Multiple Pathways for Triacylglycerol Biosynthesis in
            <i>Streptomyces coelicolor</i>

Arabolaza, Ana; Rodrı́guez, Eduardo; Altabe, Silvia; Alvarez, Héctor M.; Gramajo, Hugo

doi:10.1128/aem.02638-07

Cited by 113 publications

(110 citation statements)

References 41 publications

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“…The finding that there was a residual DGAT activity and TAG synthesis left in the triple mutant (sco0958 sco1280 sco0123) of S. coelicolor again supported this hypothesis (75). In S. coelicolor, bacterial phospholipid:DGAT (PDAT) activity could be proven for the first time.…”

Section: Other Atfa-like Acyltransferases In Different Bacteriasupporting

confidence: 66%

“…The authors further speculated that Sco1280 might have a very limited substrate range or that it might need an interaction with an oily surface or another protein for full activity. Sco0123, in contrast, seems to have a completely different physiological role (75).…”

Section: Other Atfa-like Acyltransferases In Different Bacteriamentioning

confidence: 99%

“…In the genome of S. coelicolor, there are genes for three proteins with remote similarities to AtfA from A. baylyi: Sco0958, Sco0123, and Sco1280 (75). Only Sco0958, exhibiting 25% identity to AtfA, contributes to TAG biosynthesis in S. coelicolor strain A3(2): its deletion seriously reduced TAG accumulation to approximately 30% of the S. coelicolor wild-type TAG level, whereas a deletion of the other two candidates had no effect.…”

Section: Other Atfa-like Acyltransferases In Different Bacteriamentioning

confidence: 99%

“…Thus, glycerophospholipids can act as acyl donors for TAG biosynthesis via the PDAT pathway in addition to (or as substitute for) the DGAT pathway catalyzed by AtfA-like acyltransferases. So far, the bacterial PDAT-mediating enzyme has not been identified, and the genome of S. coelicolor does not feature any obvious sequence similarity to characterized eukaryotic PDATs (e.g., Lro1 from S. cerevisiae) (75).…”

Section: Other Atfa-like Acyltransferases In Different Bacteriamentioning

confidence: 99%

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Acyltransferases in Bacteria

Röttig

Steinbüchel

2013

Microbiol Mol Biol Rev

151

141

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SUMMARY Long-chain-length hydrophobic acyl residues play a vital role in a multitude of essential biological structures and processes. They build the inner hydrophobic layers of biological membranes, are converted to intracellular storage compounds, and are used to modify protein properties or function as membrane anchors, to name only a few functions. Acyl thioesters are transferred by acyltransferases or transacylases to a variety of different substrates or are polymerized to lipophilic storage compounds. Lipases represent another important enzyme class dealing with fatty acyl chains; however, they cannot be regarded as acyltransferases in the strict sense. This review provides a detailed survey of the wide spectrum of bacterial acyltransferases and compares different enzyme families in regard to their catalytic mechanisms. On the basis of their studied or assumed mechanisms, most of the acyl-transferring enzymes can be divided into two groups. The majority of enzymes discussed in this review employ a conserved acyltransferase motif with an invariant histidine residue, followed by an acidic amino acid residue, and their catalytic mechanism is characterized by a noncovalent transition state. In contrast to that, lipases rely on completely different mechanism which employs a catalytic triad and functions via the formation of covalent intermediates. This is, for example, similar to the mechanism which has been suggested for polyester synthases. Consequently, although the presented enzyme types neither share homology nor have a common three-dimensional structure, and although they deal with greatly varying molecule structures, this variety is not reflected in their mechanisms, all of which rely on a catalytically active histidine residue.

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Section: Other Atfa-like Acyltransferases In Different Bacteriasupporting

confidence: 66%

Section: Other Atfa-like Acyltransferases In Different Bacteriamentioning

confidence: 99%

Section: Other Atfa-like Acyltransferases In Different Bacteriamentioning

confidence: 99%

Section: Other Atfa-like Acyltransferases In Different Bacteriamentioning

confidence: 99%

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Acyltransferases in Bacteria

Röttig

Steinbüchel

2013

Microbiol Mol Biol Rev

151

141

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“…142 Subsequently, the same authors also described the successful 143 reconstruction of the EPA and DHA biosynthetic pathway in the 144 seeds of an oilseed crop, C. sativa. They successfully engineered this 145 species to accumulate high levels of x3-VLCPUFAs in its seed oils 146 and yielded two iterations, in which one accumulated EPA up to 147 31% of the seed oils and the other accumulated up to 12% EPA 148 and 14% DHA in the seed oils [25]. These research efforts demon- 149 strate the feasibility of large-scale production of x3-VLCPUFAs in 150 the oilseeds of transgenic crops, which have proved to be a prom- 151 ising alternative to fish oils.…”

mentioning

confidence: 99%

Metabolic engineering of microorganisms to produce omega-3 very long-chain polyunsaturated fatty acids

Gong

Wan

Jiang

et al. 2014

Progress in Lipid Research

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Random mutagenesis of atfA and screening for Acinetobacter baylyi mutants with an altered lipid accumulation

Röttig

Steinbüchel

2013

Euro J Lipid Sci & Tech

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Acinetobacter baylyi synthesizes significant amounts of wax esters (WE) and triacylglycerols (TAG) catalyzed by wax ester synthase/acyl‐CoA:diacylglycerol acyltransferase (WS/DGAT or AtfA), representing the key enzyme for bacterial lipid accumulation. However, the structure and exact biochemical mechanism of AtfA could not be elucidated, yet. Therefore, a combination of random mutagenesis, screening and sequencing of atfA gene variants was conducted to gain further insights into the relationship between sequence and function of the enzyme. Several mutations could be detected which seriously diminished lipid accumulation in A. baylyi as well as AtfA activity in recombinant E. coli strains, such as Glu15Lys, Trp67Gly, Ala126Asp, Ser374Pro, or Gly378Ser/Asp. The affected residues are more or less conserved among a wide range of AtfA homologs. Especially the highly conserved pattern SNVPGP seems to be crucial, as mutations inside this pattern drastically impair enzyme activity. Furthermore, it became obvious that the C‐terminal part of AtfA is indispensable for activity, although the catalytic core is located in the N‐terminal half of the enzyme. In silico studies suggest that the C‐terminus might form a coiled‐coil fold which could putatively represent the dimerization domain. Practical applications: WE, composed of a long‐chain acyl moiety and a fatty alcohol residue, are valuable ingredients of many commercial products like cosmetics, medical products or lubricants. However, natural sources for high‐quality WE are currently mainly restricted to the expensive oil of the jojoba plant or to carnauba wax. As A. baylyi naturally accumulates WE with a similar composition to jojoba‐oil, this organisms and the responsible acyltransferase AtfA, are of great interest regarding a sustainable biotechnological WE production. However, a lack of structural knowledge about this enzyme family currently constricts promising enzyme optimization approaches. The insights gained by random mutagenesis of AtfA can build a basis for further site‐directed mutagenesis approaches in order to optimize its activity, stability, and/or substrate range.

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Multiple Pathways for Triacylglycerol Biosynthesis in Streptomyces coelicolor

Cited by 113 publications

References 41 publications

Acyltransferases in Bacteria

Acyltransferases in Bacteria

Metabolic engineering of microorganisms to produce omega-3 very long-chain polyunsaturated fatty acids

Random mutagenesis of atfA and screening for Acinetobacter baylyi mutants with an altered lipid accumulation

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