A survey of the three kinetoplastid genome projects revealed the presence of three putative front‐end desaturase genes in Leishmania major, one in Trypanosoma brucei and two highly identical ones (98%) in T. cruzi. The encoded gene products were tentatively annotated as Δ8, Δ5 and Δ6 desaturases for L. major, and Δ6 desaturase for both trypanosomes. After phylogenetic and structural analysis of the deduced proteins, we predicted that the putative Δ6 desaturases could have Δ4 desaturase activity, based mainly on the conserved HX3HH motif for the second histidine box, when compared with Δ4 desaturases from Thraustochytrium, Euglena gracilis and the microalga, Pavlova lutheri, which are more than 30% identical to the trypanosomatid enzymes. After cloning and expression in Saccharomyces cerevisiae, it was possible to functionally characterize each of the front‐end desaturases present in L. major and T. brucei. Our prediction about the presence of Δ4 desaturase activity in the three kinetoplastids was corroborated. In the same way, Δ5 desaturase activity was confirmed to be present in L. major. Interestingly, the putative Δ8 desaturase turned out to be a functional Δ6 desaturase, being 35% and 31% identical to Rhizopus oryzae and Pythium irregulareΔ6 desaturases, respectively. Our results indicate that no conclusive predictions can be made about the function of this class of enzymes merely on the basis of sequence homology. Moreover, they indicate that a complete pathway for very‐long‐chain polyunsaturated fatty acid biosynthesis is functional in L. major using Δ6, Δ5 and Δ4 desaturases. In trypanosomes, only Δ4 desaturases are present. The putative algal origin of the pathway in kinetoplastids is discussed.
SummaryPolyunsaturated fatty acids have important structural roles in cell membranes. They are also intermediates in the synthesis of biologically active molecules such as eicosanoids, which mediate fever, inflammation, blood pressure and neurotransmission. Arachidonic and docosahexaenoic acids are essential components of brain tissues and, through their involvement in the development of neural and retinal functions, important dietary nutrients for neonatal babies. Lower eukaryotes are particularly rich in C20-22 polyunsaturated fatty acids. Fungi and marine microalgae are currently used to produce nutraceutic oils. Other protists and algae are being studied because of the variability in their enzymes involved in polyunsaturated fatty acid biosynthesis. Such enzymes could be used as source for the production of transgenic organisms able to synthesize designed oils for human diet or, in the case of parasitic protozoa, they might be identified as putative chemotherapeutic targets. Polyunsaturated fatty acids can be synthesized by two different pathways: an anaerobic one, by using polyketide synthase related enzymes, and an aerobic one, which involves the action of elongases and oxygen dependent desaturases. Desaturases can be classified into three main types, depending on which of the consecutive steps of polyunsaturated fatty acid synthesis they are involved with. The enzymes may be specialized to act on: saturated substrates (type I); mono-and di-unsaturated fatty acids by introducing additional double bonds at the methyl-end site of the existing double bonds (type II); or the carboxy half ('front-end') of polyunsaturated ones (type III). Type III desaturases require the alternating action of elongases. A description of the enzymes that have been isolated and functionally characterized is provided, in order to highlight the different pathways found in lower eukaryotes.
Leishmania major synthesizes polyunsaturated fatty acids by using Δ6, Δ5 and Δ4 front‐end desaturases, which have recently been characterized [Tripodi KE, Buttigliero LV, Altabe SG & Uttaro AD (2006) FEBS J273, 271–280], and two predicted elongases specific for C18 Δ6 and C20 Δ5 polyunsaturated fatty acids, respectively. Trypanosoma brucei and Trypanosoma cruzi lack Δ6 and Δ5 desaturases but contain Δ4 desaturases, implying that trypanosomes use exogenous polyunsaturated fatty acids to produce C22 Δ4 fatty acids. In order to identify putative precursors of these C22 fatty acids and to completely describe the pathways for polyunsaturated fatty acid biosynthesis in trypanosomatids, we have performed a search in the three genomes and identified four different elongase genes in T. brucei, five in T. cruzi and 14 in L. major. After a phylogenetic analysis of the encoded proteins together with elongases from a variety of other organisms, we selected four candidate polyunsaturated fatty acid elongases. Leishmania major CAJ02037, T. brucei AAX69821 and T. cruzi XP_808770 share 57–52% identity, and group together with C20 Δ5 polyunsaturated fatty acid elongases from algae. The predicted activity was corroborated by functional characterization after expression in yeast. T. brucei elongase was also able to elongate Δ8 and Δ11 C20 polyunsaturated fatty acids. L. major CAJ08636, which shares 33% identity with Mortierella alpinaΔ6 elongase, showed a high specificity for C18 Δ6 polyunsaturated fatty acids. In all cases, a preference for n6 polyunsaturated fatty acids was observed. This indicates that L. major has, as predicted, Δ6 and Δ5 elongases and a complete pathway for polyunsaturated fatty acid biosynthesis. Trypanosomes contain only Δ5 elongases, which, together with Δ4 desaturases, allow them to use eicosapentaenoic acid and arachidonic acid, a precursor that is relatively abundant in the host, for C22 polyunsaturated fatty acid biosynthesis.
