Domain swapping localizes the structural determinants of regioselectivity in membrane-bound fatty acid desaturases of Caenorhabditis elegans

Identification of a crucial amino acid implicated in the hydroxylation/desaturation ratio of CpFAH12 bifunctional hydroxylase

Claviceps purpurea bifunctional Δ12-hydroxylase/desaturase, CpFAH12, and monofunctional desaturase CpFAD2, share 86% of sequence identity. To identify the underlying determinants of the hydroxylation/desaturation specificity, chimeras of these two enzymes were tested for their fatty acid production in an engineered Yarrowia lipolytica strain. It reveals that transmembrane helices are not involved in the hydroxylation/desaturation specificity whereas all cytosolic domains have an impact on it. Especially, replacing the CpFAH12 cytosolic part near the second histidine-box by the corresponding CpFAD2 part annihilates all hydroxylation activity. Further mutagenesis experiments within this domain identified isoleucine 198 as the crucial element for the hydroxylation activity of CpFAH12. Monofunctional variants performing the only desaturation were obtained when this position was exchanged by the threonine of CpFAD2. Saturation mutagenesis at this position showed modulation in the hydroxylation/desaturation specificity in the different variants. The WT enzyme was demonstrated as the most efficient for ricinoleic acid production and some variants showed a better desaturation activity. A model based on the recently discovered membrane desaturase structures indicate that these changes in specificity are more likely due to modifications in the di-iron center geometry rather than changes in the substrate binding mode.

Identification of amino acid residues that determine the substrate specificity of mammalian membrane-bound front-end fatty acid desaturases

Membrane-bound desaturases are physiologically and industrially important enzymes that are involved in the production of diverse fatty acids such as polyunsaturated fatty acids and their derivatives. Here, we identified amino acid residues that determine the substrate specificity of rat Δ6 desaturase (D6d) acting on linoleoyl-CoA by comparing its amino acid sequence with that of Δ5 desaturase (D5d), which converts dihomo-γ-linolenoyl-CoA. The N-terminal cytochrome b5-like domain was excluded as a determinant by domain swapping analysis. Substitution of eight amino acid residues (Ser209, Asn211, Arg216, Ser235, Leu236, Trp244, Gln245, and Val344) of D6d with the corresponding residues of D5d by site-directed mutagenesis switched the substrate specificity from linoleoyl-CoA to dihomo-γ-linolenoyl-CoA. In addition, replacement of Leu323 of D6d with Phe323 on the basis of the amino acid sequence of zebra fish Δ5/6 bifunctional desaturase was found to render D6d bifunctional. Homology modeling of D6d using recent crystal structure data of human stearoyl-CoA (Δ9) desaturase revealed that Arg216, Trp244, Gln245, and Leu323 are located near the substrate-binding pocket. To our knowledge, this is the first report on the structural basis of the substrate specificity of a mammalian front-end fatty acid desaturase, which will aid in efficient production of value-added fatty acids.

Diversification of substrate specificities in teleostei Fads2: characterization of Δ4 and Δ6Δ5 desaturases of Chirostoma estor

Currently existing data show that the capability for long-chain PUFA (LC-PUFA) biosynthesis in teleost fish is more diverse than in other vertebrates. Such diversity has been primarily linked to the subfunctionalization that teleostei fatty acyl desaturase (Fads)2 desaturases have undergone during evolution. We previously showed that Chirostoma estor, one of the few representatives of freshwater atherinopsids, had the ability for LC-PUFA biosynthesis from C18 PUFA precursors, in agreement with this species having unusually high contents of DHA. The particular ancestry and pattern of LC-PUFA biosynthesis activity of C. estor make this species an excellent model for study to gain further insight into LC-PUFA biosynthetic abilities among teleosts. The present study aimed to characterize cDNA sequences encoding fatty acyl elongases and desaturases, key genes involved in the LC-PUFA biosynthesis. Results show that C. estor expresses an elongase of very long-chain FA (Elovl)5 elongase and two Fads2 desaturases displaying Δ4 and Δ6/Δ5 specificities, thus allowing us to conclude that these three genes cover all the enzymatic abilities required for LC-PUFA biosynthesis from C18 PUFA. In addition, the specificities of the C. estor Fads2 enabled us to propose potential evolutionary patterns and mechanisms for subfunctionalization of Fads2 among fish lineages.

The role of C-terminal amino acid residues of a Δ⁶-fatty acid desaturase from blackcurrant

Δ⁶-fatty acid desaturase is an important enzyme in the catalytic synthesis of polyunsaturated fatty acids. Using domain swapping and a site-directed mutagenesis strategy, we found that the region of the C-terminal 67 amino acid residues of Δ⁶-fatty acid desaturase RnD6C from blackcurrant was essential for its catalytic activity and that seven different residues between RnD6C and RnD8A in that region were involved in the desaturase activity. Compared with RnD6C, the activity of the following mutations, V394A, K395I, F411L, S436P, VK3945AI and IS4356VP, was significantly decreased, whereas the activity of I417T was significantly increased. The amino acids N, T and Y in the last four residues also play a certain role in the desaturase activity.

