Improvement of Escherichia coli microaerobic oxygen metabolism by Vitreoscilla hemoglobin: New insights from NAD(P)H fluorescence and culture redox potential

On-line NAD(P)H fluorescence and culture redox potential (CRP) measurements were utilized to investigate the role of Vitreoscilla hemoglobin (VHb) in perturbing oxygen metabolism of microaerobic Escherichia coli Batch cultures of a VHb-synthesizing E. coli strain and the iso-genic control under fully aerated conditions were subject to several high/low oxygen transitions, and the NAD(P)H fluorescence and CRP were monitored during these passages. The presence of VHb decreased the rate of net NAD(P)H generation by 2.4-fold under diminishing oxygen tension. In the absence of aeration, the strain producing VHb maintained a steady NAD(P)H level 1.8-fold less than that of the control, indicating that the presence of VHb keeps E. coli in a more oxidized state under oxygen-limited conditions. Estimated from CRP, the oxygen uptake rates near anoxia were 25% higher for cells with VHb than those without. These results suggest that VHb-expressing cells have a higher microaerobic electron transport chain turnover rate. To examine how NAD(P)H utilization of VHb-expressing cells responds to rapidly changing oxygen tension, which is common in large-scale fermentations, we pulsed air intermittently into a cell suspension and recorded the fluorescence response to the imposed dissolved oxygen (DO) fluctuation. Relative to the control, cells containing VHb had a sluggish fluorescence response to sudden changes of oxygen tension, suggesting that VHb buffers intracellular redox perturbations caused by extracellular DO fluctuations.(c) John Wiley & Sons, Inc.     

从透明颤菌血红蛋白谈到植物缺氧与转基因作物

扼要介绍透明颤菌血红蛋白基因在多种微生物的表达、调节和生理功能,特别是在生物工程方面可能的应用。但最值得重视的是这一基因在烟草中的表达及其生理效应,它为我们提出一个重要的问题,就是植物是否缺氧,透明颤菌血红蛋白基因很可能是构建转基因作物的重要元件。     

Chimeric Vitreoscilla Hemoglobin (VHb) Carrying a Flavoreductase Domain Relieves Nitrosative Stress in Escherichia coli: New Insight into the Functional Role of VHb

Dimeric hemoglobin (VHb) from the bacterium Vitreoscilla sp. strain C1 displays 30 to 53% sequence identity with the heme-binding domain of flavohemoglobins (flavoHbs) and exhibits the presence of potential sites for the interaction with its FAD/NADH reductase partner. The intersubunit contact region of VHb indicates a small interface between two monomers of the homodimer, suggesting that the VHb dimers may dissociate easily. Gel filtration chromatography of VHb exhibited a 25 to 30% monomeric population of VHb, at a low protein concentration (0.05 mg/ml), whereas dimeric VHb remained dominant at a high protein concentration (10 mg/ml). The structural characteristics of VHb suggest that the flavoreductase can also associate and interact with VHb in a manner analogous to flavoHbs and could yield a flavo-VHb complex. To unravel the functional relevance of the VHb-reductase association, the reductase domain of flavoHb from Ralstonia eutropha (formerly Alcaligenes eutrophus) was genetically engineered to generate a VHb-reductase chimera (VHb-R). The physiological implications of VHb and VHb-R were studied in an hmp mutant of Escherichia coli, incapable of producing any flavoHb. Cellular respiration the of the hmp mutant was instantaneously inhibited in the presence of 10 μM nitric oxide (NO) but remained insensitive to NO inhibition when these cells produced VHb-R. In addition, E. coli overproducing VHb-R exhibited NO consumption activity that was two to three times slower in cells overexpressing only VHb and totally undetectable in the control cells. A purified preparation of VHb-R exhibited a three- to fourfold-higher NADH-dependent NO uptake activity than that of VHb alone. Overproduction of VHb-R in the hmp mutant of E. coli conferred relief from the toxicity of sodium nitroprusside, whereas VHb alone provided only partial benefit under similar condition, suggesting that the association of VHb with reductase improves its capability to relieve the deleterious effect of nitrosative stress. Based on these results, it has been proposed that the unique structural features of VHb may allow it to acquire two functional states in vivo, namely, a single-domain homodimer that may participate in facilitated oxygen transfer or a two-domain heterodimer in association with its partner reductase that may be involved in modulating the cellular response under different environmental conditions. Due to this inherent structural flexibility, it may perform multiple functions in the cellular metabolism of its host. Separation of the oxidoreductase domain from VHb may thus provide a physiological advantage to its host.     

