scholarly journals Application of Functional Genomics to Pathway Optimization for Increased Isoprenoid Production

2008 ◽  
Vol 74 (10) ◽  
pp. 3229-3241 ◽  
Author(s):  
Lance Kizer ◽  
Douglas J. Pitera ◽  
Brian F. Pfleger ◽  
Jay D. Keasling
Keyword(s):  
Biosynthetic Pathway ◽  
Fatty Acid Biosynthesis ◽  
Cell Metabolism ◽  
Genomic Analysis ◽  
Acid Biosynthesis ◽  
Cytotoxic Effects ◽  
E Coli ◽  
Pathway Optimization ◽  
Functional Genomic Analysis ◽  
Microbial Host

ABSTRACT Producing complex chemicals using synthetic metabolic pathways in microbial hosts can have many advantages over chemical synthesis but is often complicated by deleterious interactions between pathway intermediates and the host cell metabolism. With the maturation of functional genomic analysis, it is now technically feasible to identify modes of toxicity associated with the accumulation of foreign molecules in the engineered bacterium. Previously, Escherichia coli was engineered to produce large quantities of isoprenoids by creating a mevalonate-based isopentenyl pyrophosphate biosynthetic pathway (V. J. J. Martin et al., Nat. Biotechnol. 21:796-802, 2003). The engineered E. coli strain produced high levels of isoprenoids, but further optimization led to an imbalance in carbon flux and the accumulation of the pathway intermediate 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA), which proved to be cytotoxic to E. coli. Using both DNA microarray analysis and targeted metabolite profiling, we have studied E. coli strains inhibited by the intracellular accumulation of HMG-CoA. Our results indicate that HMG-CoA inhibits fatty acid biosynthesis in the microbial host, leading to generalized membrane stress. The cytotoxic effects of HMG-CoA accumulation can be counteracted by the addition of palmitic acid (16:0) and, to a lesser extent, oleic acid (cis-Δ9-18:1) in the growth medium. This work demonstrates the utility of using transcriptomic and metabolomic methods to optimize synthetic biological systems.

Functional genomic analysis of phagocytosis and identification of a Drosophila receptor for E. coli

Nature ◽  
2002 ◽  
Vol 416 (6881) ◽  
pp. 644-648 ◽  
Author(s):  
Mika Rämet ◽  
Pascal Manfruelli ◽  
Alan Pearson ◽  
Bernard Mathey-Prevot ◽  
R. Alan B. Ezekowitz
Keyword(s):  
Genomic Analysis ◽  
Functional Genomic ◽  
E Coli ◽  
Functional Genomic Analysis

scholarly journals β-Ketoacyl-Acyl Carrier Protein Synthase III (FabH) Is a Determining Factor in Branched-Chain Fatty Acid Biosynthesis

2000 ◽  
Vol 182 (2) ◽  
pp. 365-370 ◽  
Author(s):  
Keum-Hwa Choi ◽  
Richard J. Heath ◽  
Charles O. Rock
Keyword(s):  
Fatty Acid ◽  
Fatty Acid Synthase ◽  
Fatty Acid Biosynthesis ◽  
Acyl Carrier Protein ◽  
Chain Fatty Acid ◽  
Carrier Protein ◽  
Acid Biosynthesis ◽  
Biochemical Basis ◽  
E Coli ◽  
Branched Chain

ABSTRACT A universal set of genes encodes the components of the dissociated, type II, fatty acid synthase system that is responsible for producing the multitude of fatty acid structures found in bacterial membranes. We examined the biochemical basis for the production of branched-chain fatty acids by gram-positive bacteria. Two genes that were predicted to encode homologs of the β-ketoacyl-acyl carrier protein synthase III of Escherichia coli (eFabH) were identified in theBacillus subtilis genome. Their protein products were expressed, purified, and biochemically characterized. Both B. subtilis FabH homologs, bFabH1 and bFabH2, carried out the initial condensation reaction of fatty acid biosynthesis with acetyl-coenzyme A (acetyl-CoA) as a primer, although they possessed lower specific activities than eFabH. bFabH1 and bFabH2 also utilized iso- and anteiso-branched-chain acyl-CoA primers as substrates. eFabH was not able to accept these CoA thioesters. Reconstitution of a complete round of fatty acid synthesis in vitro with purified E. coli proteins showed that eFabH was the only E. colienzyme incapable of using branched-chain substrates. Expression of either bFabH1 or bFabH2 in E. coli resulted in the appearance of a branched-chain 17-carbon fatty acid. Thus, the substrate specificity of FabH is an important determinant of branched-chain fatty acid production.

