5′ Untranslated region of the Hsp12 gene contributes to efficient translation in Aspergillus oryzae

We describe a 5′ untranslated region (5′UTR) that dramatically increases the expression level of an exogenous gene in Aspergillus oryzae. Using a series of 5′UTR::GUS (uidA) fusion constructs, we analyzed the translation efficiency of chimeric mRNAs with different 5′UTRs at different temperatures. We found that the 5′UTR of a heat-shock protein gene, Hsp12, greatly enhanced the translation efficiency of the chimeric GUS mRNA at normal temperature (30°C). Moreover, at high temperature (37°C), the translation efficiency of the mRNA containing the Hsp12 5′UTR was far superior to that of mRNAs containing nonheat-shock 5′UTRs, resulting in much more efficient expression of GUS protein (about 20-fold higher GUS activity compared to the control construct). This 5′UTR can be used in combination with various strong promoters to enhance the expression of foreign proteins in A. oryzae.     

Analysis of heterologous regulatory and coding regions in algal chloroplasts

The basic photosynthetic apparatus is highly conserved across all photosynthetic organisms, and this conservation can be seen in both protein composition and amino acid sequence. Conservation of regulatory elements also seems possible in chloroplast genes, as many mRNA untranslated regions (UTRs) appear to have similar structural elements. The D1 protein of Photosystem II (psbA gene) is a highly conserved core reaction center protein that shows very similar regulation from cyanobacteria through higher plants. We engineered full and partial psbA genes from a diverse set of photosynthetic organisms into a psbA deficient strain of Chlamydomonas reinhardtii. Analysis of D1 protein accumulation and photosynthetic growth revealed that coding sequences and promoters are interchangeable even between anciently diverged species. On the other hand functional recognition of 5′ UTRs is limited to closely related organisms. Furthermore transformation of heterologous promoters and 5′ UTRs from the atpA, tufA and psbD genes conferred psbA mRNA accumulation but not translation. Overall, our results show that heterologous D1 proteins can be expressed and complement Photosystem II function in green algae, while RNA regulatory elements appear to be very specific and function only from closely related species. Nonetheless, there is great potential for the expression of heterologous photosynthetic coding sequences for studying and modifying photosynthesis in C. reinhardtii chloroplasts.     

Shine-Dalgarno-like sequences are not required for translation of chloroplast mRNAs in Chlamydomonas reinhardtii chloroplasts or in Escherichia coli

Initiation of translation in Escherichia coli and related eubacteria involves well-defined interactions between a conserved Shine-Dalgarno (SD) sequence immediately upstream of the initiation codon in the mRNA leader and an equally conserved anti-SD sequence at the 3′ end of the 16S rRNA. SD-like sequences found in the leaders of many, but not all, mRNAs from cyanobacteria and chloroplasts are hypervariable in location, size, and base composition compared to those in E. coli, while anti-SD sequences in the respective 16S rRNAs remain highly conserved. We have examined the function of the SD-like sequences found in the leaders of four chloroplast genes of the green alga Chlamydomonas reinhardtii using replacement mutagenesis to eliminate complementarity with the anti-SD sequences and insertion of canonical SD sequences (GGAGG) at positions −9 to −5 relative to the initiation codon. Promoter-leader regions of the atpB, atpE, rps4, and rps7 genes representing the diversity of chloroplast SD-like sequences were fused to aadA and uidA reporter genes encoding spectinomycin resistance and GUS activity respectively. Analysis of chloroplast transformants of C. reinhardtii and transformants of E. coli carrying the wild-type and mutant reporter constructs revealed that mutagenic replacement of the putative SD sequences had no effect on the expression of either the aadA or uidA reporter genes. Chloroplast transformants with the canonical SD sequence also showed no differences in reporter gene expression, whereas expression of the reporter genes was increased by 10 to 30% in the E. coli transformants. Collectively our results suggest that even though SD-dependent initiation predominates in E. coli, this bacterium also has the capacity to initiate translation by an SD-independent mechanism. In contrast, plant chloroplasts, and very probably their cyanobacterial ancestors, appear to have adopted the SD-independent mechanism for translational initiation of most mRNAs. Received: 8 July 1997 / Accepted: 9 September 1997     

The architecture of the chloroplast psbA-trnH non-coding region in angiosperms

The psbA-trnH intergenic region is among the most variable regions in the angiosperm chloroplast genome. It is a popular tool for plant population genetics and species level phylogenetics and has been proposed as suitable for DNA barcoding studies. This region contains two parts differing in their evolutionary conservation: 1) the psbA 3′UTR (untranslated region) and 2) the psbA-trnH intergenic non-transcribed spacer. We compared the sequence and RNA secondary structure of the psbA 3′ UTR across angiosperms and found consensus motifs corresponding to the stem portions of the RNA stem-loop structures and a consensus TTAGTGTATA box. The psbA-trnH spacer exhibited patterns that can be explained by the independent evolution of large inversions in the psbA 3′UTR and mutational hot spots in the remaining portion of the psbA-trnH spacer. We conclude that a comparison of chloroplast UTRs across angiosperms offer clues to the identity of putative regulatory elements and information about selective constraints imposed on the chloroplast non-coding regions.     

