Recombinant expression of Barnase in Escherichia coli and its application in plasmid purification.

BACKGROUND: The use of bovine-origin ribonucleases has been part of the standard protocol for plasmid DNA purification. As the field of gene therapy now enters the clinical stage, such enzymes need to be phased out or alternative purification protocols need to be developed to ensure product safety and regulatory compliance. The recombinant expression of bacterial RNase is fraught with toxicity problems making it a challenging enzyme to express. The current study describes a plasmid construct that allowed expression of barnase in Escherichia coli under co-expression of its native inhibitor barstar. RESULTS: The pure enzyme without the inhibitor barstar was exported to the extracellular space through the periplasm and then purified from the cell-free supernatant. Cation exchange chromatography was employed as a primary purification step. This was followed by hydrophobic interaction chromatography which resulted in a concentrated fraction of active enzyme. Although current levels of volumetric activity achieved are quite meagre (4 Kunitz units mL- 1), in principle its application to plasmid DNA purification could be proved. Currently, this is capable of processing small amounts (13 g) of bacterial biomass for plasmid production. CONCLUSIONS: The current work focusses on the downstream purification strategies for a recombinant RNase and sets a framework for higher scale production if specific productivity is increased by optimal hosts and/or re-engineered plasmids. Also important is to curtail the massive enzyme loss during purification by cation exchange chromatography. Application of even a relatively small amount of recombinant RNase would contribute to greatly reducing the initial RNA levels in alkaline lysates thereby augmenting further downstream plasmid purification steps.

Integration event induced changes in recombinant protein productivity in Pichia pastoris discovered by whole genome sequencing and derived vector optimization.

BACKGROUND: The classic AOX1 replacement approach is still one of the most often used techniques for expression of recombinant proteins in the methylotrophic yeast Pichia pastoris. Although this approach is largely successful, it frequently delivers clones with unpredicted production characteristics and a work-intense screening process is required to find the strain with desired productivity. RESULTS: In this project 845 P. pastoris clones, transformed with a GFP expression cassette, were analyzed for their methanol-utilization (Mut)-phenotypes, GFP gene expression levels and gene copy numbers. Several groups of strains with irregular features were identified. Such features include GFP expression that is markedly higher or lower than expected based on gene copy number as well as strains that grew under selective conditions but where the GFP gene cassette and its expression could not be detected. From these classes of strains 31 characteristic clones were selected and their genomes sequenced. By correlating the assembled genome data with the experimental phenotypes novel insights were obtained. These comprise a clear connection between productivity and cassette-to-cassette orientation in the genome, the occurrence of false-positive clones due to a secondary recombination event, and lower total productivity due to the presence of untransformed cells within the isolates were discovered. To cope with some of these problems, the original vector was optimized by replacing the AOX1 terminator, preventing the occurrence of false-positive clones due to the secondary recombination event. CONCLUSIONS: Standard methods for transformation of P. pastoris led to a multitude of unintended and sometimes detrimental integration events, lowering total productivity. By documenting the connections between productivity and integration event we obtained a deeper understanding of the genetics of mutation in P. pastoris. These findings and the derived improved mutagenesis and transformation procedures and tools will help other scientists working on recombinant protein production in P. pastoris and similar non-conventional yeasts.

Antibiotic-free segregational plasmid stabilization in Escherichia coli owing to the knockout of triosephosphate isomerase (tpiA).

BACKGROUND: Segregational stability of plasmids is of major concern for recombinant bacterial production strains. One of the best strategies to counteract plasmid loss is the use of auxotrophic mutants which are complemented with the lacking gene along with the product-relevant ones. However, these knockout mutants often show unwanted growth in complex standard media or no growth at all under uncomplemented conditions. This led to the choice of a gene for knockout that only connects two essential arms of an essential metabolic pathway - the glycolysis. RESULTS: Triosephosphate isomerase was chosen because its knockout will have a tremendous effect on growth on glucose as well as on glycerol. On glycerol the effect is almost absolute whereas on glucose growth is still possible, but with considerably lower rate than usual. This feature is essential because it may render cloning easier. This enzymatic activity was successfully tested as an alternative to antibiotic-based plasmid selection. Expression of a model recombinant ß-glucanase in continuous cultivation was possible with stable maintenance of the plasmid. In addition, the complementation of tpiA knockout strains by the corresponding plasmids and their growth characteristics were tested on a series of complex and synthetic media. The accumulation of methylglyoxal during the growth of tpiA-deficient strains was shown to be a possible cause for the growth disadvantage of these strains in comparison to the parent strain for the Keio Collection strain or the complemented knock-out strain. CONCLUSION: Through the use of this new auxotrophic complementation system, antibiotic-free cloning and selection of recombinant plasmid were possible. Continuous cultivation and recombinant protein expression with high segregational stability over an extended time period was also demonstrated.