scholarly journals Elucidation of transient protein-protein interactions within carrier protein-dependent biosynthesis

2020 ◽  
Author(s):  
Michael Burkart ◽  
Thomas Bartholow ◽  
Terra Sztain ◽  
Ashay Patel ◽  
D Lee ◽  
...  
Keyword(s):  
Fatty Acid ◽  
Protein Interactions ◽  
Fatty Acid Biosynthesis ◽  
De Novo ◽  
Acyl Carrier Protein ◽  
Protein Docking ◽  
Carrier Protein ◽  
Protein Protein Interactions ◽  
Acid Biosynthesis ◽  
E Coli

Abstract Fatty acid biosynthesis (FAB) is an essential and highly conserved metabolic pathway. In bacteria, this process is mediated by an elaborate network of protein•protein interactions (PPIs) involving a small, dynamic acyl carrier protein that interacts with dozens of other partner proteins (PPs). These PPIs have remained poorly characterized due to their dynamic and transient nature. Using a combination of solution-phase NMR spectroscopy and protein-protein docking simulations, we report a comprehensive residue-by-residue comparison of the PPIs formed during FAB in Escherichia coli. This work reveals the molecular basis of six discrete binding events responsible for E. coli FAB and offers insights into a method to characterize these events and those in related carrier protein-dependent pathways. ONE SENTENCE SUMMARY: Through a combination of structural and computational analysis, a comparative evaluation of protein-protein interactions in de novo fatty acid biosynthesis in E. coli is performed.

scholarly journals Engineering of E. coli inherent fatty acid biosynthesis capacity to increase octanoic acid production

2018 ◽  
Vol 11 (1) ◽  
Author(s):  
Zaigao Tan ◽  
Jong Moon Yoon ◽  
Anupam Chowdhury ◽  
Kaitlin Burdick ◽  
Laura R. Jarboe ◽  
...  
Keyword(s):  
Fatty Acid ◽  
Acid Production ◽  
Octanoic Acid ◽  
Fatty Acid Biosynthesis ◽  
Acid Biosynthesis ◽  
E Coli

scholarly journals Herpes ICP8 protein stimulates homologous recombination in human cells

2018 ◽  
Author(s):  
Melvys Valledor ◽  
Richard S. Myers ◽  
Paul C. Schiller
Keyword(s):  
Homologous Recombination ◽  
Gene Targeting ◽  
Genomic Analysis ◽  
Human Cells ◽  
E Coli ◽  
Recombination Proteins ◽  
Genome Modification ◽  
Functional Genomic Analysis ◽  
Human Herpes Virus Type

ABSTRACTRecombineering has transformed functional genomic analysis. Genome modification by recombineering using the phage lambda Red SynExo homologous recombination proteins Beta inEscherichia colihas approached 100% efficiency. While highly efficient inE. coli, recombineering using the Red SynExo in other organisms declines in efficiency roughly correlating with phylogenetic distance fromE. coli. SynExo recombinases are common to double-stranded DNA viruses infecting a variety of organisms, including humans. Human Herpes virus Type 1 (HHV1) encodes a SynExo comprised of ICP8 synaptase and UL12 exonuclease. In a previous study, the Herpes SynExo was reconstitutedin vitroand shown to catalyze a model recombination reaction. Here we describe stimulation of gene targeting to edit a novel fluorescent protein gene in the human genome using ICP8 and compared its efficiency to that of a “humanized” version of Beta protein from phage λ. ICP8 significantly enhanced gene targeting rates in HEK 293 T cells while Beta was not only unable to catalyze recombineering but inhibited gene targeting using endogenous recombination functions, despite both synaptases being well-expressed and localized to the nucleus. This proof of concept encourages developing species-specific SynExo recombinases for genome engineering.SIGNIFICANCEGenome modification by recombineering using SynExo viral recombination proteins has transformed functional genomic analysis in bacteria. Single-stranded DNA (ssDNA) recombineering approaches 100% efficiency inE. coliusing Beta protein from bacteriophage lambda, but recombineering has not been extended to eukaryotic genomes. Efficient recombineering requires SynExos that co-evolved with a viral host, however SynExos are common to viruses infecting a variety of organisms, including humans. The ICP8 protein of Human Herpes virus Type 1 is a SynExo protein similar to Beta. In this pioneering study, Herpes ICP8 stimulated gene targeting in a human genome by homologous recombination while the bacterial virus Beta protein inhibited recombination in human cells. This is the first demonstration of host-specific recombineering in human cells using a human viral SynExo protein.

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