Heterologous Protein Expression Levels Research Articles

High-throughput droplet microfluidics screening and genome sequencing analysis for improved amylase-producing Aspergillus oryzae

BackgroundThe exceptional protein secretion capacity, intricate post-translational modification processes, and inherent safety features of A. oryzae make it a promising expression system. However, heterologous protein expression levels of existing A. oryzae species cannot meet the requirement for industrial-scale production. Therefore, establishing an efficient screening technology is significant for the development of the A. oryzae expression system.ResultsIn this work, a high-throughput screening method suitable for A. oryzae has been established by combining the microfluidic system and flow cytometry. Its screening efficiency can reach 350 droplets per minute. The diameter of the microdroplet was enlarged to 290 µm to adapt to the polar growth of A. oryzae hyphae. Through enrichment and screening from approximately 450,000 droplets within 2 weeks, a high-producing strain with α-amylase increased by 6.6 times was successfully obtained. Furthermore, 29 mutated genes were identified by genome resequencing of high-yield strains, with 15 genes subjected to editing and validation. Two genes may individually influence α-amylase expression in A. oryzae by affecting membrane-associated multicellular processes and regulating the transcription of related genes.ConclusionsThe developed high-throughput screening strategy provides a reference for other filamentous fungi and Streptomyces. Besides, the strains with different excellent characteristics obtained by efficient screening can also provide materials for the analysis of genetic and regulatory mechanisms in the A. oryzae expression system.

Development of a “deconstructed” vector based on the genome of grapevine virus A

The development of new vectors based on plant viruses creates more efficient vectors driving high expression levels of heterologous proteins. Currently, deconstructed vectors are more suitable for the expression of target genes. We attempted to develop a deconstructed vector based on the genome of grapevine virus A (GVA) by replacing the coat protein gene of GVA to the coat protein gene (aCP) of ACLSV (apple chlorotic leaf spot virus). This is the first work on creation of deconstructed vector based on GVA genome. The heterologous gene was placed under the control of the CP subgenomic promoter of GVA and fused with ORF5. The 2A self-cleaving sequence was inserted between the target protein and the protein encoded by ORF5 to enable the expression of separate proteins. The transient expression of coat protein of ACLSV from this vector was assessed in both transgenic plants carrying the CP of GVA and in non-transgenic plants. The level of aCP expression in transgenic plants was higher than the expression level in non-transgenic plants. Transgenic plants were developed in this study to increase target protein yield, because GVA cannot move between cells in its non-encapsidated form. The developed vector based on the grapevine virus A genome can be used in transient expression of different heterologous proteins utilizing magnifection method or via co-agroinfiltration with native genome of GVA.

Synthetic microbiome: When “synthetic biology” meets “microbiomics”

Microbiomics focuses on the composition and function of microbial communities in a specific environment, while synthetic biology is an emerging discipline that uses engineering principles to elucidate, simulate and construct biological systems. The interdisciplinary branch of these disciplines has developed into an emerging subject called synthetic microbiomics, which has become a topic of interest in the field of microbiology. Distinct from the traditional functional microbiome, the synthetic microbiome refers to the functional microbiota constructed under the guidance of synthetic biology instead of the natural microbiota. The construction of a synthetic microbiome involves several steps, including model design, strain engineering, evaluation and optimization. Characterized by the modularization of metabolic pathways, the synthetic microbiome actualizes the cooperation of multiple strains with different functions. The synthetic microbiome has several advantages over monoculture in the case of synthesizing complex macromolecules and other platform chemicals. First, the metabolic burden of each strain is reduced as well as the difficulty of plasmid construction. Second, varied expression platforms are provided for multiple modules to increase the expression level of heterologous proteins. Third, modules could be easily added or substituted to obtain diverse products, and the relative metabolic intensity of each module is controlled through the inoculation ratio of co-cultured strains. Meanwhile, different parts of metabolic pathways are insulated by cell membrane, reducing the yield of by-products. Finally, mixed substrates, such as lignocellulose hydrolysates, can be efficiently utilized by multiple strains, which cannot be used by a single strain due to substrate preference. Research on the synthetic microbiome has increased in recent years, yet most of these findings have not been applied in industry. The applications of the synthetic microbiome are normally concentrated on the production of three categories of products: platform compounds, complex macromolecules and biofuels. Other applications, such as bioelectrochemical systems and light-driven consortia, offer new energy resources and have significance in fundamental research on the symbiotic relationship of co-cultured strains. In many cases, the yield has remarkably improved thanks to the decrease of metabolic burdens caused by the division of labour. However, the stability and robustness of synthetic microbiomes remain as challenges. To improve stability, two design strategies could be taken into consideration: The quorum sensing system and the cross-feeding system. Improvements in genetic engineering and substrate utilization will enhance robustness. With the development of synthetic biology, more genetic editing and regulation tools will come into use, providing the possibility to construct stable and robust synthetic microbiomes comprising more strains. Once stability and robustness are attained, synthetic microbiome applications will likely spread throughout industry.

