Roles of Multiple Acetoacetyl Coenzyme A Reductases in Polyhydroxybutyrate Biosynthesis in Ralstonia eutropha H16

The bacterium Ralstonia eutropha H16 synthesizes polyhydroxybutyrate (PHB) from acetyl coenzyme A (acetyl-CoA) through reactions catalyzed by a β-ketothiolase (PhaA), an acetoacetyl-CoA reductase (PhaB), and a polyhydroxyalkanoate synthase (PhaC). An operon of three genes encoding these enzymatic steps was discovered in R. eutropha and has been well studied. Sequencing and analysis of the R. eutropha genome revealed putative isologs for each of the PHB biosynthetic genes, many of which had never been characterized. In addition to the previously identified phaB1 gene, the genome contains the isologs phaB2 and phaB3 as well as 15 other potential acetoacetyl-CoA reductases. We have investigated the roles of the three phaB isologs by deleting them from the genome individually and in combination. It was discovered that the gene products of both phaB1 and phaB3 contribute to PHB biosynthesis in fructose minimal medium but that in plant oil minimal medium and rich medium, phaB3 seems to be unexpressed. This raises interesting questions concerning the regulation of phaB3 expression. Deletion of the gene phaB2 did not result in an observable phenotype under the conditions tested, although this gene does encode an active reductase. Addition of the individual reductase genes to the genome of the ΔphaB1 ΔphaB2 ΔphaB3 strain restored PHB production, and in the course of our complementation experiments, we serendipitously created a PHB-hyperproducing mutant. Measurement of the PhaB and PhaA activities of the mutant strains indicated that the thiolase reaction is the limiting step in PHB biosynthesis in R. eutropha H16 during nitrogen-limited growth on fructose.Polyhydroxyalkanoates (PHAs) are natural polyesters synthesized by a wide range of bacteria as carbon and energy reserves. PHAs are typically stored when organisms are in an environment in which carbon is plentiful but the lack of another nutrient limits normal cell growth. It has been found that in environments with fluctuating carbon levels, PHA producers have crucial advantages over rival species (14). In addition to their importance in the microbial world, these polymers have been studied for their potential uses in biodegradable consumer goods (12) and medical products (22) and as chemical precursors (4). Although many PHA monomers have been discovered, the most common are 3-hydroxyalkanoates (32). Common PHAs are typically characterized by their constituent monomers as short-chain-length polymers (SCL-PHA; C₄ and C₅ monomers) or medium-chain-length polymers (MCL-PHA; C₆ and longer monomers).The model organism used to study PHA biosynthesis is the Gram-negative bacterium Ralstonia eutropha. This organism accumulates a high percentage of its cell dry weight (CDW) as SCL-PHA under nutrient limitation. When grown on sugars or plant oils, R. eutropha makes poly(3-hydroxybutyrate) (PHB) almost exclusively, although the addition of precursors such as propionate to the growth medium can lead to incorporation of 3-hydroxyvalerate into the polymer chain as well (2). An operon of biosynthetic genes from R. eutropha encoding enzymes sufficient for synthesis of PHB from acetyl coenzyme A (acetyl-CoA), which consisted of phaC-phaA-phaB, was discovered in the late 1980s (25, 26, 36). In this pathway, two molecules of acetyl-CoA are condensed by a β-ketothiolase (PhaA) and the resulting acetoacetyl-CoA is reduced by a reductase (PhaB) to form (R)-3-hydroxybutyryl-CoA (HB-CoA), which is the substrate for the PHA synthase (PhaC). Sequencing and analysis of the R. eutropha genome revealed the existence of putative isologs for each of the PHA synthetic genes (29). While the existence of alternate β-ketothiolases was already known (39), most of the potential isologs identified had never been characterized.Our group wanted to better understand how acetoacetyl-CoA reduction occurs in R. eutropha. In addition to the earlier-identified phaB gene, now referred to as phaB1 (GeneID, 4249784), the genes phaB2 (GeneID, 4249785) and phaB3 (GeneID, 4250155) were discovered on R. eutropha chromosome 1. Fifteen other potential isologs were also found to encode amino acid sequences that could potentially indicate acetoacetyl-CoA reductase activity (29). The roles of the newly discovered genes in PHB biosynthesis were unclear, especially given the results of an earlier biochemical study that suggested there was a single NADPH-dependent acetoacetyl-CoA reductase in R. eutropha (10). In order to determine the roles of the reductase genes in R. eutropha, we deleted phaB1, phaB2, and phaB3 from the genome both individually and in combination. In addition to characterizing these newly discovered genes, we also hoped to eliminate or diminish formation of HB-CoA by stopping the reduction reaction. Efforts to purify the PHA synthase from R. eutropha have been complicated by the high levels of PHB made by this organism (7). Studying formation and growth of PHB granules is difficult because PHB accumulates at a high rate, causing individual granules to coalesce and become indistinct (44). We therefore believed that an R. eutropha strain with decreased HB-CoA synthesis would be a useful experimental tool and could also serve as a platform for engineering new PHA synthesis pathways into R. eutropha.