The 5' cap (m7GpppN) and the poly(A) tail of eukaryotic mRNAs work in concert to establish an efficient level of translation in vivo. Nevertheless, several mRNAs naturally lack a cap or a poly(A) tail. Determining how these messages effectively compete for the translational machinery not only reveals alternative mechanisms for translational competence, but can also underscore similarities between alternative mechanisms and the standard cap/poly(A) tail interaction. The genomic RNA of tobacco etch virus (TEV), a potyvirus, is a polyadenylated mRNA that naturally lacks a cap (m7GpppN) at the 5'-terminus and yet is a highly competitive mRNA during translation. The 144-nt 5'-leader is largely responsible for directing efficient translation and can greatly increase the translational competence of reporter mRNAs. We have examined the synergy between the TEV 5'-leader and the poly(A) tail in transfected plant and animal cells. The TEV 5'-leader functioned optimally as a regulator of reporter mRNA translation only when a poly(A) tail was present. The effect of the TEV 5'-leader on the translation of capped transcripts was significantly less than that for uncapped mRNAs, suggesting that the TEV 5'-leader and the cap may promote similar steps in translation.

Characterisation of the 5'-leader sequence of tobacco mosaic virus RNA as a general enhancer of translation in vitro.

Uncapped messenger RNAs (mRNAs) encoding calf preprochymosin, chicken prelysozyme, or Escherichia coli beta-glucuronidase (GUS) were synthesized in vitro, with or without a 5'-terminal 67-nucleotide sequence (omega') derived from the untranslated 5'-leader (omega) of tobacco mosaic virus (TMV) RNA. Messenger RNAs were translated in vitro, in messenger-dependent systems derived from rabbit reticulocytes (MDL), wheat-germ (WG) or E. coli (EC). The omega' sequence enhanced expression of each mRNA in almost every translation system. While MDL was the least responsive to omega', this sequence proved particularly efficient in permitting translation of the eukaryotic mRNAs in EC, despite the absence of a consensus Shine-Dalgarno sequence in either the mRNAs or omega'. The local context of the initiation codon (AUG) in two GUS mRNA constructs did not influence the relative enhancement caused by the omega' sequence. These findings extend the utility of omega' as a general enhancer of translation for both prokaryotic and eukaryotic mRNAs in either 80S- or 70S-ribosome-based systems.

The effect of the length of the 3'-untranslated region on expression in plants.

The effect of increasing the length of the 3'-untranslated region (UTR) on expression of luciferase mRNA was examined in transiently transfected carrot protoplasts. The effect of the 3'-UTR on both poly(A)- and poly(A)+ mRNA was examined. A nested set of constructs in which the 3'-UTR increased from 4 to 104 bases was generated by the introduction and reiteration of a 20 base sequence downstream of the luc stop codon. For poly(A)- mRNA, there was a consistent increase in expression when the length of the 3'-UTR was increased from 4 to 104 bases. For poly(A)+ mRNA, expression increased 18-fold when the length of the 3'-UTR was increased from 7 to 27 bases. Further increases in the length of the 3'-UTR did not affect expression. The increase in expression was largely due to an increase in translational efficiency. These data suggest that the length of the 3'-UTR plays an important role in determining the extent to which a poly(A) tail can stimulate the translation of an mRNA.

Secondary structure in the 5'-leader or 3'-untranslated region reduces protein yield but does not affect the functional interaction between the 5'-cap and the poly(A) tail.

The 5'-cap structure and poly(A) tail of eukaryotic mRNAs cooperate to promote translation initiation but whether this functional interaction benefits certain classes of mRNAs has not been investigated. In this study, we investigate whether a structured 5'-leader or 3'-untranslated region (UTR) affects the cap/poly(A) tail interaction. A structured leader reduced the degree to which the 5'-cap promoted translation in plant cells and inhibited translation from capped and uncapped mRNAs equally in yeast. Secondary structure within the 3'-UTR reduced translational efficiency when adjacent to the stop codon but had little effect on the cap/poly(A) tail synergy. The functional interaction between the cap and poly(A) tail was as important for an mRNA with a structured leader or 3'-UTR as it was for an unstructured mRNA in either species, suggesting that these structures can reduce translation without affecting the functional interaction between the cap and poly(A) tail. However, the loss of Xrn1p, the major 5'-->3' exoribonuclease in yeast, abolished cap-dependent translation and the functional interaction between the cap and poly(A) tail, suggesting that the cap/poly(A) tail synergy is of particular importance under conditions of active RNA turnover.

Enhancing effect of the 3'-untranslated region of tobacco mosaic virus RNA on protein synthesis in vitro.

In order to test the enhancing effect of the 3'-terminal untranslated region (3'-UTR) of tobacco mosaic virus (TMV) RNA on protein synthesis in vitro we used a chimeric mRNA construct containing TMV 5'-UTR (omega) and firefly luciferase mRNA. The addition of the TMV 3'-UTR to the chimeric mRNA construct results in a more than 3-fold stimulation of the synthesis of the functionally active protein in the wheat germ cell-free translation system. We have demonstrated that the proper length of the TMV 3'-terminal part is important for efficient translation; elongation of the TMV tail by 160 vector-derived nucleotides fully abolishes the stimulation effect of the TMV 3'-UTR in vitro.

Arabidopsis thaliana Hsp100 proteins: kith and kin.

Arabidopsis thaliana, the first plant for which the entire genome sequence is available, was also among the first plant species from which Hsp100 proteins were characterized. The Athsp101 complementary DNA (cDNA) corresponds to the gene identification At1g74310 in the Arabidopsis genome sequence. Analysis of the genome revealed 7 additional proteins that are variably homologous with At1g74310 throughout the entire amino acid sequence and significant similarities or identities in the signature sequences conserved among Hsp100 proteins. Although AtHsp101 is cytoplasmic, 5 of the 7 related proteins have predicted plastidial localization signals. This complete description of the AtHsp100 family sets the stage for future research on expression and function.

The cap and poly(A) tail function synergistically to regulate mRNA translational efficiency.

The cap structure and the poly(A) tail are important regulatory determinants in establishing the translational efficiency of a messenger RNA. Although the mechanism by which either determinant functions remains poorly characterized, the interaction between the poly(A) tail-poly(A)-binding protein complex and events occurring at the 5' terminus during translation initiation has been an intriguing possibility. In this report, the mutual dependence of the cap and the poly(A) tail was studied. Poly(A)+ and poly(A)- luciferase (Luc) mRNAs generated in vitro containing or lacking a cap were translated in vivo in tobacco protoplasts, Chinese hamster ovary cells, and yeast following delivery by electroporation. The poly(A) tail-mediated regulation of translational efficiency was wholly dependent on the cap for function. Moreover, cap function was enhanced over an order of magnitude by the presence of a poly(A) tail. The relative differences in stability between the mRNAs could not account for the synergism. The synergism between the cap and poly(A) tail was not observed in yeast cells in which active translation had been disrupted. In addition, the synergism was not observed in in vitro translation lysates. These data demonstrate that the cap and the poly(A) tail are interdependent for optimal function in vivo and suggest that communication between the two regulatory determinants may be important in establishing efficient translation.