Heterologous Expression and Maturation of an NADP-Dependent [NiFe]-Hydrogenase: A Key Enzyme in Biofuel Production

Sun, Junsong; Hopkins, Robin; Jenney, Francis E.; McTernan, Patrick M.; Adams, Michael W. W.

doi:10.1371/journal.pone.0010526

Cited by 84 publications

(66 citation statements)

References 39 publications

(43 reference statements)

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“…Studying the pathways of hydrogen production in P. furiosus is of great interest because of the increasing concern for production of alternative energy sources, such as hydrogen, to replace fossil fuels. Hyperthermophiles such as P. furiosus could potentially have an important role in biological hydrogen production systems (15,42), and although the cytoplasmic hydrogenases have been characterized in vitro (21,22), as demonstrated herein, their in vivo functions have yet to be established. We anticipate that the ability to investigate their functions in vivo through genetic manipulation, together with the roles of related enzymes, will provide insight into the mechanisms of hydrogen uptake and production in P. furiosus as well as in related hyperthermophiles.…”

Section: Discussionmentioning

confidence: 90%

Natural Competence in the Hyperthermophilic ArchaeonPyrococcus furiosusFacilitates Genetic Manipulation: Construction of Markerless Deletions of Genes Encoding the Two Cytoplasmic Hydrogenases

Lipscomb

Stirrett

Schut

et al. 2011

Appl Environ Microbiol

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In attempts to develop a method of introducing DNA into Pyrococcus furiosus, we discovered a variant within the wild-type population that is naturally and efficiently competent for DNA uptake. A pyrF gene deletion mutant was constructed in the genome, and the combined transformation and recombination frequencies of this strain allowed marker replacement by direct selection using linear DNA. We have demonstrated the use of this strain, designated COM1, for genetic manipulation. Using genetic selections and counterselections based on uracil biosynthesis, we generated single-and double-deletion mutants of the two gene clusters that encode the two cytoplasmic hydrogenases. The COM1 strain will provide the basis for the development of more sophisticated genetic tools allowing the study and metabolic engineering of this important hyperthermophile.It would be difficult to overestimate the contribution of genetic manipulation to the study of any biological system, and it is an essential tool for the metabolic engineering of biosynthetic and substrate utilization pathways. This is particularly true for the archaea since, in spite of their environmental and industrial importance, coupled with their unique molecular features, much remains to be learned about their biology (2). The marine hyperthermophilic anaerobe Pyrococcus furiosus is of special interest not only for its ability to grow optimally at 100°C and the implications of this trait for its biology but also for industrial applications of its enzymes, as well as its capacity to produce hydrogen efficiently (4, 13, 44). The ability to apply genetic analyses of P. furiosus to underpin existing biochemical and molecular studies will contribute greatly to the establishment of P. furiosus as a model organism, particularly for biological hydrogen production.The development of genetic systems in the archaea, in general, presents many unique challenges given the extreme growth requirements of many of these organisms. To date, genetic systems of various levels of sophistication have been developed for representatives of all major groups of archaea, including halophiles, methanogens, thermoacidophiles, and hyperthermophiles (2,6,30,40,43,46). A variety of transformation methods are being used, including electroporation, heat shock with or without CaCl 2 treatment, phage-mediated transduction, spheroplast transformation, liposomes, and, very recently, even conjugation with Escherichia coli (2, 12). Transformation via natural competence has been reported in three archaeal species, in comparison to over 60 bacterial species that are known to exhibit this trait (16,36). Two of them are the methanogens Methanococcus voltae PS (7, 27) and Methanobacterium thermoautotrophicum Marburg (47); however, transformation frequencies were low, and there have been no follow-up studies regarding natural competence. The other is the hyperthermophile Thermococcus kodakarensis, which has an optimal growth temperature of 85°C. Its natural competence has enabled the development of genetic tools fo...