Techniques for chromosomal integration and expression optimization in Escherichia coli.

Due to the inherent expression stability and low metabolic burden to the host cell, the expression of heterologous proteins in the bacterial chromosome in a precise and efficient manner is highly desirable for metabolic engineering and live bacterial applications. However, obtaining suitable chromosome expression levels is particularly challenging. In this minireview, we briefly present the technologies available for the integration of heterologous genes into Escherichia coli chromosomes and strategies to optimize the expression levels of heterologous proteins.

Rapid monitoring of the target protein expression with a fluorescent signal based on a dicistronic construct in Escherichia coli

Real-time quantification of recombinant proteins is important in studies on fermentation engineering, cell engineering, etc. Measurement of the expression level of heterologous proteins in bacterial fermentation broth has traditionally relied on time-consuming and labor-intensive procedures, such as polyacrylamide gel electrophoresis, immunoblot analysis, and biological activity assays. We describe a simple, fast, and high sensitive assay for detecting heterologous proteins production in bacteria either at the overall level (fluorescence spectrophotometry) or at the individual level (fluorescence microscopic image) in this study. Based on a dicistronic model, the translation of target gene in the upstream open reading frame (ORF) was coupled with the synthesis of the mCherry reporter in the downstream ORF in E. coli cells, and subsequently this demonstrated a positive correlation between the expression of target gene and mCherry. Although a time lag exists between the expression of target protein and mCherry reporter, the method described here allows facile monitoring of dynamic changes in target protein expression, relying on indirect determination of the fluorescence intensity of mCherry during fermentation in real-time models. Additionally, the performance of a single bacterial cell factory could be checked under the fluorescence microscope field.

An Artificial Design Technique to Optimize Signal Peptide

To determine optimal artificial signal peptide candidates for the possibility of creating high levels of secretion of heterologous proteins, substitution and redesign of amino acid sequences in the H-domain of the signal peptide was theoretically attempted. The method was based on comprehensive score matrix and Markov transfer matrix, which can make the artificial sequences maintain the structural characteristics and original polarity of signal peptides. For the artificial sequence, the feature vector of Structural Fusion Degree (SFD) is first extracted to quantitatively describe the compatibility of artificial cleaved region, then by comparing with highly secreted natural samples; tendencies of specific substitutions in the amino acid sequence can be identified at certain locations. These substitutions may represent the key amino acids that influence the secretion and expression levels of heterologous proteins.

Quantitative relationship between the mRNA secondary structure of translational initiation region and the expression level of heterologous protein in Escherichia coli.

Translational efficiency in Escherichia coli is strongly influenced by mRNA secondary structure of translational initiation region (TIR). We have previously reported that the expression of heterologous protein is directly related to the minimal folding free energy (ΔG) of the local secondary structure. However, identifying biologically relevant maximum and minimum levels of expression, or exploring the optimal level between them, is a key to successful optimization of heterologous protein expression. To systematically search a large range of the ΔG of TIR, we now present a quantitative analysis of the relationship between expression level and these ΔGs. The ΔG of TIR in green fluorescent protein is found to be linearly correlated with the fluorescence intensity over a range of tenfold change. The result demonstrates that the increasing ΔG of TIR can enhance the expression level linearly with no threshold or plateau.

Overexpression of pucC improves the heterologous protein expression level in a Rhodobacter sphaeroides expression system.

The Rhodobacter sphaeroides system has been used to express membrane proteins. However, its low yield has substantially limited its application. In order to promote the protein expression capability of this system, the pucC gene, which plays a crucial role in assembling the R. sphaeroides light-harvesting 2 complex (LH2), was overexpressed. To build a pucC overexpression strain, a pucC overexpression vector was constructed and transformed into R. sphaeroides CQU68. The overexpression efficiency was evaluated by quantitative real-time polymerase chain reaction. A well-used reporter β-glucuronidase (GUS) was fusion-expressed with LH2 to evaluate the heterologous protein expression level. As a result, the cell culture and protein in the pucC overexpression strain showed much higher typical spectral absorption peaks at 800 and 850 nm compared with the non-overexpression strain, suggesting a higher expression level of LH2-GUS fusion protein in the pucC overexpression strain. This result was further confirmed by Western blot, which also showed a much higher level of heterologous protein expression in the pucC overexpression strain. We further compared GUS activity in pucC overexpression and non-overexpression strains, the results of which showed that GUS activity in the pucC overexpression strain was approximately ten-fold that in the non-overexpression strain. These results demonstrate that overexpressed pucC can promote heterologous protein expression levels in R. sphaeroides.