The ciliate Tetrahymena thermophila incorporates sterols from its environment that desaturates at positions C5(6), C7(8), and C22(23). Phytosterols are additionally modified by removal of the ethyl group at carbon 24 (C24). The enzymes involved are oxygen-, NAD(P)H-, and cytochrome b5 dependent, reason why they were classified as members of the hydroxylases/desaturases superfamily. The ciliate's genome revealed the presence of seven putative sterol desaturases belonging to this family, two of which we have previously characterized as the C24-de-ethylase and C5(6)-desaturase. A Rieske oxygenase was also identified; this type of enzyme, with sterol C7(8)-desaturase activity, was observed only in animals, called Neverland in insects and DAF-36 in nematodes. They perform the conversion of cholesterol into 7-dehydrocholesterol, first step in the synthesis of the essential hormones ecdysteroids and dafachronic acids. By adapting an RNA interference-by-feeding protocol, we easily screened six of the eight genes described earlier, allowing the characterization of the Rieske-like oxygenase as the ciliate's C7(8)-desaturase (Des7p). This characterization was confirmed by obtaining the corresponding knockout mutant, making Des7p the first nonanimal Rieske-sterol desaturase described. To our knowledge, this is the first time that the feeding-RNAi technique was successfully applied in T. thermophila, enabling to consider such methodology for future reverse genetics high-throughput screenings in this ciliate. Bioinformatics analyses revealed the presence of Des7p orthologs in other Oligohymenophorean ciliates and in nonanimal Opisthokonts, like the protists Salpingoeca rosetta and Capsaspora owczarzaki. A horizontal gene transfer event from a unicellular Opisthokont to an ancient phagotrophic Oligohymenophorean could explain the acquisition of the Rieske oxygenase by Tetrahymena.
An open reading frame with fatty acid desaturase similarity was identified in the genome of Trypanosoma brucei. The 1224 bp sequence specifies a protein of 408 amino acids with 59% and 58% similarity to Mortierella alpina and Arabidopsis thalianaΔ12 desaturase, respectively, and 51% with A. thalianaω3 desaturases. The histidine tracks that compose the iron‐binding active centers of the enzyme were more similar to those of the ω3 desaturases. Expression of the trypanosome gene in Saccharomyces cerevisiae resulted in the production of fatty acids that are normally not synthesized in yeast, namely linoleic acid (18:2Δ9,12) and hexadecadienoic acid (16:2Δ9,12), the levels of which were dependent on the culture temperature. At low temperature, the production of bi‐unsaturated fatty acids and the 16:2/18:2 ratio were higher. Transformed yeast cultures supplemented with 19:1Δ10 fatty acid yielded 19:2Δ10,13, indicating that the enzyme is able to introduce a double bond at three carbon atoms from a pre‐existent olefinic bond. The expression of the gene in a S. cerevisiae mutant defective in cytochrome b5 showed a significant reduction in bi‐unsaturated fatty acid production, although it was not totally abolished. Based on the regioselectivity and substrate preferences, we characterized the trypanosome enzyme as a cytochrome b5‐dependent oleate desaturase. Expression of the ORF in a double mutant (ole1Δ,cytb5Δ) abolished all oleate desaturase activity completely. OLE1 codes for the endogenous stearoyl‐CoA desaturase. Thus, Ole1p has, like Cytb5p, an additional cytochrome b5 function (actually an electron donor function), which is responsible for the activity detected when using the cytb5Δ single mutant.
The synthesis of periplasmic beta(1-2)glucan is required for crown gall tumor formation by Agrobacterium tumefaciens and for effective nodulation of alfalfa by Rhizobium meliloti. The exoC (pscA) gene is required for this synthesis by both bacteria as well as for the synthesis of capsular polysaccharide and normal lipopolysaccharide. We tested the possibility that the pleiotropic ExoC phenotype is due to a defect in the synthesis of an intermediate common to several polysaccharide biosynthetic pathways. Cytoplasmic extracts from wild-type A. tumefaciens and from exoC mutants of A. tumefaciens containing a cloned wild-type exoC gene synthesized in vitro UDP-glucose from glucose, glucose 1-phosphate, and glucose 6-phosphate. Extracts from exoC mutants synthesized UDP-glucose from glucose 1-phosphate but not from glucose or glucose 6-phosphate. Membranes from exoC mutant cells synthesized beta(1-2)glucan in vitro when exogenous UDP-glucose was added and contained the 235-kilodalton protein, which has been shown to carry out this synthesis in wild-type cells. We conclude that the inability of exoC mutants to synthesize beta(1-2)glucan is due to a deficiency in the activity of the enzyme phosphoglucomutase (EC 2.7.5.1), which in wild-type bacteria converts glucose 6-phosphate to glucose 1-phosphate, an intermediate in the synthesis of UDP-glucose. This interpretation can account for all of the deficiencies in polysaccharide synthesis which have been observed in these mutants.
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