Importance of mRNA folding and start codon accessibility in the expression of genes in a ribosomal protein operon of Escherichia coli.

The trmD operon of Escherichia coli consists of the genes for the ribosomal protein (r-protein) S16, a 21 kilodalton protein (21K) of unknown function, the tRNA(m1G37)methyltransferase (TrmD), and r-protein L19, in that order. The synthesis of the 21K and TrmD proteins is 12 and 40-fold lower, respectively, than that of the two r-proteins, although the corresponding parts of the mRNA are equally abundant. This translational control of expression of at least the 21K protein gene (21K), is mediated by a negative control element located between codons 18 and 50 of 21K. Here, we present evidence for a model in which mRNA sequences up to around 100 nucleotides downstream from the start codon of 21K fold back and base-pair to the 21K translation initiation region, thereby decreasing the translation initiation frequency. Mutations in the internal negative control element of 21K that would prevent the formation of the proposed mRNA secondary structure over both the Shine-Dalgarno (SD) sequence and the start codon increased expression up to about 20-fold, whereas mutations that would disrupt the base-pairing with the SD-sequence had only relatively small effects on expression. In addition, the expression increased 12-fold when the stop codon of the preceding gene, rpsP, was moved next to the SD-sequence of 21K allowing the ribosomes to unfold the postulated mRNA secondary structure. The expression increased up to 150-fold when that stop codon change was combined with the internal negative control element base-substitutions that derepressed translation about 20-fold. The negative control element of 21K does not seem to be responsible for the low expression of the trmD gene located downstream. However, a similar negative control element native to trmD can explain at least partly the low expression of trmD. Possibly, the two mRNA secondary structures function to decouple translation of 21K and trmD from that of the respective upstream cistron in order to achieve their independent regulation.     

Codon usage and protein length-dependent feedback from translation elongation regulates translation initiation and elongation speed

Essential cellular functions require efficient production of many large proteins but synthesis of large proteins encounters many obstacles in cells. Translational control is mostly known to be regulated at the initiation step. Whether translation elongation process can feedback to regulate initiation efficiency is unclear. Codon usage bias, a universal feature of all genomes, plays an important role in determining gene expression levels. Here, we discovered that there is a conserved but codon usage-dependent genome-wide negative correlation between protein abundance and CDS length. The codon usage effects on protein expression and ribosome flux on mRNAs are influenced by CDS length; optimal codon usage preferentially promotes production of large proteins. Translation of mRNAs with long CDS and non-optimal codon usage preferentially induces phosphorylation of initiation factor eIF2α, which inhibits translation initiation efficiency. Deletion of the eIF2α kinase CPC-3 (GCN2 homolog) in Neurospora preferentially up-regulates large proteins encoded by non-optimal codons. Surprisingly, CPC-3 also inhibits translation elongation rate in a codon usage and CDS length-dependent manner, resulting in slow elongation rates for long CDS mRNAs. Together, these results revealed a codon usage and CDS length-dependent feedback mechanism from translation elongation to regulate both translation initiation and elongation kinetics.     

Influence of the codon following the AUG initiation codon on the expression of a modified lacZ gene in Escherichia coli.

In a lacZ expression vector (pMC1403Plac), all 64 codons were introduced immediately 3' from the AUG initiation codon. The expression of the second codon variants was measured by immunoprecipitation of the plasmid-coded fusion proteins. A 15-fold difference in expression was found among the codon variants. No distinct correlation could be made with the level of tRNA corresponding to the codons and large differences were observed between synonymous codons that use the same tRNA. Therefore the effect of the second codon is likely to be due to the influence of its composing nucleotides, presumably on the structure of the ribosomal binding site. An analysis of the known sequences of a large number of Escherichia coli genes shows that the use of codons in the second position deviates strongly from the overall codon usage in E. coli. It is proposed that codon selection at the second position is not based on requirements of the gene product (a protein) but is determined by factors governing gene regulation at the initiation step of translation.     

mRNA secondary structure at start AUG codon is a key limiting factor for human protein expression in Escherichia coli