Chloroplast translation regulation

Chloroplast gene expression is primarily controlled during the translation of plastid mRNAs. Translation is regulated in response to a variety of biotic and abiotic factors, and requires a coordinate expression with the nuclear genome. The translational apparatus of chloroplasts is related to that of bacteria, but has adopted novel mechanisms in order to execute the specific roles that this organelle performs within a eukaryotic cell. Accordingly, plastid ribosomes contain a number of chloroplast-unique proteins and domains that may function in translational regulation. Chloroplast translation regulation involves cis-acting RNA elements (located in the mRNA 5′ UTR) as well as a set of corresponding trans-acting protein factors. While regulation of chloroplast translation is primarily controlled at the initiation steps through these RNA-protein interactions, elongation steps are also targets for modulating chloroplast gene expression. Translation of chloroplast mRNAs is regulated in response to light, and the molecular mechanisms underlying this response involve changes in the redox state of key elements related to the photosynthetic electron chain, fluctuations of the ADP/ATP ratio and the generation of a proton gradient. Photosynthetic complexes also experience assembly-related autoinhibition of translation to coordinate the expression of different subunits of the same complex. Finally, the localization of all these molecular events among the different chloroplast subcompartments appear to be a crucial component of the regulatory mechanisms of chloroplast gene expression.     

Cooperation between the chloroplast psbA 5′‐untranslated region and coding region is important for translational initiation: the chloroplast translation machinery cannot read a human viral gene coding region

Chloroplast mRNA translation is regulated by the 5′‐untranslated region (5′‐UTR). Chloroplast 5′‐UTRs also support translation of the coding regions of heterologous genes. Using an in vitro translation system from tobacco chloroplasts, we detected no translation from a human immunodeficiency virus tat coding region fused directly to the tobacco chloroplast psbA 5′‐UTR. This lack of apparent translation could have been due to rapid degradation of mRNA templates or synthesized protein products. Replacing the psbA 5′‐UTR with the E. coli phage T7 gene 10 5′‐UTR, a highly active 5′‐UTR, and substituting synonymous codons led to some translation of the tat coding region. The Tat protein thus synthesized was stable during translation reactions. No significant degradation of the added tat mRNAs was observed after translation reactions. These results excluded the above two possibilities and confirmed that the tat coding region prevented its own translation. The tat coding region was then fused to the psbA 5′‐UTR with a cognate 5′‐coding segment. Significant translation was detected from the tat coding region when fused after 10 or more codons. That is, translation could be initiated from the tat coding region once translation had started, indicating that the tat coding region inhibits translational initiation but not elongation. Hence, cooperation/compatibility between the 5′‐UTR and its coding region is important for translational initiation.     

Sequence characteristics and divergent evolution of the chloroplastpsbA-trnH noncoding region in gymnosperms

ThepsbA-trnH intergenic region is among the most variable regions in the gymnosperm chloroplast genome. It is proposed as suitable for DNA barcoding studies and is useful in phylogenetics at the species level. This region consists of two parts differing in their evolutionary characteristics: 1) thepsbA 3′UTR (untranslated region) and 2) thepsbA-trnH intergenic spacer. We compared the sequence and RNA secondary structure of thepsbA 3′ UTR across gymnosperms and found consensus motifs corresponding to the stem portions of the RNA stem-loop structures and a consensus TGGATTGTTATGT box. ThepsbA-trnH spacer is highly variable in length and composition. Tandem repeats that form stem—loop structures were detected in both thepsbA 3′ UTR and the psbA-trnH spacer. The presence of promoters and stem—loop structures in the psbA-trnH spacer and high sequence variation in this region suggest that psbA and trnH in some gymnosperms are independently transcribed. Acomparison of chloroplast UTRs across gymnosperms offer clues to the identity of putative regulatory elements and information on selective constraints imposed on the chloroplast non-coding regions. The present study should inspire researchers to explore the full potential of thepsbA-trnH non-coding sequence and to further stimulate its application in a broader spectrum of studies, not limited to phylogenetics and DNA barcoding.     