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Section: Discussionmentioning

confidence: 90%

Natural Competence in the Hyperthermophilic ArchaeonPyrococcus furiosusFacilitates Genetic Manipulation: Construction of Markerless Deletions of Genes Encoding the Two Cytoplasmic Hydrogenases

Lipscomb

Stirrett

Schut

et al. 2011

Appl Environ Microbiol

Self Cite

160

251

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“…It is not clear whether the hypCABDFE genes are essential. Recently, an active [NiFe] hydrogenase from P. furiosus was expressed in E. coli when only the structural genes and the protease were expressed (Sun et al, 2010). Because these experiments were performed under anaerobic conditions, it is likely that accessory proteins from E. coli assisted the maturation of the heterologous hydrogenase.…”

Section: Discussionmentioning

confidence: 99%

“…For example, expression of the Thiocapsa roseopersicina hynSL genes in E. coli failed to yield an active hydrogenase (Shirshikova et al, 2009). Recently, however, an active NADP-dependent [NiFe] hydrogenase from Pyrococcus furiosus was expressed in E. coli and required expression of only an additional protease for activity (Sun et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

Heterologous expression of Alteromonas macleodii and Thiocapsa roseopersicina [NiFe] hydrogenases in Escherichia coli

et al. 2011

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HynSL from Alteromonas macleodii 'deep ecotype' (AltDE) is an oxygen-tolerant and thermostable [NiFe] hydrogenase. Its two structural genes (hynSL), encoding small and large hydrogenase subunits, are surrounded by eight genes (hynD, hupH and hypCABDFE ) predicted to encode accessory proteins involved in maturation of the hydrogenase. A 13 kb fragment containing the ten structural and accessory genes along with three additional adjacent genes (orf2, cyt and orf1) was cloned into an IPTG-inducible expression vector and transferred into an Escherichia coli mutant strain lacking its native hydrogenases. Upon induction, HynSL from AltDE was expressed in E. coli and was active, as determined by an in vitro hydrogen evolution assay. Subsequent genetic analysis revealed that orf2, cyt, orf1 and hupH are not essential for assembling an active hydrogenase. However, hupH and orf2 can enhance the activity of the heterologously expressed hydrogenase. We used this genetic system to compare maturation mechanisms between AltDE HynSL and its Thiocapsa roseopersicina homologue. When the structural genes for the T. roseopersicina hydrogenase, hynSL, were expressed along with known T. roseopersicina accessory genes (hynD, hupK, hypC1C2 and hypDEF ), no active hydrogenase was produced. Further, co-expression of AltDE accessory genes hypA and hypB with the entire set of the T. roseopersicina genes did not produce an active hydrogenase. However, co-expression of all AltDE accessory genes with the T. roseopersicina structural genes generated an active T. roseopersicina hydrogenase. This result demonstrates that the accessory genes from AltDE can complement their counterparts from T. roseopersicina and that the two hydrogenases share similar maturation mechanisms.

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“…4-Hydroxybutyrate-CoA ligase (Msed_0406) was cloned into pET46-Ek/LIC with an N-terminal His 6 tag as described previously (9). 4-Hydroxybutyryl-CoA dehydratase (Msed_1321) was cloned with an N-terminal His 6 tag into a modified pETA vector into which the anaerobic hya promoter from Escherichia coli had been inserted to allow for anaerobically regulated expression (10). Crotonyl-CoA hydratase/(S)-3-hydroxybutyryl-CoA dehydrogenase (Msed_0399) was cloned into pET21b without a His tag, and ␤-ketothiolase (Msed_0656) was cloned into pCDF-Ek/LIC with an N-terminal His 6 tag.…”

Section: Methodsmentioning

confidence: 99%

Conversion of 4-Hydroxybutyrate to Acetyl Coenzyme A and Its Anapleurosis in the Metallosphaera sedula 3-Hydroxypropionate/4-Hydroxybutyrate Carbon Fixation Pathway

