Effects of culture conditions on enhancement of 2,4-dinitrotoluene degradation by Burkholderia engineered with the Vitreoscilla hemoglobin gene

Nicotiana tabacum-associated bioengineered Pseudomonas putida can enhance rhizoremediation of soil containing 2,4-dinitrotoluene

Rhizoremediation processes are based on plant-bacteria interactions and can be effectively used for cleaning many pollutants from the environment to overcome the constraints of individual phytoremediation. Here, 1 mM and 1.5 mM concentrations of 2,4-dinitrotoluene (2,4-DNT) degrading Pseudomonas putida (P. putida) strain KT.DNT and various growth stages of Nicotiana tabacum (N. tabacum) were initially assayed in in vitro tissue culture system and the best conditions for the association of plant-rhizobacterium were ascertained to remediation of the soil contaminated with 2,4-DNT. 5-days old N. tabacum plants inoculated with 2 × 106 cfu/mL bacterial inoculum for 3 weeks were preferred for rhizoremediation experiments as they showed a nearly threefold increase in the fresh and dry biomass in comparison to noninoculated ones. When these seedlings were planted either alone or together with P. putida KT2440 or P. putida KT.DNT in soils contaminated with 1 mM and 1.5 mM of 2,4-DNT, the maximum degradation rate of 98% and ~ 93% were determined at the end of 14 days by KT.DNT inoculated tobacco plants. Our results indicate that it would be advantageous to use the 2,4-DNT-degrading bacterium inoculated with N. tabacum plants to accelerate and enhance the cleanup of soil contaminated with 2,4-DNT.

Recent applications of Vitreoscilla hemoglobin technology in bioproduct synthesis and bioremediation

Since its first use in 1990 to enhance production of α-amylase in E. coli, engineering of heterologous hosts to express the hemoglobin from the bacterium Vitreoscilla (VHb) has become a widely used strategy to enhance production of a variety of bioproducts, stimulate bioremediation, and increase growth and survival of engineered organisms. The hosts have included a variety of bacteria, yeast, fungi, higher plants, and even animals. The beneficial effects of VHb expression are presumably the result of one or more of its activities. The available evidence indicates that these include oxygen binding and delivery to the respiratory chain and oxygenases, protection against reactive oxygen species, and control of gene expression. In the past 4 to 5 years, the use of this "VHb technology" has continued in a variety of biotechnological applications in a wide range of organisms. These include enhancement of production of an ever wider array of bioproducts, new applications in bioremediation, a possible role in enhancing aerobic waste water treatment, and the potential to enhance growth and survival of both plants and animals of economic importance.

The Biochemistry of Vitreoscilla hemoglobin

The hemoglobin (VHb) from Vitreoscilla was the first bacterial hemoglobin discovered. Its structure and function have been extensively investigated, and engineering of a wide variety of heterologous organisms to express VHb has been performed to increase their growth and productivity. This strategy has shown promise in applications as far-ranging as the production of antibiotics and petrochemical replacements by microorganisms to increasing stress tolerance in plants. These applications of “VHb technology” have generally been of the “black box” variety, wherein the endpoint studied is an increase in the levels of a certain product or improved growth and survival. Their eventual optimization, however, will require a thorough understanding of the various functions and activities of VHb, and how VHb expression ripples to affect metabolism more generally. Here we review the current knowledge of these topics. VHb's functions all involve oxygen binding (and often delivery) in one way or another. Several biochemical and structure-function studies have provided an insight into the molecular details of this binding and delivery. VHb activities are varied. They include supply of oxygen to oxygenases and the respiratory chain, particularly under low oxygen conditions; oxygen sensing and modulation of transcription factor activity; and detoxification of NO, and seem to require interactions of VHb with “partner proteins”. VHb expression affects the levels of ATP and NADH, although not enormously. VHb expression may affect the level of many compounds of intermediary metabolism, and, apparently, alters the levels of expression of many genes. Thus, the metabolic changes in organisms engineered to express VHb are likely to be numerous and complicated.