Codon usage and thermodynamic optimization of the 5'-end of mRNA have been applied to improve the efficiency of human protein production in Escherichia coli. However, high level expression of human protein in E. coli is still a challenge that virtually depends upon each individual target genes. Using human interleukin 10 (huIL-10) and interferon alpha (huIFN-alpha) coding sequences, we systematically analyzed the influence of several major factors on expression of human protein in E. coli. The results from huIL-10 and reinforced by huIFN-alpha showed that exposing AUG initiator codon from base-paired structure within mRNA itself significantly improved the translation of target protein, which resulted in a 10-fold higher protein expression than the wild-type genes. It was also noted that translation process was not affected by the retained short-range stem-loop structure at Shine-Dalgarno (SD) sequences. On the other hand, codon-optimized constructs of huIL-10 showed unimproved levels of protein expression, on the contrary, led to a remarkable RNA degradation. Our study demonstrates that exposure of AUG initiator codon from long-range intra-strand secondary structure at 5'-end of mRNA may be used as a general strategy for human protein production in E. coli.     

Restructuring the translation initiation region of the human parathyroid hormone gene for improved expression in Escherichia coli

Overexpression of native human parathyroid hormone in Escherichia coli was achieved by a modification of the 5' end of the genomic gene sequence, thereby adapting this part of the translation initiation region to the bacterial host. Some simple rules abstracted from optimization studies of translation initiation of a beta-interferon gene were applied. These included (a) extending complementarity of the mRNA to the anticodon loop of tRNAfMet by use of a codon with a purine nucleotide directly following the ATG, (b) avoidance of stable secondary structure in the mRNA by use of synonymous A/U-rich codons, (c) elimination of a potential second Shine-Dalgarno sequence. The appropriate silent changes led to a 20-fold increase in parathyroid hormone production resulting in 4.3% of total soluble protein. This result proves the validity of our simple approach for optimization of foreign gene expression in E. coli.     

A molecular approach to optimize hIFN α2b expression and secretion in <Emphasis Type="Italic">Yarrowia lipolytica</Emphasis>

In this work, we investigated the effect of codon bias and consensus sequence (CACA) at the translation initiation site on the expression level of heterologous proteins in Yarrowia lipolytica; human interferon alpha 2b (hIFN-α2b) was studied as an example. A codon optimized hIFN-α2b gene was synthesized according to the frequency of codon usage in Y. lipolytica. Both wild-type (IFN-wt) and optimized hIFN-α2b (IFN-op) genes were expressed under the control of a strong inducible promoter acyl-co-enzyme A oxidase (POX2). Protein secretion was directed by the targeting sequence of the extracellular lipase (LIP2): pre–proLIP2. Codon optimization increased protein production by 11-fold, whereas the insertion of CACA sequence upstream of the initiation codon of IFN-op construct resulted in 16.5-fold increase of the expression level; this indicates that translational efficiency plays an important part in the increase of hIFN-α2b production level. The replacement of the pre–proLIP2 signal secretion with the LIP2 pre-region sequence followed by the X-Ala/X-Pro stretch but without the pro-region also increased the secretion of the target protein by twofold, suggesting therefore that the LIP2 pro-region is not necessary for extracellular secretion of small heterologous proteins in Yarrowia lipolytica.     

TISs-ST: a web server to evaluate polymorphic translation initiation sites and their reflections on the secretory targets

Background  

The nucleotide sequence flanking the translation initiation codon (start codon context) affects the translational efficiency of eukaryotic mRNAs, and may indicate the presence of an alternative translation initiation site (TIS) to produce proteins with different properties. Multi-targeting may reflect the translational variability of these other protein forms. In this paper we present a web server that performs computations to investigate the usage of alternative translation initiation sites for the synthesis of new protein variants that might have different functions.     

Optimization of the expression of equistatin in Pichia pastoris.