Chimeric Vitreoscilla hemoglobin (VHb) carrying a flavoreductase domain relieves nitrosative stress in Escherichia coli: new insight into the functional role of VHb.

Dimeric hemoglobin (VHb) from the bacterium Vitreoscilla sp. strain C1 displays 30 to 53% sequence identity with the heme-binding domain of flavohemoglobins (flavoHbs) and exhibits the presence of potential sites for the interaction with its FAD/NADH reductase partner. The intersubunit contact region of VHb indicates a small interface between two monomers of the homodimer, suggesting that the VHb dimers may dissociate easily. Gel filtration chromatography of VHb exhibited a 25 to 30% monomeric population of VHb, at a low protein concentration (0.05 mg/ml), whereas dimeric VHb remained dominant at a high protein concentration (10 mg/ml). The structural characteristics of VHb suggest that the flavoreductase can also associate and interact with VHb in a manner analogous to flavoHbs and could yield a flavo-VHb complex. To unravel the functional relevance of the VHb-reductase association, the reductase domain of flavoHb from Ralstonia eutropha (formerly Alcaligenes eutrophus) was genetically engineered to generate a VHb-reductase chimera (VHb-R). The physiological implications of VHb and VHb-R were studied in an hmp mutant of Escherichia coli, incapable of producing any flavoHb. Cellular respiration the of the hmp mutant was instantaneously inhibited in the presence of 10 microM nitric oxide (NO) but remained insensitive to NO inhibition when these cells produced VHb-R. In addition, E. coli overproducing VHb-R exhibited NO consumption activity that was two to three times slower in cells overexpressing only VHb and totally undetectable in the control cells. A purified preparation of VHb-R exhibited a three- to fourfold-higher NADH-dependent NO uptake activity than that of VHb alone. Overproduction of VHb-R in the hmp mutant of E. coli conferred relief from the toxicity of sodium nitroprusside, whereas VHb alone provided only partial benefit under similar condition, suggesting that the association of VHb with reductase improves its capability to relieve the deleterious effect of nitrosative stress. Based on these results, it has been proposed that the unique structural features of VHb may allow it to acquire two functional states in vivo, namely, a single-domain homodimer that may participate in facilitated oxygen transfer or a two-domain heterodimer in association with its partner reductase that may be involved in modulating the cellular response under different environmental conditions. Due to this inherent structural flexibility, it may perform multiple functions in the cellular metabolism of its host. Separation of the oxidoreductase domain from VHb may thus provide a physiological advantage to its host.     

Vitreoscilla hemoglobin. Intracellular localization and binding to membranes

The obligate aerobic bacterium, Vitreoscilla, synthesizes elevated quantities of a homodimeric hemoglobin (VHb) under hypoxic growth conditions. Expression of VHb in heterologous hosts often enhances growth and product formation. A role in facilitating oxygen transfer to the respiratory membranes is one explanation of its cellular function. Immunogold labeling of VHb in both Vitreoscilla and recombinant Escherichia coli bearing the VHb gene clearly indicated that VHb has a cytoplasmic (not periplasmic) localization and is concentrated near the periphery of the cytosolic face of the cell membrane. OmpA signal-peptide VHb fusions were transported into the periplasm in E. coli, but this did not confer any additional growth advantage. The interaction of VHb with respiratory membranes was also studied. The K(d) values for the binding of VHb to Vitreoscilla and E. coli cell membranes were approximately 5-6 microm, a 4-8-fold higher affinity than those of horse myoglobin and hemoglobin for these same membranes. VHb stimulated the ubiquinol-1 oxidase activity of inverted Vitreoscilla membranes by 68%. The inclusion of Vitreoscilla cytochrome bo in proteoliposomes led to 2.4- and 6-fold increases in VHb binding affinity and binding site number, respectively, relative to control liposomes, suggesting a direct interaction between VHb and cytochrome bo.     