Vitreoscilla hemoglobin (VHb) overexpression increases hypoxia tolerance in zebrafish (Danio rerio)

Aquaculture farming may benefit from genetically engineering fish to tolerate environmental stress. Here, we used the vector pCVCG expressing the Vitreoscilla hemoglobin (vhb) gene driven by the common carp β-actin promoter to create stable transgenic zebrafish. The survival rate of the 7-day-old F(2) transgenic fish was significantly greater than that of the sibling controls under 2.5% O(2) (dissolved oxygen (DO), 0.91 mg/l). Meanwhile, we investigated the relative expression levels of several marker genes (hypoxia-inducible factor alpha 1, heat shock cognate 70-kDa protein, erythropoietin, beta and alpha globin genes, lactate dehydrogenase, catalase, superoxide dismutase, and glutathione peroxidase) of transgenic fish and siblings after hypoxia exposure for 156 h. The expression profiles of the vhb transgenic zebrafish revealed that VHb could partially alleviate the hypoxia stress response to improve the survival rate of the fish. These results suggest that that vhb gene may be an efficient candidate for genetically modifying hypoxia tolerance in fish.

Use of Genetically Engineered Microorganisms (GEMs) for the Bioremediation of Contaminants

This paper presents a critical review of the literature on the application of genetically engineered microorganisms (GEMs) in bioremediation. The important aspects of using GEMs in bioremediation, such as development of novel strains with desirable properties through pathway construction and the modification of enzyme specificity and affinity, are discussed in detail. Particular attention is given to the genetic engineering of bacteria using bacterial hemoglobin (VHb) for the treatment of aromatic organic compounds under hypoxic conditions. The application of VHb technology may advance treatment of contaminated sites, where oxygen availability limits the growth of aerobic bioremediating bacteria, as well as the functioning of oxygenases required for mineralization of many organic pollutants. Despite the many advantages of GEMs, there are still concerns that their introduction into polluted sites to enhance bioremediation may have adverse environmental effects, such as gene transfer. The extent of horizontal gene transfer from GEMs in the environment, compared to that of native organisms including benefits regarding bacterial bioremediation that may occur as a result of such transfer, is discussed. Recent advances in tracking methods and containment strategies for GEMs, including several biological systems that have been developed to detect the fate of GEMs in the environment, are also summarized in this review. Critical research questions pertaining to the development and implementation of GEMs for enhanced bioremediation have been identified and posed for possible future research.

Recent developments and future prospects of Vitreoscilla hemoglobin application in metabolic engineering

In hypoxic conditions, bacteria express a kind of hemoglobin, which is proposed to enhance respiration and energy metabolism by promoting oxygen delivery. Bacteria hemoglobin from Vitreoscilla stercoraria - Vitreoscilla hemoglobin (VHb), when expressed in various hosts in oxygen-limited conditions, has been shown to improve growth, protein secretion, metabolite productivity and stress resistance of hosts, thus rendering the protein promising in metabolic engineering, especially in plant metabolism optimization. In this review, many well-studies areas are presented to illustrate the potential of VHb application in biotechnology industry, to discuss the cellular mechanisms of VHb function and to show the wide variety of approaches taken within the field.

Comparison of 2-chlorobenzoic acid biodegradation in a membrane bioreactor by B. cepacia and B. cepacia bearing the bacterial hemoglobin gene

Degradation of 2-chlorobenzoic acid (2-CBA), a model recalcitrant chlorinated organic compound, by pure cultures of Burkholderia cepacia strain DNT with (transformed B. cepacia) and without (untransformed B. cepacia) the bacterial hemoglobin (Vitreoscilla hemoglobin, VHb) gene, vgb, was investigated in parallel membrane bioreactors (MBRs). This was done aseptically to prevent contamination during the operation of the MBRs. The objective was to determine whether the degradation of 2-CBA by cometabolism, using acetate as a primary carbon source, under hypoxic conditions might be enhanced for vgb-bearing cells in MBRs. The 2-CBA removal efficiency of transformed B. cepacia (97-99%) was slightly higher than that of untransformed B. cepacia (95-99%) at all stages. The average amount of chloride released from 2-CBA by transformed cells was also higher than for untransformed cells, 92-96% compared to 64-84% of the maximum theoretical amount, the exact value depending on the operating conditions. These results indicate that 2-CBA degradation/transformation is not accompanied by the stoichiometric release of chloride for the untransformed strain. The difference between percentages of 2-CBA removal and chloride release by untransformed cells was attributed to persistence, under hypoxic conditions, of the 2-CBA chlorine atom in 2-CBA metabolites. Growth of transformed cells was also significantly enhanced under hypoxic conditions compared to untransformed cells. For varying media compositions, the transformed cells reached higher cell densities (3.2-5.4 g/L) relative to untransformed cells (2.8-4.7 g/L) at food to microorganism ratios ranging from 0.44-0.59 to 0.38-0.49 g COD/g biomass-d The observed yields thus ranged from 0.16-0.20 and 0.15-0.18 g TSS/g COD for untransformed and transformed cells, respectively. The value of the yield depended on medium composition. The MBR system using vgb-containing B. cepacia maintained a high biomass concentration without oxygen limitations and provided cell-free effluent. Hence, it may be useful for treating high volumes of water contaminated with low levels of recalcitrant organics.