Extracellular recombinant protein production under continuous culture conditions with Escherichia coli using an alternative plasmid selection mechanism.

The secretion of recombinant proteins into the extracellular space by Escherichia coli presents advantages like easier purification and protection from proteolytic degradation. The controlled co-expression of a bacteriocin release protein aids in moving periplasmic proteins through the outer membrane. Since such systems have rarely been applied in continuous culture it seemed to be attractive to study the interplay between growth-phase regulated promoters controlling release protein genes and the productivity of a chemostat process. To avoid the use of antibiotics and render this process more sustainable, alternative plasmid selection mechanisms were required. In the current study, the strain E. coli JM109 harboring plasmid p582 was shown to stably express and secrete recombinant ß-glucanase in continuous culture using a minimal medium. The segregational instability of the plasmid in the absence of antibiotic selection pressure was demonstrated. The leuB gene, crucial in the leucine biosynthetic pathway, was cloned onto plasmid p582 and the new construct transformed into an E. coli Keio (ΔleuB) knockout strain. The ability of the construct to complement the leucine auxotrophy was initially tested in shake-flasks and batch cultivation. Later, this strain was successfully grown for more than 200 h in a chemostat and was found to be able to express the recombinant protein. Significantly, it showed a stable maintenance of the recombinant plasmid in the absence of any antibiotics. The plasmid stability in a continuously cultivated E. coli fermentation, in the absence of antibiotics, with extracellular secretion of recombinant protein provides an interesting model for further improvements.

Establishment of a near-contiguous genome sequence of the citric acid producing yeast Yarrowia lipolytica DSM 3286 with resolution of rDNA clusters and telomeres.

Yarrowia lipolytica is an oleaginous yeast that is particularly suitable for the sustainable production of secondary metabolites. The genome of this yeast is characterized by its relatively large size and its high number of different rDNA clusters located in its telomeric regions. However, due to the presence of long repetitive elements in the sub-telomeric regions, rDNA clusters and telomeres are missing in current genome assemblies of Y. lipolytica. Here, we present the near-contiguous genome sequence of the biotechnologically relevant strain DSM 3286. We employed a hybrid assembly strategy combining Illumina and nanopore sequencing reads to integrate all six rDNA clusters as well as telomeric repeats into the genome sequence. By fine-tuning of DNA isolation and library preparation protocols, we were able to create ultra-long reads that not only contained multiples of mitochondrial genomes but also shed light on the inter- and intra-chromosomal diversity of rDNA cluster types. We show that there are ten different rDNA units present in this strain that additionally appear in a predefined order in a cluster. Based on single reads, we also demonstrate that the number of rDNA repeats in a specific cluster varies from cell to cell within a population.

Recombinant expression of an l-amino acid oxidase from the fungus Hebeloma cylindrosporum in Pichia pastoris including fermentation.

l-amino acid oxidases (LAAOs) are flavoenzymes that catalyze the oxidative deamination of l-amino acids to the corresponding α-keto acids, ammonia, and hydrogen peroxide. Here, we show the overexpression, purification, and the characterization of LAAO4 from the fungus Hebeloma cylindrosporum in the yeast Pichia pastoris with a 9His-tag and compare this with the recently characterized 6His-hcLAAO4 expressed in E. coli. The expression of the enzyme with an ER-signal sequence in P. pastoris resulted in a glycosylated, secreted protein. The enzymatic activity without activation was higher after expression in P. pastoris compared to E. coli. Due to treatment with acidic pH, a striking increase of activity could be detected for both expression systems resulting in similar specific activities after acid activation. Regarding the substrate spectrum, temperature stability, Km, and vmax values, hcLAAO4 showed very few differences when produced in these two expression systems. A higher yield of hcLAAO4 could be obtained by fermentation.

Integrated bioprocess for the production and purification of recombinant proteins by affinity chromatography in Escherichia coli.

In order to improve the effectiveness of the production of recombinant proteins in E. coli, integrated fermentation processes were developed. Therefore, expression vectors were constructed containing a strongly expressed gene for a beta-glucanase fused with a metal-chelating affinity tag and a leader peptide for directing the fusion protein into the periplasmic space. Its export into the medium was achieved by means of co-expression of a bacteriocin-release protein, the Kil protein from pColE1. Bioreactors were modified so that special devices containing metal chelate pentadentate chelator PDC resins were located within the bioreactor. Using the bioreactor with an internal device the Zn2+-PDC had a 4.3-fold higher binding capacity than metal-free PDC (12.3 and 2.6 kU ml(-1) PDC, respectively. Using the bioreactor with charged PDC in an external circuit revealed even higher beta-glucanase concentration (65.6 kU ml(-1)), i.e. 1.5-fold compared to the internal adsorbent system.