An alternative method of enhancing the expression level of heterologous protein in Escherichia coli

Though numerous strategy options are available for achieving high expression levels of genes in Escherichia coli, not every gene can be efficiently expressed in this organism. By investigating the relationship between the mRNA secondary structure of translational initiation region (TIR) and gene expression in E.coli, we establish a simple method to design sequences of appropriate TIR (from −35 to +36) that meet a specific expression level as we need. Using this method, overexpression of native human humor necrosis factor α and extracellular domain of Her2/neu protein (aa 23–146) in E. coli were achieved. Differences in expression appeared was mainly related to the efficiency of translation initiation and the stability of mRNA secondary structure, because the intracellular mRNA levels analyzed by real-time RT-PCR were quite similar. Our approach can overcome the steric hindrance of translation startup, and therefore promote translation smoothly to acquire high expression of exogenous protein.

Overexpression and self-assembly of virus-like particles in Nicotiana benthamiana by a single-vector DNA replicon system.

Based on recent developments, virus-like particles (VLPs) are considered to be perfect candidates as nanoplatforms for applications in materials science and medicine. To succeed, mass production of VLPs and self-assembly into a correct form in plant systems are key factors. Here, we report expression of synthesized coat proteins of the three viruses, Brome mosaic virus, Cucumber mosaic virus, and Maize rayado fino virus, in Nicotiana benthamiana and production of self-assembled VLPs by transient expression system using agroinfiltration. Each coat protein was synthesized and cloned into a pBYR2fp single replicon vector. Target protein expression in cells containing p19 was fourfold higher than that of cells lacking p19. After agroinfiltration, protein expression was analyzed by SDS-PAGE and quantitative image analyzer. Quantitative analysis showed that BMVCP, CMVCP, and MRFVCP concentrations were 0.5, 1.0, and 0.8 mg · g(-1) leaf fresh weight, respectively. VLPs were purified by sucrose cushion ultracentrifugation and then analyzed by transmission electron microscopy. Our results suggested that BMVCP and CMVCP proteins expressed in N. benthamiana leaves were able to correctly self-assemble into particles. Moreover, we evaluated internal cavity accessibility of VLPs to load foreign molecules. Finally, plant growth conditions after agroinfiltration are critical for increasing heterologous protein expression levels in a transient expression system.

Prediction of soluble heterologous protein expression levels inEscherichia colifrom sequence-based features and its potential in biopharmaceutical process development

Prediction of soluble protein expression levels in Escherichia coli based on the nature of protein itself remains a challenge for bioprocess development (BD). This review will critically discuss the current efforts and achievements that employ computational approaches to develop prediction models for soluble protein expression in E. coli. The contrast between the remarkable progresses made on the predictive models achieved by bioinformatics and their relatively infrequent application in BD will be explained. The effects of process-relevant variables at four different levels on the expression of heterologous proteins, for example, gene, vector, host cell and cultivation process, and also a critical comparison of several established bioinformatics tools for predicting expression levels will be presented. The potential utility of this emergent technology to increase the efficiency of BD strategies and thereby to reduce the cost of establishing a process for soluble protein expression are critically examined.

Introduction of silent mutations in a codon-optimized xylanase (xynB) results in enhanced protein expression in HEK293A cells

Xylanase is used extensively to improve feed conversion rates to enhance the performance of poultry and pigs. By expressing xylanase in simple-stomached animals, new breeds of genetically modified animals with enhanced feed conversion rates may be obtained. However, expression of heterologous proteins derived from lower organisms in mammalian cells is usually inefficient. When common codons of a ''one amino acid-one codon"-optimized xylanase from Streptomyces olivaceoviridis were replaced with rare codons, xylanase expression in human embryonic kidney 293A cells increased by 1.4- to 2.3-fold as determined by flow cytometry, western blot and enzymatic activity assay. Quantitative RT-PCR assay indicated that the enhanced expression could not be attributed to altered mRNA levels. This study provides an alternative strategy for improving expression levels of heterologous proteins in mammalian cells, which is potentially helpful for generating genetically modified animals with enhanced feed conversion ability.