pH-induced quaternary assembly of Vitreoscilla hemoglobin: The monomer exhibits better peroxidase activity

pH-dependent (pH 6.0–8.0) quaternary structural changes of ferric Vitreoscilla hemoglobin (VHb) have been investigated using dynamic light scattering. The VHb exhibits a monomeric state under neutral conditions at pH 7.0, while the protein forms distinct homodimeric species at pH 6.0 and 8.0, respectively. The dissociation constant obtained using the Bio-Layer Interferometry technology indicates that, at pH 7.0, the monomer–monomer dissociation of VHb is about 6-fold or 5-fold higher (K_D = 6.34 μM) compared with that at slightly acidic pH (K_D = 1.05 μM) or slightly alkaline pH (K_D = 1.22 μM). The pH-dependent absorption spectra demonstrate that the heme microenvironment of VHb is sensitive to the changes of pH value. The maximum absorption band of heme group of VHb shifts from 402 nm to 407 nm when pH changes from 6.0 to 8.0. In addition, the fluorescence emission spectra of VHb, taken at excitation wavelength of 295 nm, suggest that the single Trp122 fluorescence quantum yields in VHb are decreased due to the formation of the homodimeric species. However, the circular dichroism spectra data display that the secondary structures of VHb are little affected by pH transitions. The pH-dependent peroxidase activity of VHb was also investigated in this study. The optimum pH for VHb using 2,2′-azino-bis-(3-ethylbenzothiazoline-6-sulfonic acid) as substrate is 7.0, which implies that the monomer state of VHb would exhibit better peroxidase activity than the homodimeric species of VHb at pH 6.0 and 8.0.     

Cloning and Expression of the Vitreoscilla Hemoglobin Gene in Enterobacter Aerogenes: Effect on Cell Growth and Oxygen Uptake

The hemoglobins found in unicellular organisms show a great deal of chemical reactivity, protecting cells against oxidative stress, and hence have been implicated in a wider variety of potential functions than those traditionally associated with animal and plant hemoglobins. There are well-documented studies showing that bacteria expressing Vitreoscilla hemoglobin (VHb), the first prokaryotic hemoglobin characterized, have better growth and oxygen uptake rates than their VHb counterparts. Here, the expression of VHb, its effect on the growth and antioxidant enzyme status of cells under different culture conditions was studied by cloning the complete regulatory and coding sequences (vgb) for VHb in Enterobacter aerogenes. Contrary to what has been reported for Escherichia coli, the expression of vgb in E.aerogenes decreased several fold under 10% of atmospheric oxygen (2% oxygen) and its growth was not greatly improved by the presence of VHb. Measured either as viable cells or total cell mass, untransformed E. aerogenes grew better than the recombinant strains. At the late exponential phase, however, the vgb-bearing strain was determined to have a higher cell number and total cell mass than the strain bearing only the plasmid vector with no vgb insert. The VHb expressing strain also had an oxygen uptake rate several fold higher than its counterparts. Given that oxidative stress may occur upon elevated oxygen exposure and be balanced by the action of antioxi-dative compounds, the level of antioxidative response of E. aerogenes expressing VHb was also studied. The VHb expressing strain had substantially (1.5–2.6-fold) higher catalase activity than strains not expressing VHb. Both VHb+ and VHb- strains, however, showed similar levels of superoxide dismutase activity. The activity of both enzymes was also growth phase dependent. Stationary phase cells of all strains showed 2–5-fold higher activity for these enzymes than cells at the exponential phase.     