To improve the expression of equistatin, a proteinase inhibitor from the sea anemone Actinia equina, in the yeast Pichia pastoris, we prepared gene variants with yeast-preferred codon usage and lower repetitive AT and GC content. The full gene optimization approximately doubled the level of steady-state mRNA and protein accumulated in the culture medium. The removal of a short stretch of 12 additional nucleotides from the multiple cloning site (MCS) sequence in the vector pPIC9 had an enhancement effect similar to full gene optimization (factor 1.5) at the mRNA level. However, at the protein level, this increase was 4- to 10-fold. The optimized gene without the MCS sequence yielded 1.66 g/L active protein in a bioreactor and was purified by a new two-step procedure with a recovery of activity that was >95%. This production level constitutes an overall improvement of about 20-fold relative to our previously published results. The characteristics of the MCS sequence element are discussed in the light of its apparent ability to act as negative expression regulator.     

High-temperature cultivation and 5' mRNA optimization are key factors for the efficient overexpression of thermostable Deinococcus geothermalis purine nucleoside phosphorylase in Escherichia coli

Overexpression of genes from thermophiles in Escherichia coli is an attractive approach towards the large-scale production of thermostable biocatalysts. However, various factors can challenge efficient heterologous protein expression--one example is the formation of stable 5' mRNA secondary structures that can impede an efficient translation initiation. In this work, we describe the expression optimization of purine nucleoside phosphorylase from the thermophilic microbe Deinococcus geothermalis in E. coli. Poor expression levels caused by stable secondary 5' mRNA structure formation were addressed by two different approaches: (i) increasing the cultivation temperature above the range used typically for recombinant protein expression and (ii) optimizing the 5' mRNA sequence for reduced secondary structures in the translation initiation region. The increase of the cultivation temperature from 30°C to 42°C allowed a more than 10-fold increase of activity per cell and optimizing the 5' mRNA gene sequence further increased the activity per cell 1.7-fold at 42°C. Thus, the combination of high-temperature cultivation and 5' sequence optimization is described as an effective approach to overcome poor expression levels resulting from stable secondary 5' mRNA structure formation. We suggest that this method is especially suitable for improving the expression of proteins derived from thermophiles in E. coli.     

Translation elongation can control translation initiation on eukaryotic mRNAs

Synonymous codons encode the same amino acid, but differ in other biophysical properties. The evolutionary selection of codons whose properties are optimal for a cell generates the phenomenon of codon bias. Although recent studies have shown strong effects of codon usage changes on protein expression levels and cellular physiology, no translational control mechanism is known that links codon usage to protein expression levels. Here, we demonstrate a novel translational control mechanism that responds to the speed of ribosome movement immediately after the start codon. High initiation rates are only possible if start codons are liberated sufficiently fast, thus accounting for the observation that fast codons are overrepresented in highly expressed proteins. In contrast, slow codons lead to slow liberation of the start codon by initiating ribosomes, thereby interfering with efficient translation initiation. Codon usage thus evolved as a means to optimise translation on individual mRNAs, as well as global optimisation of ribosome availability.     

同义密码子通过精微翻译选择机制实现对基因的表达调控

自然界中,同义密码子的存在使得众多氨基酸能够同时被多种密码子编码合成。随着研究的深入,同义密码子使用偏嗜性发挥出的生物学功能已经渗透到了基因复制、转录、翻译以及化学修饰等生命活动过程中。基于同义密码子使用偏嗜性的生物学特性,陆续发现密码子对(codon pair)和密码子共现(codon co-occurrence)同样在使用模式上存在明显的偏嗜性。在基因表达的过程中,针对编码序列的密码子优化能够显著提升基因的表达水平,这在生物工程领域对于蛋白表达有着重要的生物学意义。此外,同义密码子使用模式在调控基因转录、化学修饰以及翻译过程中间接控制着细胞内生命活动的有序性。而这些与同义密码子使用模式有着千丝万缕联系的生命过程主要是受精微翻译选择压力来调控运行的。本文中,我们结合当前同义密码子使用模式介导的精微翻译选择压力,简述密码子使用模式如何从转录、化学修饰以及翻译等方面来影响基因表达及蛋白产物生物学功能。这将为今后生物工程学领域如何优化蛋白高效表达以及深入研究重要生物学活动中基因表达调控提供可参考的思路与理念。     