Hawkins

Adams

Kelly

2014

Appl Environ Microbiol

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The extremely thermoacidophilic archaeon Metallosphaera sedula (optimum growth temperature, 73°C, pH 2.0) grows chemolithoautotrophically on metal sulfides or molecular hydrogen by employing the 3-hydroxypropionate/4-hydroxybutyrate (3HP/ 4HB) carbon fixation cycle. This cycle adds two CO 2 molecules to acetyl coenzyme A (acetyl-CoA) to generate 4HB, which is then rearranged and cleaved to form two acetyl-CoA molecules. Previous metabolic flux analysis showed that two-thirds of central carbon precursor molecules are derived from succinyl-CoA, which is oxidized to malate and oxaloacetate. The remaining onethird is apparently derived from acetyl-CoA. As such, the steps beyond succinyl-CoA are essential for completing the carbon fixation cycle and for anapleurosis of acetyl-CoA. Here, the final four enzymes of the 3HP/4HB cycle, 4-hydroxybutyrate-CoA ligase (AMP forming) (Msed_0406), 4-hydroxybutyryl-CoA dehydratase (Msed_1321), crotonyl-CoA hydratase/(S)-3-hydroxybutyrylCoA dehydrogenase (Msed_0399), and acetoacetyl-CoA ␤-ketothiolase (Msed_0656), were produced recombinantly in Escherichia coli, combined in vitro, and shown to convert 4HB to acetyl-CoA. Metabolic pathways connecting CO 2 fixation and central metabolism were examined using a gas-intensive bioreactor system in which M. sedula was grown under autotrophic (CO 2 -limited) and heterotrophic conditions. Transcriptomic analysis revealed the importance of the 3HP/4HB pathway in supplying acetyl-CoA to anabolic pathways generating intermediates in M. sedula metabolism. The results indicated that flux between the succinate and acetyl-CoA branches in the 3HP/4HB pathway is governed by 4-hydroxybutyrate-CoA ligase, possibly regulated posttranslationally by the protein acetyltransferase (Pat)/Sir2-dependent system. Taken together, this work confirms the final four steps of the 3HP/4HB pathway, thereby providing the framework for examining connections between CO 2 fixation and central metabolism in M. sedula. Metallosphaera sedula is an extremely thermoacidophilic archaeon (optimum growth temperature, 73°C, and optimum pH, 2.0) that grows heterotrophically on peptides and chemolithoautotrophically on metal sulfides or hydrogen gas (1). For chemolithotrophic growth, it uses a unique carbon fixation pathway known as the 3-hydroxypropionate/4-hydroxybutyrate (3HP/4HB) cycle (2), so far found only in members of the order Sulfolobales. This cycle is one of two such cycles found exclusively in thermophilic archaea, the other being the dicarboxylate/4-hydroxybutyrate (DC/4HB) cycle present in the orders Desulfurococcales and Thermoproteales (3-5). In the first part of the 3HP/4HB cycle, acetyl coenzyme A (CoA) (C 2 ) is converted into succinylCoA (C 4 ) by two successive carboxylation steps (5-7). In the second half of this cycle, succinyl-CoA is then converted to 4HB, which is rearranged and cleaved to produce two molecules of acetyl-CoA. Both the 3HP/4HB and DC/4HB cycles use the same set of enzymes to convert succinyl-CoA to acetyl-CoA. However, the enzymes used in ...

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Heterologous Expression and Maturation of an NADP-Dependent [NiFe]-Hydrogenase: A Key Enzyme in Biofuel Production

Cited by 84 publications

References 39 publications

Natural Competence in the Hyperthermophilic ArchaeonPyrococcus furiosusFacilitates Genetic Manipulation: Construction of Markerless Deletions of Genes Encoding the Two Cytoplasmic Hydrogenases

Natural Competence in the Hyperthermophilic ArchaeonPyrococcus furiosusFacilitates Genetic Manipulation: Construction of Markerless Deletions of Genes Encoding the Two Cytoplasmic Hydrogenases

Heterologous expression of Alteromonas macleodii and Thiocapsa roseopersicina [NiFe] hydrogenases in Escherichia coli

Conversion of 4-Hydroxybutyrate to Acetyl Coenzyme A and Its Anapleurosis in the Metallosphaera sedula 3-Hydroxypropionate/4-Hydroxybutyrate Carbon Fixation Pathway

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