Error-prone PCR of Vitreoscilla hemoglobin (VHb) to support the growth of microaerobic Escherichia coli

Expression of the gene encoding bacterial hemoglobin (VHb) from Vitreoscilla has been previously used to improve recombinant cell growth and enhance product formation under microaerobic conditions. It is very likely that the properties of VHb are not optimized for foreign hosts; therefore, we used error-prone PCR to generate a number of randomly mutated vhb genes to be expressed and studied in Escherichia coli. In addition, the mutated VHb proteins also contained an extension of eight residues (MTMITPSF) at the amino terminus. VHb mutants were screened for improved growth properties under microaerobic conditions and 15 clones expressing mutated hemoglobin protein were selected for further characterization and cultivated in a microaerobic bioreactor to analyze the physiological effects of novel VHb proteins on cell growth. The expression of four VHb mutants, carried by pVM20, pVM50, pVM104, and pVM134, were able to enhance microaerobic growth of E. coli by approximately 22%, 155%, 50%, and 90%, respectively, with a concomitant decrease of acetate excretion into the culture medium. The vhb gene in pVM20 contains two mutations substituting residues Glu19(A17) and Glu137(H23) to Gly. pVM50 expresses a VHb protein carrying two mutations: His36(C1) to Arg36 and Gln66(E20) to Arg66. pVM104 and pVM134 express VHb proteins carrying the mutations Ala56(E10) to Gly and Ile24(B5) to Thr, respectively. Our experiments also indicate that the positive effects elicited by mutant VHb-expression from pVM20 and pVM50 are linked to the peptide tail. Removal of the N-terminal sequence reduced cell growth approximately 23% and 53%, respectively, relative to wild-type controls. These results clearly demonstrate that it is possible to obtain mutated VHb proteins with improved characteristics for improving microaerobic growth of E. coli by using combined mutation techniques, addition of a peptide tail, and random error-prone PCR.     

Co-expression of bacterial hemoglobin overrides high glucose-induced repression of foreign protein expression in Escherichia coli W3110

Co-expression of Vitreoscilla hemoglobin (VHb) can enhance production of foreign proteins in several microorganisms, including Escherichia coli. Production of foreign proteins [green fluorescent protein (GFP) and organophosphorous hydrolase (OPH)] has been examined in two typical industrial E. coli strains, W3110 (a K12 derivative) and BL21 (a B derivative). In particular, we investigated the effects of VHb co-expression and media glucose concentration on target protein production. We employed the nar O(2)-dependent promoter for self-tuning of VHb expression based on the natural changes in dissolved O(2) levels over the duration of culture. Foreign protein production in strain BL21 was decreased by a high glucose concentration but co-expression of VHb had no effect on this. In contrast, co-expression of VHb in strain W3110 overrode the glucose-induced repression and resulted in steady expression of foreign proteins.     

Improvement of amorpha-4,11-diene production by a yeast-conform variant of Vitreoscilla hemoglobin

Amorpha-4,11-diene is the precursor of the antimalarial compound artemisinin. The effect of Vitreoscilla hemoglobin (VHb) and its yeast-conform variant (VHbm) on amorpha-4,11-diene production in engineered Saccharomyces cerevisiae was investigated. First, the VHb gene was mutated to the yeast-conform variant VHbm based on step-by-step extension of a short region of the gene through a series of polymerase chain reactions (PCR). The artificial VHbm gene contained codons preferred by the yeast translation machinery. Two yeast expression vectors containing VHb or VHbm gene were constructed and introduced into the amorpha-4,11-diene-producing strain S. cerevisiae WK1 to form WK1[VHb] and WK1[VHbm], respectively. Western blot and CO-difference spectrum absorbance assay showed that VHb and VHbm were successfully expressed. In shake flasks, VHbm expression conferred higher cell growth than VHb expression. GC-MS results indicated the amorpha-4,11-diene production in WK1[VHbm] and WK1[VHb] was 3- and 2-fold higher than that in WK1, respectively. This suggests that VHb might improve the amorpha-4,11-diene production in engineered S. cerevisiae.     