Secretion and assembly of functional mini-cellulosomes from synthetic chromosomal operons in Clostridium acetobutylicum ATCC 824

BackgroundConsolidated bioprocessing (CBP) is reliant on the simultaneous enzyme production, saccharification of biomass, and fermentation of released sugars into valuable products such as butanol. Clostridial species that produce butanol are, however, unable to grow on crystalline cellulose. In contrast, those saccharolytic species that produce predominantly ethanol, such as Clostridium thermocellum and Clostridium cellulolyticum, degrade crystalline cellulose with high efficiency due to their possession of a multienzyme complex termed the cellulosome. This has led to studies directed at endowing butanol-producing species with the genetic potential to produce a cellulosome, albeit by localising the necessary transgenes to unstable autonomous plasmids. Here we have explored the potential of our previously described Allele-Coupled Exchange (ACE) technology for creating strains of the butanol producing species Clostridium acetobutylicum in which the genes encoding the various cellulosome components are stably integrated into the genome.ResultsWe used BioBrick2 (BB2) standardised parts to assemble a range of synthetic genes encoding C. thermocellum cellulosomal scaffoldin proteins (CipA variants) and glycoside hydrolases (GHs, Cel8A, Cel9B, Cel48S and Cel9K) as well as synthetic cellulosomal operons that direct the synthesis of Cel8A, Cel9B and a truncated form of CipA. All synthetic genes and operons were integrated into the C. acetobutylicum genome using the recently developed ACE technology. Heterologous protein expression levels and mini-cellulosome self-assembly were assayed by western blot and native PAGE analysis.ConclusionsWe demonstrate the successful expression, secretion and self-assembly of cellulosomal subunits by the recombinant C. acetobutylicum strains, providing a platform for the construction of novel cellulosomes.

Effects of rare codons on expression levels of heterologous proteins in genetic engineered Escherichia coli

Effects of rare codons on expression levels of heterologous proteins in genetic engineered Escherichia coli

A Novel Rhodobacter sphaeroides Expression System for Real-Time Evaluation of Heterologous Protein Expression Levels

Heterologous protein expression levels can not be evaluated in real-time by experimental procedures commonly used for most expression systems during host cell culture. Rb. sphaeroides has provided an ideal system for studying both photosynthesis and membrane development and exhibited potential as a novel expression system. We constructed the puc1BA and puc2BA mutant strain Rb. sphaeroides CQU68 and used it as a novel expression system to heterologously express proteins fused to β-subunit of light-harvesting 2 complexes (LH2). The presence of LH2 with β-subunit fusion proteins was spectrally detected by the LH2 typical absorption at ~800 nm and ~850 nm, and the formation of these complexes were further confirmed by SDS-PAGE and Western blot analysis. The expression levels of heterologous protein measured by SDS-PAGE and Western blot turned out to be higher as the typical spectral peak heights increase. These findings suggested that the production of the heterologous protein could be rapidly detected through the LH2 absorption at ~800 nm and ~850 nm. Moreover, the typical absorption could be used as a monitor for rapid and real-time evaluation of heterologous protein expression levels.

A molecular approach to optimize hIFN α2b expression and secretion in Yarrowia lipolytica

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.

The HAC1 gene from Pichia pastoris: characterization and effect of its overexpression on the production of secreted, surface displayed and membrane proteins

BackgroundThe unfolded protein response (UPR) in eukaryotes upregulates factors that restore ER homeostasis upon protein folding stress and in yeast is activated by a non-conventional splicing of the HAC1 mRNA. The spliced HAC1 mRNA encodes an active transcription factor that binds to UPR-responsive elements in the promoter of UPR target genes. Overexpression of the HAC1 gene of S. cerevisiae can reportedly lead to increased production of heterologous proteins. To further such studies in the biotechnology favored yeast Pichia pastoris, we cloned and characterized the P. pastoris HAC1 gene and the splice event.ResultsWe identified the HAC1 homologue of P. pastoris and its splice sites. Surprisingly, we could not find evidence for the non-spliced HAC1 mRNA when P. pastoris was cultivated in a standard growth medium without any endoplasmic reticulum stress inducers, indicating that the UPR is constitutively active to some extent in this organism. After identification of the sequence encoding active Hac1p we evaluated the effect of its overexpression in Pichia. The KAR2 UPR-responsive gene was strongly upregulated. Electron microscopy revealed an expansion of the intracellular membranes in Hac1p-overexpressing strains. We then evaluated the effect of inducible and constitutive UPR induction on the production of secreted, surface displayed and membrane proteins. Wherever Hac1p overexpression affected heterologous protein expression levels, this effect was always stronger when Hac1p expression was inducible rather than constitutive. Depending on the heterologous protein, co-expression of Hac1p increased, decreased or had no effect on expression level. Moreover, α-mating factor prepro signal processing of a G-protein coupled receptor was more efficient with Hac1p overexpression; resulting in a significantly improved homogeneity.ConclusionsOverexpression of P. pastoris Hac1p can be used to increase the production of heterologous proteins but needs to be evaluated on a case by case basis. Inducible Hac1p expression is more effective than constitutive expression. Correct processing and thus homogeneity of proteins that are difficult to express, such as GPCRs, can be increased by co-expression with Hac1p.