The sequence and secondary structure of the 3′-UTR affect 3′-end maturation,RNA accumulation,and translation in tobacco chloroplasts

RNA maturation and modulation of RNA stability play important roles in chloroplast gene expression. In vitro and in vivo studies have shown that both the 5- and 3-untranslated regions (UTRs) contain sequence and structural elements that guide these processes, and interact with specific proteins. We have previously characterized the spinach chloroplast petD 3-UTR in detail by in vitro approaches. This stem-loop forming sequence is a weak terminator but is required for RNA maturation and also exhibits sequence-specific protein binding. To test petD 3-UTR function in vivo, tobacco chloroplast transformants were generated containing uidA reporter genes flanked by variants of the petD 3-UTR, including one which does not form an RNA-protein complex in vitro, and one which lacks a stem-loop structure. Analysis of uidA mRNA indicated that a stable secondary structure is required to accumulate a discrete mRNA, and that changes in the 3-UTR sequence which affect protein binding in vitro can also affect RNA metabolism in vivo. The 3-UTR also influenced -glucuronidase protein accumulation, but not in proportion to RNA levels. These results raise the possibility that in tobacco chloroplasts, the 3-UTR may influence translational yield.     

Strong Expression and Conserved Regulation of <Emphasis Type="Italic">ACT2</Emphasis> in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> and <Emphasis Type="Italic">Physcomitrella patens</Emphasis>

Arabidopsis ACT2 represents an ancient class of vegetative plant actins and is strongly and constitutively expressed in almost all Arabidopsis sporophyte vegetative tissues. Using the beta glucuronidase report system, the studies showed that ACT2 5′ regulatory region was significantly more active than CaMV 35S promoter in Arabidopsis seedlings and gametophyte vegetative tissues of Physcomitrella patens. Its activity was also observed in rice and maize seedlings. Thus, the ACT2 5′ regulatory region could potentially serve as a strong regulator to express a transgene in divergent plant species. ACT2 5′ regulatory region contained 15 conserved sequence elements, an ancient intron in its 5′ un-translated region (5′ UTR), and a purine-rich stretch followed by a pyrimidine-rich stretch (PuPy). Mutagenesis and deletion analysis illustrated that some of the conserved sequence elements and the region containing PuPy sequences played regulatory roles in Arabidopsis. Interestingly, mutation of the conserved elements did not lead a dramatic change in the activity of ACT2 5′ regulatory region. The ancient intron in ACT2 5′ UTR was required for its strong expression in both Arabidopsis and P. patens, but did not fully function as a canonical intron. Thus, it was likely that some of the conserved sequence elements and gene structures had been preserved in ACT2 5′ regulatory region over the course of land plant evolution partly due to their functional importance. The studies provided additional evidences that identification of evolutionarily conserved features in non-coding region might be used as an efficient strategy to predict gene regulatory elements.     

Expression Enhancement of a Rice Polyubiquitin Gene Promoter

An 808 bp promoter from a rice polyubiquitin gene, rubi3, has been isolated. The rubi3 gene contained an open reading frame of 1140 bp encoding a pentameric polyubiquitin arranged as five tandem, head-to-tail repeats of 76 aa. The 1140 bp 5′ UTR intron of the gene enhanced its promoter activity in transient expression assays by 20-fold. Translational fusion of the GUS reporter gene to the coding sequence of the ubiquitin monomer enhanced GUS enzyme activity in transient expression assays by 4.3-fold over the construct containing the original rubi3 promoter (including the 5′ UTR intron) construct. The enhancing effect residing in the ubiquitin monomer coding sequence has been narrowed down to the first 9 nt coding for the first three amino acid residues of the ubiquitin protein. Mutagenesis at the third nucleotide of this 9 nt sequence still maintains the enhancing effect, but leads to translation of the native GUS protein rather than a fusion protein. The resultant 5′ regulatory sequence, consisting of the rubi3 promoter, 5′ UTR exon and intron, and the mutated first 9 nt coding sequence, has an activity nearly 90-fold greater than the rubi3 promoter only (without the 5′ UTR intron), and 2.2-fold greater than the maize Ubi1 gene promoter (including its 5′ UTR intron). The newly created expression vector is expected to enhance transgene expression in monocot plants. Considering the high conservation of the polyubiquitin gene structure in higher plants, the observed enhancement in gene expression may apply to 5′ regulatory sequences of other plant polyubiquitin genes.