Expression of double Vitreoscilla hemoglobin enhances growth and alters ribosome and tRNA levels in Escherichia coli

In several organisms, expression of a gene encoding dimeric hemoglobin (VHb) from the obligate aerobic bacterium Vitreoscilla stercoraria has been shown to increase microaerobic cell growth and enhance oxygen-dependent cell metabolism. In an attempt to further improve these effects of VHb, a gene encoding two vhb genes connected by a short linker of six base pairs was constructed and expressed in Escherichia coli(double VHb). Escherichia coli cells expressing double VHb reached a cell density 19% higher than that of cells expressing native VHb. The protein production per cell remained constant since the increase in cell growth was accompanied by an increase in protein content by 16%. Investigation of ribosome and tRNA content revealed that cells expressing double VHb reached their maximal capacity of protein synthesis later during cultivation than cells expressing native VHb, and furthermore they reached considerably higher levels of ribosome and tRNA compared to that of the VHb-expressing cells.     

Functional implications of the proximal site hydrogen bonding network in Vitreoscilla hemoglobin (VHb): role of Tyr95 (G5) and Tyr126 (H12)

Although Vitreoscilla hemoglobin (VHb) carries a conventional globin fold, its proximal site geometry is unique in having a hydrogen-bonding network between proximal site residues, HisF8-TyrG5-GluH23 and TyrG5-TyrH12. TyrG5 and TyrH12 were mutated to study their relevance in VHb function. VHb G5 mutants (Tyr95Phe and Tyr95Leu showed no stable oxyform and nitric oxide dioxygenase activity, whereas, VHb H12 mutants (Tyr126Phe and Tyr126Leu) displayed little change in their oxygen affinity indicating a crucial role of Tyr95 in protein function. The VHb H12 mutant, Tyr126Leu, enhanced the intracellular pool of oxygen and cell growth better than VHb. Molecular modeling suggests that the replacement of tyrosine with leucine in Tyr126Leu creates an opening on the protein surface that may facilitate oxygen diffusion and accumulation.     

Effect of Vitreoscilla hemoglobin dosage on microaerobic Escherichia coli carbon and energy metabolism

The amount of Vitreoscilla hemoglobin (VHb) expression was modulated over a broad range with an isopropyl-beta-D-thiogalactopyranoside- (IPTG-) inducible plasmid, and the consequences on microaerobic Escherichia coli physiology were examined in glucose fed-batch cultivations. The effect of IPTG induction on growth under oxygen-limited conditions was most visible during late fed-batch phase where the final cell density increased initially linearly with increasing VHb concentrations, ultimately saturating at a 2.7-fold increase over the VHb-negative (Vhb(-)) control. During the same growth phase, the specific excretions of fermentation by-products, acetate, ethanol, formate, lactate, and succinate from the culture expressing the highest amount of VHb were reduced by 25%, 49%, 68%, 72%, and 50%, respectively, relative to the VHb(-) control. During the exponential growth phase, VHb exerted a positive but smaller control on growth rate, growth yield, and respiration. Varying the amount of VHb from 0 to 3.8 mumol/g dry cell weight (DCW) increased the specific growth rate, the growth yield, and the oxygen consumption rate by 33%, 35%, and 60%, respectively. Increasing VHb concentration to 3.8 mumol/g DCW suppressed the rate of carbon dioxide evolution in the exponential phase by 30%. A metabolic flux distribution analysis incorporating data from these cultivations discloses that VHb(+) cells direct a larger fraction of glucose toward the pentose phosphate pathway and a smaller fraction of carbon through the tricarboxylic acid cycle from acetyl coenzyme A. The overall nicotinamide adenine dinucleotide [NAD(P)H] flux balance indicates that VHb-expressing cells generate a net NADH flux by the NADH/NADPH transhydrogenase while the VHb(-) cells yield a net NADPH flux under the same growth conditions. Flux distribution analysis also reveals that VHb(+) cells have a smaller adenosine triphosphate (ATP) synthesis rate from substrate-level phosphorylation but a larger overall ATP production rate under microaerobic conditions. The thermodynamic efficiency of growth, based on reducing equivalents generated per unit of biomass produced, is greater for VHb(+) cells. (c) 1996 John Wiley & Sons, Inc.     