Codon usage-mediated inhibition of HIV-1 gag expression in mammalian cells occurs independently of translation

Codon usage is considered one of the critical factors that limit the expression rate of heterologous genes. Impaired translation efficiency, specifically insufficient amount of corresponding tRNAs and changed startcodon context, are believed to account for the low translation initiation and elongation rates during the protein biosynthesis in unicellular organisms. Translational efficiency is probably not the primary factor influencing codon usage diversity in mammalian cells. However, the other possible mechanisms preventing expression of genes with low-usage such as mRNA stability, processing and nucleocytoplasmic transport, are not adequately explored. In our work, we addressed the question of whether codon usage differences affect exclusively translational efficiency of mammalian gene products. We demonstrated that the CMV-induced expression of gag-reporter in human H1299 cell line was influenced by the nucleotide composition of the mRNA, and the limitation of gag expression appeared to be inversely related to the level of codon optimization. However, cytoplasmic expression of the gag-reporter driven by vaccinia virus/T7 RNA polymerase hybrid system rescued its expression independently of HIV-1 gag mRNA nucleotide content. We concluded that impaired HIV-1 gag expression may be caused by translation-independent mechanisms, which probably play a major role in codon usage-mediated defects in heterologous gene expression in mammalian cells.     

Two rat surfactant protein A isoforms arise by a novel mechanism that includes alternative translation initiation

A single gene for rat surfactant protein A (SP-A) encodes two isoforms that are distinguished by an isoleucine-lysine-cysteine (IKC) N-terminal extension (SP-A and IKC-SP-A). Available evidence suggests that the variants are generated by alternative signal peptidase cleavage of the nascent polypeptide at a primary site (Cys(-)(1)-Asn(1)) and a secondary site (Gly(-)(4)-Ile(-)(3)). In this study, we used site-directed mutagenesis and heterologous expression in vitro and in insect cells to the examine mechanisms that may lead to alternative signal peptidase cleavage including alternative translation initiation at two in-frame AUGs (Met(-)(30) and Met(-)(20)), a suboptimal context for hydrolysis at the primary cleavage site, or cotranslational protein modifications that expose an otherwise cryptic secondary cleavage site. In vitro translation of a rat cDNA for SP-A resulted in both 28 and 29 kDa primary translation products on SDS-PAGE analysis, while translation of cDNAs encoding Met-30Ala and Met-20Ala mutations resulted in only the single 28 and 29 kDa molecular mass species, respectively. These data are consistent with translation initiation at both Met(-)(30) and Met(-)(20) during in vitro synthesis of SP-A. The Met-30Ala mutation reduced expression of the longer isoform in insect cells, indicating that the Met(-)(30) site also contributes to eucaryotic protein expression. Forcing translation initiation at Met(-)(30) by optimizing the Kozak consensus sequence surrounding that codon or by mutating the Met(-)(20) codon resulted in preferential expression of the longer SP-A isoform but reduced overall expression of the protein almost 10-fold. Both isoforms were generated to some degree whether translation was initiated at the codon for Met(-)(30) or Met(-)(20), indicating that the site of translation initiation is not the sole determinant of isoform generation and suggesting that either the context of the primary cleavage site is suboptimal or that cotranslational modifications affect cleavage. Preventing N-terminal glycosylation at Asn(1) did not affect the site of signal peptidase cleavage. Disruption of interchain disulfide formation at Cys(-)(1) by substitution with serine markedly enhanced cleavage at the Gly(-)(4)-Ile(-)(3) bond, but substitution with alanine enhanced cleavage at the Cys(-)(1)-Asn(1) bond. We conclude that rat SP-A isoforms arise by a novel mechanism that includes both alternative translation initiation at two in-frame AUGs and a suboptimal context for signal peptidase hydrolysis at the primary cleavage site.     