Correlation between bacterial hemoglobin and carbon sources: their effect on copper uptake by transformed E. coli strain alpha DH5

Escherichia coli alphaDH5 harboring Vitreoscilla hemoglobin gene, vgb (Escherichia:pUC8:16), and control strains (parental and vgb-lacking transformed strains, E. coli:pUC9) were employed for studying the potential ability of copper uptake. The strains were grown on a minimal medium, 5XM9, that contained different carbon (mannitol, fructose, lactose, and maltose) and nitrogen (casein and yeast extract) sources. A clear type-response relationship between the level of copper uptake and the type of carbon and nitrogen sources was observed. Copper uptake ability was better for vgb-bearing cells grown on either mannitol, lactose, fructose, or maltose as carbon source and casein as well as yeast extract as nitrogen source compared with the control medium. The increase in copper uptake was in the following order: parental cells, then pUC9-bearing cells, then VHb-expressing cells.

Enhanced production of acetoin and butanediol in recombinant Enterobacter aerogenes carrying Vitreoscilla hemoglobin gene

Microbial production of butanediol and acetoin has received increasing interest because of their diverse potential practical uses. Although both products are fermentative in nature, their optimal production requires a low level of oxygen. In this study, the use of a recombinant oxygen uptake system on production of these metabolites was investigated. Enterobacter aerogenes was transformed with a pUC8-based plasmid carrying the gene (vgb) encoding Vitreoscilla (bacterial)hemoglobin (VHb). The presence of vgb and production of VHb by this strain resulted in an increase in viability from 72 to 96 h in culture, but no overall increase in cell mass. Accumulation of the fermentation products acetoin and butanediol were enhanced (up to 83%) by the presence of vgb/VHb. This vgb/VHb related effect appears to be due to an increase of flux through the acetoin/butanediol pathway, but not at the expense of acid production.

Improvement of bioremediation by Pseudomonas and Burkholderia by mutants of the Vitreoscilla hemoglobin gene (vgb) integrated into their chromosomes

Using genetic engineering, the Vitreoscilla (bacterial) hemoglobin gene (vgb) was integrated stably into the chromosomes of Pseudomonas aeruginosa and Burkholderia sp. strain DNT. This was done for both wild type vgb and two site-directed mutants of vgb that produce Vitreoscilla hemoglobin (VHb) with lowered oxygen affinities; in all cases functional VHb was expressed. Similar to previous results, the wild type VHb improved growth for both species and degradation of 2,4-dinitrotoluene (Burkholderia sp.) or benzoic acid (P. aeruginosa) under both normal and low aeration conditions. Both mutant vgbs enhanced these parameters compared to wild type vgb, and the improvement was seen in both species. The enhancements were generally greater at low aeration than at normal aeration. The results demonstrate the possibility that the positive effects provided by VHb may be augmented by protein engineering.

Structure–function studies of the Vitreoscilla hemoglobin D-region

The D-region connecting helices C and E of Vitreoscilla hemoglobin (VHb) appears disordered in the crystal structure. Six site-directed mutants in this region were made to investigate its possible functions. The mutant VHb's were analyzed using UV-visible and FTIR spectroscopy, using primarily the CO liganded forms, and their heme/protein ratios were determined. The results implicate Asp44, Arg47, and Glu49 as especially important in heme-globin interactions and ligand binding, and enabled construction of a model in which the D-region forms a loop that protrudes upward over the heme. Interactions between VHb (wild type and the D-region mutants) with the flavin domain of 2,4-DNT dioxygenase from Burkholderia were tested using bacterial two-hybrid screening. There was a correlation between the extent of the D-loop perturbation predicted for each mutant and the amount of the reduction in VHb-flavin domain interaction, suggesting that this region may be more generally involved in binding of VHb to flavoproteins.