Enhancement of cellulose pellicle production by constitutively expressing vitreoscilla hemoglobin in Acetobacter xylinum

Vitreoscilla hemoglobin (VHb) gene driven by the constitutive bla promoter was expressed in the cellulose-producing Acetobacter xylinum. The expressed VHb was biochemically active and could enhance cell growth in a shaken culture containing cellulase. VHb-expressing A. xylinum (VHb+) exhibited a specific growth rate 50% higher than that of the host strain (VHb-). Probably because of its faster growth rate, the size of tentacled cellulose beads produced by VHb+ was about 20% of that produced by VHb- after 2 days cultivation in a shake-flask. When cultured statically, the amount of cellulose pellicle produced by VHb+ could be 2-fold that produced by VHb-. Cellulose pellicle concentration of 11 g/L was obtained for VHb+, whereas 6 g/L was obtained for VHb- after 6 days of microaerobic incubation.     

Intracellular expression of Vitreoscilla hemoglobin modifies microaerobic Escherichia coli metabolism through elevated concentration and specific activity of cytochrome o

The function of the reversible oxygen-binding hemoprotein from Vitreoscilla (VHb), which enhances oxygen-limited cell growth and recombinant protein production when functionally expressed in Escherichia coli, was investigated in wild-type E. coli and in E. coli mutants lacking one of the two terminal oxidases, cytochrome o complex (aerobic terminal oxidase, Cyo) or cytochrome d complex (microaerobic terminal oxidase, Cyd). Deconvolution of VHb, cytochrome o, and cytochrome d bands from in vivo absorption spectra revealed a 5-fold enhancement in cytochrome o content and a 1.5-fold increment in cytochrome d by VHb under microaerobic environments (dissolved oxygen less than 2% air saturation). Based upon oxygen uptake kinetics measurements of these mutants, the apparent oxygen affinity of the Cyo(+), Cyd(-) E. coli was increased in the presence of VHb, but no difference in the apparent K(m) was observed for the Cyo(-), Cyd(+) strain. Results suggest that the expression of VHb in E. coli increases the level and activity of terminal oxidases and thereby improves the efficiency of microaerobic respiration and growth.     

High-efficiency generation of monoclonal antibody for Vitreoscilla hemoglobin protein

Bacterial hemoglobin from Vitreoscilla (VHb) is recognized as a good fusion protein for the soluble expression of foreign protein. In this study, we generated a monoclonal antibody (MAb) against VHb for its detection. For the rapid screening of MAb, a protein chip technology based on the Alexa-488 (A488) dye labeling method was introduced. In order to fabricate the chip, the VHb protein was chemically coupled to the chip surface and then the culture supernatants of 84 hybridoma cell lines were spotted onto the VHb chip. The bound MAbs were measured by A488- modified anti-mouse IgG. A single spot (MAb A10) exhibited significantly high signal intensity. The immunoblot analysis evidenced that the MAb A10 can detect VHb-fused proteins with high specificity.     