SDD17 desaturase can convert arachidonic acid to eicosapentaenoic acid in mammalian cells

The possibility of elevating the omega-3 fatty acid contents in mammalian cells using the sdd17 gene from Saprolegnia diclina was investigated in the current study. The nucleotide sequence of the sdd17 gene was optimized and the pSDD17-IRES-GFP plasmid was introduced into murine 3T3 fibroblast cells by electroporation, following which its heterologous expression was evaluated by fatty acid analysis. Evaluation of GFP co-expression and RT-PCR analysis indicated that sdd17 could be expressed at very high levels in mammalian cells. Total cellular lipid analysis of transformed cells fed with arachidonic acid (20:4 n-6) as a substrate showed that the sdd17 expression resulted in an 82-155% (p<0.05) increase in eicosapentaenoic acid (20:5 n-3) compared with the control. This expression also reduced the arachidonic acid/(eicosapentaenoic+docosapentaenoic+docosahexaenoic acid) ratio from approximately 4:1 in control cells to 1.5:1 in sdd17-transformed cells (p<0.05). This study demonstrated that the foreign sdd17 gene from EPA-rich fungus was expressed at a high efficiency and caused the omega-3 fatty acid contents in mammalian cells to be elevated. It also provided a basis for potential applications of this gene in animal transgenesis.

An abundant acyl-CoA (Delta9) desaturase transcript in pheromone glands of the cabbage moth, Mamestra brassicae, encodes a catalytically inactive protein

The principal sex pheromone component produced by females of the cabbage moth, Mamestra brassicae, is derived from the monounsaturated fatty acid, Z11-16:1, whereas two additional trace components are derived from E11-16:1 and Z9-16:1. This report presents the isolation and analysis of cDNAs encoding pheromone gland-specific acyl-CoA desaturases implicated in the production of these unsaturated fatty acids (UFAs). Comparisons of the encoded amino acid sequences of four cDNA fragments isolated by degenerate PCR from cabbage moth pheromone glands established their orthology with previously characterized noctuid desaturases as follows: MbraLPAQ, belonging to the pheromone gland-specific LPAQ desaturase lineage having Delta11 regioselectivity, MbraKPSE-a and MbraKPSE-b, belonging to the pheromone gland-specific KPSE desaturase lineage having Delta9 regioselectivity and a substrate preference for palmitic acid (16:0) over oleic acid (18:0), and MbraNPVE, belonging to the NPVE desaturase lineage having Delta9 regioselectivity and a substrate preference 18:0>16:0. Full-length cDNAs corresponding to the two most abundantly expressed pheromone gland-specific desaturase transcripts, MbraLPAQ and MbraKPSE-b, were isolated and assayed for their ability to genetically complement the UFA auxotrophy of a desaturase-deficient ole1 strain of Saccharomyces cerevisiae. The MbraLPAQ desaturase restored UFA prototrophy and GC-MS analysis identified Z11-16:1 and Z11-18:1 as the predominant UFAs produced. Surprisingly, MbraKPSE-b failed to complement the ole1 mutation, although it shares >98% amino acid sequence similarity with other noctuid KPSE desaturases that do. Site-directed mutagenesis of either or both of two nonconservative amino acid substitutions restored functionality to the MbraKPSE-b protein, although GC-MS analysis revealed that neither reversion resulted in the characteristic KPSE substrate preference for 16:0.

Truncation mutants highlight a critical role for the N- and C-termini of the Spirulina Delta(6) desaturase in determining regioselectivity

The results of our previous study on heterologous expression in Escherichia coli of the gene desD, which encodes Spirulina Delta(6) desaturase, showed that co-expression with an immediate electron donor-either cytochrome b ( 5 ) or ferredoxin-was required for the production of GLA (gamma-linolenic acid), the product of the reaction catalyzed by Delta(6) desaturase. Since a system for stable transformation of Spirulina is not available, studies concerning Spirulina-enzyme characterization have been carried out in heterologous hosts. In this present study, the focus is on the role of the enzyme's N- and C-termini, which are possibly located in the cytoplasmic phase. Truncated enzymes were expressed in E. coli by employing the pTrcHisA expression system. The truncation of the N- and C-terminus by 10 (N10 and C10) and 30 (N30 and C30) amino acids, respectively, altered the enzyme's regioselective mode from one that measures from a preexisting double bond to that measuring from the methyl end of the substrate.