Enhancing the recombinant protein expression of halohydrin dehalogenase HheA in Escherichia coli by applying a codon optimization strategy

Halohydrin dehalogenases are attractive biocatalysts in producing a series of important chiral building blocks. Recombinant expression of halohydrin dehalogenase from Arthrobacter sp. AD2 (HheA) in Escherichia coli using T7 promoter-based pGEF(+) system revealed much lower expression level than that of the well-studied halohydrin dehalogenase from Agrobacterium radiobacter AD1 (HheC). In this study, we changed the codon usage in the 5′-end of hheA gene to improve the expression yield of HheA. Our results showed that the expression of HheA could be largely improved by the replacement of G-rich +2 codon (adjacent to the start codon) with less G-containing codons. The expression of one of the resulting mutants HheA-D1 (replaced +2 codon GTG with CCA) was about 4-fold higher and purified yields about 8-fold greater than that of the wild-type HheA. Moreover, the expression level of the resulting HheA variants correlated well with the minimal folding free energy (ΔG) of the mRNA secondary structure surrounding the 5′-end region of the genes. These findings suggested that the G-rich +2 codon of hheA gene might be the main suppressive factor for limiting the recombinant expression of HheA and that +2 codon optimization strategy could be used as a general tool in modulating recombinant protein production in E. coli.     

Heterologous protein expression is enhanced by harmonizing the codon usage frequencies of the target gene with those of the expression host

Synonymous codon replacement can change protein structure and function, indicating that protein structure depends on DNA sequence. During heterologous protein expression, low expression or formation of insoluble aggregates may be attributable to differences in synonymous codon usage between expression and natural hosts. This discordance may be particularly important during translation of the domain boundaries (link/end segments) that separate elements of higher ordered structure. Within such regions, ribosomal progression slows as the ribosome encounters clusters of infrequently used codons that preferentially encode a subset of amino acids. To replicate the modulation of such localized translation rates during heterologous expression, we used known relationships between codon usage frequencies and secondary protein structure to develop an algorithm ("codon harmonization") for identifying regions of slowly translated mRNA that are putatively associated with link/end segments. It then recommends synonymous replacement codons having usage frequencies in the heterologous expression host that are less than or equal to the usage frequencies of native codons in the native expression host. For protein regions other than these putative link/end segments, it recommends synonymous substitutions with codons having usage frequencies matched as nearly as possible to the native expression system. Previous application of this algorithm facilitated E. coli expression, manufacture and testing of two Plasmodium falciparum vaccine candidates. Here we describe the algorithm in detail and apply it to E. coli expression of three additional P. falciparum proteins. Expression of the "recoded" genes exceeded that of the native genes by 4- to 1,000-fold, representing levels suitable for vaccine manufacture. The proteins were soluble and reacted with a variety of functional conformation-specific mAbs suggesting that they were folded properly and had assumed native conformation. Codon harmonization may further provide a general strategy for improving the expression of soluble functional proteins during heterologous expression in hosts other than E. coli.     

Fine-Tuning Translation Kinetics Selection as the Driving Force of Codon Usage Bias in the Hepatitis A Virus Capsid

Hepatitis A virus (HAV), the prototype of genus Hepatovirus, has several unique biological characteristics that distinguish it from other members of the Picornaviridae family. Among these, the need for an intact eIF4G factor for the initiation of translation results in an inability to shut down host protein synthesis by a mechanism similar to that of other picornaviruses. Consequently, HAV must inefficiently compete for the cellular translational machinery and this may explain its poor growth in cell culture. In this context of virus/cell competition, HAV has strategically adopted a naturally highly deoptimized codon usage with respect to that of its cellular host. With the aim to optimize its codon usage the virus was adapted to propagate in cells with impaired protein synthesis, in order to make tRNA pools more available for the virus. A significant loss of fitness was the immediate response to the adaptation process that was, however, later on recovered and more associated to a re-deoptimization rather than to an optimization of the codon usage specifically in the capsid coding region. These results exclude translation selection and instead suggest fine-tuning translation kinetics selection as the underlying mechanism of the codon usage bias in this specific genome region. Additionally, the results provide clear evidence of the Red Queen dynamics of evolution since the virus has very much evolved to re-adapt its codon usage to the environmental cellular changing conditions in order to recover the original fitness.