透明颤菌血红蛋白的分离纯化与分析检测

透明颤菌血红蛋白(Vitreoscillahemoglobin,VHb)是惟一一种研究得较为透彻的原核生物氧结合蛋白血红蛋白。它支持细胞在微氧条件下进行好氧生长,克服发酵过程中的溶氧限制,因此在需氧微生物发酵工业中具有重要的应用价值。简述了VHb的分离纯化过程,综述了VHb的各种定性检测和定量分析方法,比较了各种检测分析方法的优缺点和适用性。提出利用改进的一氧化碳差光谱法以全细胞悬浮液为对象直接进行VHb的定量分析是发酵工业中应用VHb重组菌株的研究发展方向 。     

透明颤菌血红蛋白的研究进展及其在发酵工业中的应用

透明颤菌血红蛋白（Vitreoscilla Hemoglobin, VHb）是20世纪70年代后期发现的一种血红蛋白,该蛋白质能使透明颤菌在低氧的环境下生存,并保持较高的生长速率。随着其作用机理的深入研究,VHb在生物工程领域的应用越来越广泛。本文总结了近年来VHb的研究进展,包括蛋白结构、细胞定位、基因改组、作用机理等方面的研究,并概述了其在微生物发酵工业中的应用。     

毕赤酵母中表达透明颤菌血红蛋白提高重组脂肪酶的表达

解脂耶氏酵母胞外脂肪酶Lip2(YlLip2)是一种具有广泛应用前景的工业酶.为了改善高密度发酵生产Y1Lip2过程中的溶氧限制,提高Y1Lip2的表达量,将YlLip2基因lip2和透明颤菌血红蛋白(VHb)基因vgb分别置于AOXl启动子和PsADH2启动子的调控之下,进行YlLip2和VHb在毕赤酵母中的共表达.PsADH2启动子来源于树干毕赤酵母Pichia stipitis,在低氧条件下能被激活.SDS-PAGE和CO-差式光谱分析表明,Y1Lip2和VHb在重组菌中成功实现了共表达.在氧限制性条件下,VHb表达的细胞(VHb+,GS 115/9Klip2-pZPVT)与对照细胞(VHb-,GS 115/9Klip2)相比,摇瓶和10 L发酵罐中YlLip2表达量分别提高了25％和83％.此外,在低氧条件下,VHb+细胞在10 L发酵罐中的生物量也比VHb-细胞高.文中也获得了一株表达了VHb的并携带有多个lip2基因拷贝的克隆子GS 115/9Klip2-pZP VTlip2 49#,在低氧条件下,该克隆子在10L发酵罐中的最高脂肪酶水解活力达33 900 U/mL.因此,在毕赤酵母中用PsADH2启动子表达VHb,同时增加lip2基因的拷贝数是提高YlLip2表达量的一种有效策略.     

Nitrite inhibition of Vitreoscilla hemoglobin (VHb) in recombinant E. coli: direct evidence that VHb enhances recombinant protein production

Bacteria engineered with the gene (vgb) encoding Vitreoscilla hemoglobin (VHb) typically produce more protein than unengineered cells, and it has generally been assumed that VHb is responsible for this effect. Here, using matched strains of E. coli that bear a recombinant alpha-amylase gene (MK57) or the alpha-amylase gene and vgb (MK79), we provide evidence supporting this assumption. Sodium nitrite (which is known to inhibit heme proteins) was tested over a range of concentrations regarding effects on growth, alpha-amylase production, respiration, and VHb function in MK57 and MK79. Nitrite concentrations were identified at which respiration of cell membranes was inhibited only slightly and to approximately equal degrees in both strains, while whole cell respiration was inhibited to a greater extent and about twice as much in MK79 as MK57. This suggests that these concentrations inhibit VHb while having a much smaller effect on cytochrome oxidase. Direct measurements of VHb showed, in fact, that the same nitrite concentrations greatly decreased the levels of active (ferrous) and, to a somewhat lesser extent, total (ferrous plus ferric) VHb in MK79. Finally, these same nitrite concentrations reversed the advantage regarding alpha-amylase production of MK79 over MK57 seen at 0 mM nitrite, linking the presence of active VHb with the increase in alpha-amylase production.