Mutational and functional analysis of the beta-carotene ketolase involved in the production of canthaxanthin and astaxanthin

Biosynthesis of the commercial carotenoids canthaxanthin and astaxanthin requires beta-carotene ketolase. The functional importance of the conserved amino acid residues of this enzyme from Paracoccus sp. strain N81106 (formerly classified as Agrobacterium aurantiacum) was analyzed by alanine-scanning mutagenesis. Mutations in the three highly conserved histidine motifs involved in iron coordination abolished its ability to catalyze the formation of ketocarotenoids. This supports the hypothesis that the CrtW ketolase belongs to the family of iron-dependent integral membrane proteins. Most of the mutations generated at other highly conserved residues resulted in partial activity. All partially active mutants showed a higher amount of adonixanthin accumulation than did the wild type when expressed in Escherichia coli cells harboring the zeaxanthin biosynthetic gene cluster. Some of the partially active mutants also produced a significant amount of echinenone when expressed in cells producing beta-carotene. In fact, expression of a mutant carrying D117A resulted in the accumulation of echinenone as the predominant carotenoid. These observations indicate that partial inactivation of the CrtW ketolase can often lead to the production of monoketolated intermediates. In order to improve the conversion rate of astaxanthin catalyzed by the CrtW ketolase, a color screening system was developed. Three randomly generated mutants, carrying L175M, M99V, and M99I, were identified to have improved activity. These mutants are potentially useful in pathway engineering for the production of astaxanthin.

Functional characterization of a plastidial omega-3 desaturase from sunflower (Helianthus annuus) in cyanobacteria

Fatty acid desaturases (FAD) play an important role in plant lipid metabolism and they can be found in several subcellular compartments such as the plastids and endoplasmic reticulum. Lipids are critical components of the cell membrane and, as a consequence, they are fundamental for the proper growth and development of all living organisms. We have used sequences from the conserved regions of known omega-3-desaturases to design degenerated oligonucleotides and clone a cDNA encoding a plastidial omega-3 desaturase from sunflower (HaFAD7). From its presumed full-length sequence, we predict that Hafad7 encodes a protein of 443 amino acids with a molecular mass of 50.8 kDa, and that it contains a putative chloroplast transit peptide of 51 amino acids. The predicted hydrophobicity of the protein identifies four potential membrane-spanning regions and, according to the TargetP algorithm, the protein should be targeted to the plastid/chloroplast membrane. RT-PCR analysis of its expression shows the transcript is preferentially expressed in photosynthetically active tissues. Heterologous expression of this protein in the unicellular cyanobacterium Synechocystis sp. PCC 6803 confirmed that the protein produced from this cDNA has omega-3 desaturase activity.

Modular organization of FDH: Exploring the basis of hydrolase catalysis

An abundant enzyme of liver cytosol, 10-formyltetrahydrofolate dehydrogenase (FDH), is an interesting example of a multidomain protein. It consists of two functionally unrelated domains, an aldehyde dehydrogenase-homologous domain and a folate-binding hydrolase domain, which are connected by an approximately 100-residue linker. The amino-terminal hydrolase domain of FDH (Nt-FDH) is a homolog of formyl transferase enzymes that utilize 10-formyl-THF as a formyl donor. Interestingly, the concerted action of all three domains of FDH produces a new catalytic activity, NADP+-dependent oxidation of 10-formyltetrahydrofolate (10-formyl-THF) to THF and CO2. The present studies had two objectives: First, to explore the modular organization of FDH through the production of hybrid enzymes by domain replacement with methionyl-tRNA formyltransferase (FMT), an enzyme homologous to the hydrolase domain of FDH. The second was to explore the molecular basis for the distinct catalytic mechanisms of Nt-FDH and related 10-formyl-THF utilizing enzymes. Our studies revealed that FMT cannot substitute for the hydrolase domain of FDH in order to catalyze the dehydrogenase reaction. It is apparently due to inability of FMT to catalyze the hydrolysis of 10-formyl-THF in the absence of the cosubstrate of the transferase reaction despite the high similarity of the catalytic centers of the two enzymes. Our results further imply that Ile in place of Asn in the FDH hydrolase catalytic center is an important determinant for hydrolase catalysis as opposed to transferase catalysis.

The Bacillus subtilis desaturase: a model to understand phospholipid modification and temperature sensing

Most fatty acid desaturases are members of a large superfamily of integral membrane, O2-dependent, iron-containing enzymes that insert double bonds into previously synthesized fatty acyl chains. The cold shock-induced, membrane-bound desaturase from Bacillus subtilis (Delta5-Des) uses existing phospholipids as substrates to introduce a cis-double bond at the fifth position of the fatty acyl chain. While essentially no three-dimensional structural information is available for these difficult-to-purify enzymes, experimental analysis of the topology of Delta5-Des has provided a model that might be extended to most acyl-lipid desaturases. In addition, studies of the cold-induced expression of Delta5-Des led to the identification of a two-component system composed of a membrane-associated kinase, DesK, and a transcriptional regulator, DesR, which stringently controls the transcription of the des gene, coding for the desaturase. A model for sensing and transduction of low-temperature signals has emerged from our results, which we discuss in the context of transcriptional regulation of membrane lipid fluidity homeostasis.