A machine vision system for automated non-invasive assessment of cell viability via dark field microscopy, wavelet feature selection and classification.

BACKGROUND: Cell viability is one of the basic properties indicating the physiological state of the cell, thus, it has long been one of the major considerations in biotechnological applications. Conventional methods for extracting information about cell viability usually need reagents to be applied on the targeted cells. These reagent-based techniques are reliable and versatile, however, some of them might be invasive and even toxic to the target cells. In support of automated noninvasive assessment of cell viability, a machine vision system has been developed. RESULTS: This system is based on supervised learning technique. It learns from images of certain kinds of cell populations and trains some classifiers. These trained classifiers are then employed to evaluate the images of given cell populations obtained via dark field microscopy. Wavelet decomposition is performed on the cell images. Energy and entropy are computed for each wavelet subimage as features. A feature selection algorithm is implemented to achieve better performance. Correlation between the results from the machine vision system and commonly accepted gold standards becomes stronger if wavelet features are utilized. The best performance is achieved with a selected subset of wavelet features. CONCLUSION: The machine vision system based on dark field microscopy in conjugation with supervised machine learning and wavelet feature selection automates the cell viability assessment, and yields comparable results to commonly accepted methods. Wavelet features are found to be suitable to describe the discriminative properties of the live and dead cells in viability classification. According to the analysis, live cells exhibit morphologically more details and are intracellularly more organized than dead ones, which display more homogeneous and diffuse gray values throughout the cells. Feature selection increases the system's performance. The reason lies in the fact that feature selection plays a role of excluding redundant or misleading information that may be contained in the raw data, and leads to better results.

Systematic investigation of optimal aptamer immobilization for protein-microarray applications.

Aptamers are short single-stranded DNA or RNA oligonucleotides that can bind to a wide range of target molecules with high affinity and specificity. As nucleic acids, aptamers can undergo denaturation, but the process is reversible. As a result of this stability and the possibility of automated selection of aptamers, these oligonucleotides are highly promising capture molecules in microarray formats. In this study, his-tagged proteins and an aptamer directed against the his-tag were chosen as a model system. Different factors affect the activity of aptamers immobilized on a solid support like a microarray surface. The orientation of the immobilized aptamer plays an important role in correct aptamer folding and, thus, in effective binding of the corresponding target. Other important parameters identified in this work are the microarrays' surface charge as well as the length of the spacer between aptamer and solid support. These parameters were investigated systematically, resulting in the development of an aptamer-based microarray for detection of his-tagged proteins. The general applicability of the developed immobilization strategy was demonstrated by utilization of three different aptamers.

Secretion of recombinant proteins from E. coli.

The microorganism Escherichia coli is commonly used for recombinant protein production. Despite several advantageous characteristics like fast growth and high protein yields, its inability to easily secrete recombinant proteins into the extracellular medium remains a drawback for industrial production processes. To overcome this limitation, a multitude of approaches to enhance the extracellular yield and the secretion efficiency of recombinant proteins have been developed in recent years. Here, a comprehensive overview of secretion mechanisms for recombinant proteins from E. coli is given and divided into three main sections. First, the structure of the E. coli cell envelope and the known natural secretion systems are described. Second, the use and optimization of different one- or two-step secretion systems for recombinant protein production, as well as further permeabilization methods are discussed. Finally, the often-overlooked role of cell lysis in secretion studies and its analysis are addressed. So far, effective approaches for increasing the extracellular protein concentration to more than 10 g/L and almost 100% secretion efficiency exist, however, the large range of optimization methods and their combinations suggests that the potential for secretory protein production from E. coli has not yet been fully realized.

Recycling of bacterial biomass in a process of L-threonine production by means of a recombinant strain of Escherichia coli.

The Gram-negative bacterium Escherichia coli B-3996 represents an interesting host organism for the production of the essential amino acid L-threonine. Microbial processes - especially those of aerobic cultivation - lead to the generation of considerable amounts of biomass, thus lowering the product yield. These are the reasons for studying methods for the recycling of biomass from E. coli. It will be shown that it is possible to disintegrate the microbial biomass - preferably by means of high pressure homogenisation followed by a protease treatment of the resulting slurry of debris - in an efficient way and to recycle at least different amounts of the soluble part as cultivation medium component. By studying the growth and product formation of E. coli no adverse effects have been observed.