Enhanced kinetics of genetically engineeredBurkholderia cepacia: the role ofvgb in the hypoxic metabolism of 2-CBA

Application of Vitreoscilla hemoglobin (VHb) technology to 2-CBA degradation by Burkholderia cepacia strain DNT under hypoxic conditions was studied in continuous culture chemostats. Dechlorination abilities of both recombinant (VHb gene (vgb) containing) and untransformed cells were investigated at various dilution rates to ensure complete degradation of 2-CBA. As the dilution rate increased from 0.025 to 0.25 h(-1), the ratios of chloride release to degraded 2-CBA concentration decreased from 0.95 to 0.72 and from 0.89 to 0.39 for recombinant and untransformed cells, respectively. A nonstoichiometric relationship between chloride release and 2-CBA degradation was more pronounced for untransformed cells. Recombinant cell densities were 0.1-0.2. g L(-1) greater than untransformed cell densities for a range of dilution rates. As the dilution rate increased, the oxygen uptake rate (OUR) and the substrate utilization rate (SUR) decreased for both strains. The OUR/SUR ratio increased as the dilution rate increased for both strains but was much higher for the recombinant strain compared to untransformed cells. The specific 2-CBA degradation rate of recombinant cells was greater than that of untransformed cells (1.17 vs. 0.46 mg CBA (mg) day(-1), and half-saturation constants for recombinant cells were lower than those of untransformed cells (0.18 and 0.32 mg CBA L(-1), respectively). The pseudo-first-order degradation constants, k(1CBA) and k(1ACE), were higher for recombinant cells (6.5 L (mg cells)(-1) day(-1) and 95.6 L (mg cells)(-1) day(-1), respectively) than those of untransformed cells (1.44 L (mg cells)(-1) day(-1) and 73.7 L (mg cells)(-1) day(-1), respectively).

Bacterial hemoglobins and flavohemoglobins: versatile proteins and their impact on microbiology and biotechnology

In response to oxygen limitation or oxidative and nitrosative stress, bacteria express three kinds of hemoglobin proteins: truncated hemoglobins (tr Hbs), hemoglobins (Hbs) and flavohemoglobins (flavo Hbs). The two latter groups share a high sequence homology and structural similarity in their globin domain. Flavohemoglobin proteins contain an additional reductase domain at their C-terminus and their expression is induced in the presence of reactive nitrogen and oxygen species. Flavohemoglobins detoxify NO in an aerobic process, termed nitric oxide dioxygenase reaction, which protects the host from various noxious nitrogen compounds. Only a small number of bacteria express hemoglobin proteins and the best studied of these is from Vitreoscilla sp. Vitreoscilla hemoglobin (VHb) has been expressed in various heterologous hosts under oxygen-limited conditions and has been shown to improve growth and productivity, rendering the protein interesting for biotechnology industry. The close interaction of VHb with the terminal oxidases has been shown and this interplay has been proposed to enhance respiratory activity and energy production by delivering oxygen, the ultimate result being an improvement in growth properties.

Correlation between bacterial haemoglobin gene (vgb) and aeration: their effect on the growth and alpha-amylase activity in transformed Enterobacter aerogenes

AIMS

To evaluate the effects of bacterial haemoglobin on bacterial growth and alpha-amylase formation under different aeration conditions.

METHODS AND RESULTS

Enterobacter aerogenes was transformed with the gene encoding Vitreoscilla (bacterial) haemoglobin, vgb. The growth kinetics and ability to synthesize alpha-amylase enzyme were investigated in this transformed Enterobacter strain as well as in two other Enterobacter control strains that do not harbour the vgb gene. Such comparison was made under variable aeration conditions, using the agitation rate as a measure of aeration. The expression of bacterial haemoglobin-supported cell growth determined as O.D.600 and cell viability in addition to the alpha-amylase production. These positive effects of bacterial haemoglobin were observed under both low and high aerations, but at different extents.

CONCLUSIONS

In addition to improving cell growth under low aeration, the bacterial haemoglobin is able to promote bacterial cell tolerance during exposure to high oxygen tension.

SIGNIFICANCE AND IMPACT OF THE STUDY

The expression of bacterial haemoglobin is advantageous in reducing the burden of certain toxic conditions such as high oxygen levels. It may have the same impact on some environmental toxic substances. This, haemoglobin biotechnology can be extended to induce enzymes of pollutants degradation or production of some useful industrial substances.