Boosted expression of the SARS-CoV nucleocapsid protein in tobacco and its immunogenicity in mice

Vaccines produced in plant systems are safe and economical; however, the extensive application of plant-based vaccines is mainly hindered by low expression levels of heterologous proteins in plant systems. Here, we demonstrated that the post-transcriptional gene silencing suppressor p19 protein from tomato bushy stunt virus substantially enhanced the transient expression of recombinant SARS-CoV nucleocapsid (rN) protein in Nicotiana benthamiana. The rN protein in the agrobacteria-infiltrated plant leaf accumulated up to a concentration of 79μg per g fresh leaf weight at 3 days post infiltration. BALB/c mice were intraperitoneally vaccinated with pre-treated plant extract emulsified in Freund's adjuvant. The rN protein-specific IgG in the mouse sera attained a titer about 1:1,800 following three doses of immunization, which suggested effective B-cell maturation and differentiation in mice. Antibodies of the subclasses IgG1 and IgG2a were abundantly present in the mouse sera. During vaccination of rN protein, the expression of IFN-γ and IL-10 was evidently up-regulated in splenocytes at different time points, while the expression of IL-2 and IL-4 was not. Up to now, this is the first study that plant-expressed recombinant SARS-CoV N protein can induce strong humoral and cellular responses in mice.

Combined protein construct and synthetic gene engineering for heterologous protein expression and crystallization using Gene Composer

BackgroundWith the goal of improving yield and success rates of heterologous protein production for structural studies we have developed the database and algorithm software package Gene Composer. This freely available electronic tool facilitates the information-rich design of protein constructs and their engineered synthetic gene sequences, as detailed in the accompanying manuscript.ResultsIn this report, we compare heterologous protein expression levels from native sequences to that of codon engineered synthetic gene constructs designed by Gene Composer. A test set of proteins including a human kinase (P38α), viral polymerase (HCV NS5B), and bacterial structural protein (FtsZ) were expressed in both E. coli and a cell-free wheat germ translation system. We also compare the protein expression levels in E. coli for a set of 11 different proteins with greatly varied G:C content and codon bias.ConclusionThe results consistently demonstrate that protein yields from codon engineered Gene Composer designs are as good as or better than those achieved from the synonymous native genes. Moreover, structure guided N- and C-terminal deletion constructs designed with the aid of Gene Composer can lead to greater success in gene to structure work as exemplified by the X-ray crystallographic structure determination of FtsZ from Bacillus subtilis. These results validate the Gene Composer algorithms, and suggest that using a combination of synthetic gene and protein construct engineering tools can improve the economics of gene to structure research.

Codon Optimization Increases Steady-State mRNA Levels in Aspergillus oryzae Heterologous Gene Expression

We investigated the effect of codon optimization on the expression levels of heterologous proteins in Aspergillus oryzae, using the mite allergen Der f 7 as a model protein. A codon-optimized Der f 7 gene was synthesized according to the frequency of codon usage in A. oryzae by recursive PCR. Both native and optimized Der f 7 genes were expressed under the control of a high-level-expression promoter with their own signal peptides or in a fusion construct with A. oryzae glucoamylase (GlaA). Codon optimization markedly increased protein and mRNA production levels in both nonfused and GlaA-fused Der f 7 constructs. For constructs with native codons, analysis by 3' rapid amplification of cDNA ends revealed that poly(A) tracts tended to be added within the coding region, producing aberrant mRNAs that lack a termination codon. Insertion of a termination codon between the carrier GlaA and native Der f 7 proteins in the GlaA fusion construct resulted in increases in mRNA and secreted-carrier-GlaA levels. These results suggested that mRNAs without a termination codon as a result of premature polyadenylation are degraded, possibly through the nonstop mRNA decay pathway. We suggest that codon optimization in A. oryzae results in elimination of cryptic polyadenylation signals in native Der f 7, thereby circumventing the production of truncated transcripts and resulting in an increase in steady-state mRNA levels.