The plasticity of global proteome and genome expression analyzed in closely related W3110 and MG1655 strains of a well-studied model organism, Escherichia coli-K12.

The use of Escherichia coli as a model organism has provided a great deal of basic information in biomolecular sciences. Examining trait differences among closely related strains of the same species addresses a fundamental biological question: how much diversity is there at the single species level? The main aim of our research was to identify significant differences in the activities of groups of genes between two laboratory strains of an organism closely related in genome structure. We demonstrate that despite strict and controlled growth conditions, there is high plasticity in the global proteome and genome expression in two closely related E. coli K12 sub-strains (W3110 and MG1655), which differ insignificantly in genome structure. The growth patterns of these two sub-strains were very similar in a well-equipped bioreactor, and their genome structures were shown to be almost identical by DNA microarray. However, detailed profiling of protein and gene expression by 2-dimensional gel electrophoresis and microarray analysis showed many differentially expressed genes and proteins, combinations of which were highly correlated. The differentially regulated genes and proteins belonged to the following functional categories: genes regulated by sigma subunit of RNA polymerase (RpoS), enterobactin-related genes, and genes involved in central metabolism. Genes involved in central cell metabolism - the glycolysis pathway, the tricarboxylic acid cycle and the glyoxylate bypass - were differentially regulated at both the mRNA and proteome levels. The strains differ significantly in central metabolism and thus in the generation of precursor metabolites and energy. This high plasticity probably represents a universal feature of metabolic activities in closely related species, and has the potential to reveal differences in regulatory networks. We suggest that unless care is taken in the choice of strains for any validating experiment, the results might be misleading.

In situ dark field microscopy for on-line monitoring of yeast cultures.

A new-type in situ probe has been developed to acquire dark field images of yeast in bioreactors. It has been derived from an in situ bright field microscope that is able to measure cell density in bioreactors during fermentation processes. The illumination part of the probe has been replaced with a dark field device, in which an aspheric condenser is used, so that high contrast dark field images can be obtained. The technique of second imaging is implemented to improve the sharpness of the images by means of a relay lens. This new in situ probe is expected to enable the evaluation of the cell viability without staining owing to modern image processing.

Towards systems metabolic engineering in Pichia pastoris.

The methylotrophic yeast Pichia pastoris is firmly established as a host for the production of recombinant proteins, frequently outperforming other heterologous hosts. Already, a sizeable amount of systems biology knowledge has been acquired for this non-conventional yeast. By applying various omics-technologies, productivity features have been thoroughly analyzed and optimized via genetic engineering. However, challenging clonal variability, limited vector repertoire and insufficient genome annotation have hampered further developments. Yet, in the last few years a reinvigorated effort to establish P. pastoris as a host for both protein and metabolite production is visible. A variety of compounds from terpenoids to polyketides have been synthesized, often exceeding the productivity of other microbial systems. The clonal variability was systematically investigated and strategies formulated to circumvent untargeted events, thereby streamlining the screening procedure. Promoters with novel regulatory properties were discovered or engineered from existing ones. The genetic tractability was increased via the transfer of popular manipulation and assembly techniques, as well as the creation of new ones. A second generation of sequencing projects culminated in the creation of the second best functionally annotated yeast genome. In combination with landmark physiological insights and increased output of omics-data, a good basis for the creation of refined genome-scale metabolic models was created. The first application of model-based metabolic engineering in P. pastoris showcased the potential of this approach. Recent efforts to establish yeast peroxisomes for compartmentalized metabolite synthesis appear to fit ideally with the well-studied high capacity peroxisomal machinery of P. pastoris. Here, these recent developments are collected and reviewed with the aim of supporting the establishment of systems metabolic engineering in P. pastoris.

Complete Draft Genome Sequence of Escherichia coli KRX, a Strain for Efficient Cloning and High-Yield Expression of Proteins under Control of the T7 RNA Polymerase.

Escherichia coli KRX is a strain offering both a high transformation efficiency and the possibility to produce the target protein to high yields in one host, avoiding additional cloning steps. Here, the draft genome sequence of E. coli KRX is presented and provides the genetic basis for additional biotechnological applications.

Fermentative production of L-pipecolic acid from glucose and alternative carbon sources.

Corynebacterium glutamicum is used for the million-ton scale production of amino acids and has recently been engineered for production of the cyclic non-proteinogenic amino acid L-pipecolic acid (L-PA). In this synthetic pathway L-lysine was converted to L-PA by oxidative deamination, dehydration and reduction by L-lysine 6-dehydrogenase (deaminating) from Silicibacter pomeroyi and pyrroline 5-carboxylate reductase from C. glutamicum. However, production of L-PA occurred as by-product of L-lysine production only. Here, the author show that abolishing L-lysine export by the respective gene deletion resulted in production of L-PA as major product without concomitant lysine production while the specific growth rate was reduced due to accumulation of high intracellular lysine concentrations. Increasing expression of the genes encoding L-lysine 6-dehydrogenase and pyrroline 5-carboxylate reductase in C. glutamicum strain PIPE4 increased the L-PA titer to 3.9 g L-1 , and allowed faster growth and, thus, a higher volumetric productivity of 0.08 ± 0.00 g L-1 h-1 respectively. Secondly, expression of heterologous genes for utilization of glycerol, xylose, glucosamine, and starch in strain PIPE4 enabled L-PA production from these alternative carbon sources. Third, in a glucose/sucrose-based fed-batch fermentation with C. glutamicum PIPE4 L-PA was produced to a titer of 14.4 g L-1 with a volumetric productivity of 0.21 g L-1 h-1 and an overall yield of 0.20 g g-1 .

A Mitochondrial Autonomously Replicating Sequence from Pichia pastoris for Uniform High Level Recombinant Protein Production.

Pichia pastoris is a non-conventional methylotrophic yeast that is widely used for recombinant protein production, typically by stably integrating the target gene into the genome as part of an expression cassette. However, the comparatively high clonal variability associated with this approach usually necessitates a time intense screening step in order to find strains with the desired productivity. Some of the factors causing this clonal variability can be overcome using episomal vectors containing an autonomously replicating sequence (ARS). Here, we report on the discovery, characterization, and application of a fragment of mitochondrial DNA from P. pastoris for use as an ARS. First encountered as an off-target event in an experiment aiming for genomic integration, the newly created circular plasmid named "pMito" consists of the expression cassette and a fragment of mitochondrial DNA. Multiple matches to known ARS consensus sequence motifs, but no exact match to known chromosomal ARS from P. pastoris were detected on the fragment, indicating the presence of a novel ARS element. Different variants of pMito were successfully used for transformation and their productivity characteristics were assayed. All analyzed clones displayed a highly uniform expression level, exceeding by up to fourfold that of a reference with a single copy integrated in its genome. Expressed GFP could be localized exclusively to the cytoplasm via super-resolution fluorescence microscopy, indicating that pMito is present in the nucleus. While expression levels were homogenous among pMito clones, an apparent upper limit of expression was visible that could not be explained based on the gene dosage. Further investigation is necessary to fully understand the bottle-neck hindering this and other ARS vectors in P. pastoris from reaching their full capability. Lastly, we could demonstrate that the mitochondrial ARS from P. pastoris is also suitable for episomal vector transformation in Saccharomyces cerevisiae, widening the potential for biotechnological application. pMito displayed strong potential to reduce clonal variability in experiments targeting recombinant protein production. These findings also showcase the as of yet largely untapped potential of mitochondrial ARS from different yeasts for biotechnological applications.

Complete Draft Genome Sequence of Escherichia coli K802.

Escherichia coli K802 is an old strain used for cloning experiments, as well as for the production of recombinant proteins. To understand the genomic background of E. coli K802 better, we present here its complete draft genome sequence.

Fed-batch production and secretion of streptavidin by Hansenula polymorpha: Evaluation of genetic factors and bioprocess development.

Streptavidin - a protein secreted by the filamentous bacterium Streptomyces avidinii - is applied in a variety of methods, leading to numerous studies on its heterologous production. Development and characterization of a novel expression system for streptavidin genes by Hansenula polymorpha is described utilizing different target gene variants along with the two methanol-inducible promoters PMOX and PFMD. Extracellular product concentrations were higher for cultivation at 30 instead of 37°C. The best performing strain carrying the full-length streptavidin gene under control of PFMD was characterized in the bioreactor applying a synthetic medium and oxygen-controlled feeding of glucose. Derepression resulted in an extracellular concentration of 1.31±0.07µM of tetrameric streptavidin after 48h (27.3nMh(-1)). Feeding of glycerol improved biomass formation, but lowered the product concentration. By combining derepression and methanol induction the final extracellular streptavidin concentration increased to 11.42±0.22µM (approx. 751mgL(-1)), yielding a productivity of 52.5nMh(-1). Despite supplementing biotin the proportion of biotin-blocked binding sites in the supernatant dropped from 54.4±5.0 % after 18h to 17.2±6.5 % towards the end of glucose feeding to a final value of 1.1±3.8 %, indicating a highly bioactive product. Thus, H. polymorpha proved to be a suitable host for the production of streptavidin.