Identification of candidate odorant degrading gene/enzyme systems in the antennal transcriptome of Drosophila melanogaster.

The metabolism of volatile signal molecules by odorant degrading enzymes (ODEs) is crucial to the ongoing sensitivity and specificity of chemoreception in various insects, and a few specific esterases, cytochrome P450s, glutathione S-transferases (GSTs) and UDP-glycosyltransferases (UGTs) have previously been implicated in this process. Significant progress has been made in characterizing ODEs in Lepidoptera but very little is known about them in Diptera, including in Drosophila melanogaster, a major insect model. We have therefore carried out a transcriptomic analysis of the antennae of D. melanogaster in order to identify candidate ODEs. Virgin male and female and mated female antennal transcriptomes were determined by RNAseq. As with the Lepidoptera, we found that many esterases, cytochrome P450 enzymes, GSTs and UGTs are expressed in D. melanogaster antennae. As olfactory genes generally show selective expression in the antennae, a comparison to previously published transcriptomes for other tissues has been performed, showing preferential expression in the antennae for one esterase, JHEdup, one cytochrome P450, CYP308a1, and one GST, GSTE4. These largely uncharacterized enzymes are now prime candidates for ODE functions. JHEdup was expressed heterologously and found to have high catalytic activity against a chemically diverse group of known ester odorants for this species. This is a finding consistent with an ODE although it might suggest a general role in clearing several odorants rather than a specific role in clearing a particular odorant. Our findings do not preclude the possibility of odorant degrading functions for other antennally expressed esterases, P450s, GSTs and UGTs but, if so, they suggest that these enzymes also have additional functions in other tissues.

300-Fold increase in production of the Zn2+-dependent dechlorinase TrzN in soluble form via apoenzyme stabilization.

Microbial metalloenzymes constitute a large library of biocatalysts, a number of which have already been shown to catalyze the breakdown of toxic chemicals or industrially relevant chemical transformations. However, while there is considerable interest in harnessing these catalysts for biotechnology, for many of the enzymes, their large-scale production in active, soluble form in recombinant systems is a significant barrier to their use. In this work, we demonstrate that as few as three mutations can result in a 300-fold increase in the expression of soluble TrzN, an enzyme from Arthrobacter aurescens with environmental applications that catalyzes the hydrolysis of triazine herbicides, in Escherichia coli. Using a combination of X-ray crystallography, kinetic analysis, and computational simulation, we show that the majority of the improvement in expression is due to stabilization of the apoenzyme rather than the metal ion-bound holoenzyme. This provides a structural and mechanistic explanation for the observation that many compensatory mutations can increase levels of soluble-protein production without increasing the stability of the final, active form of the enzyme. This study provides a molecular understanding of the importance of the stability of metal ion free states to the accumulation of soluble protein and shows that differences between apoenzyme and holoenzyme structures can result in mutations affecting the stability of either state differently.

The evolution of new enzyme function: lessons from xenobiotic metabolizing bacteria versus insecticide-resistant insects.

Here, we compare the evolutionary routes by which bacteria and insects have evolved enzymatic processes for the degradation of four classes of synthetic chemical insecticide. For insects, the selective advantage of such degradative activities is survival on exposure to the insecticide, whereas for the bacteria the advantage is simply a matter of access to additional sources of nutrients. Nevertheless, bacteria have evolved highly efficient enzymes from a wide variety of enzyme families, whereas insects have relied upon generalist esterase-, cytochrome P450- and glutathione-S-transferase-dependent detoxification systems. Moreover, the mutant insect enzymes are less efficient kinetically and less diverged in sequence from their putative ancestors than their bacterial counterparts. This presumably reflects several advantages that bacteria have over insects in the acquisition of new enzymatic functions, such as a broad biochemical repertoire from which new functions can be evolved, large population sizes, high effective mutation rates, very short generation times and access to genetic diversity through horizontal gene transfer. Both the insect and bacterial systems support recent theory proposing that new biochemical functions often evolve from 'promiscuous' activities in existing enzymes, with subsequent mutations then enhancing those activities. Study of the insect enzymes will help in resistance management, while the bacterial enzymes are potential bioremediants of insecticide residues in a range of contaminated environments.

Only one esterase of Drosophila melanogaster is likely to degrade juvenile hormone in vivo.

Previously we identified juvenile hormone esterase (JHE) from Drosophila melanogaster by the criteria that it showed both appropriate developmental expression and kinetics for juvenile hormone (JH). We also noted three further esterases of D. melanogaster with some JHE-like characteristics, such as a GQSAG active site motif, a particular amphipathic helix, or close phylogenetic relationship with other JHEs. In this study, these JHE-like enzymes were expressed in vitro and their kinetic parameters compared with those of the previously identified JHE. Despite considerable phylogenetic distance between some of the esterases, they could all hydrolyse racemic JHIII. However, only the previously identified JHE had kinetic parameters (K(M) and k(cat)) towards various forms of JH (racemic or individual isomers of JHIII, JHII, JHI, and methyl farnesoate) consistent with a physiological role in JH regulation. Furthermore, only this JHE showed a preference for artificial substrates with acyl chain lengths similar to that of JH. This suggests that there is probably only one physiologically functional JHE in D. melanogaster but multiple esterases with JH esterase activity. Genomic comparisons of the selective JHE across 11 other Drosophila species showed a single orthologue in 10 of them but Drosophila willistoni has 16 full-length copies, five of them with the GQSAG motif and amphipathic helix.

A global response to sulfur starvation in Pseudomonas putida and its relationship to the expression of low-sulfur-content proteins.

Sulfur is essential for life on Earth, but its availability is limited in many environments. Here the sulfur-starvation response of the model soil bacterium Pseudomonas putida KT2440 is shown to be associated with an approximately fivefold reduction in the total soluble thiol content of the cell. A bioinformatic survey of the P. putida KT2440 genome identified 646 genes encoding proteins with a significantly lower than average sulfur content (low sulfur-content proteins, LSPs), the expression of which may have a role in the global reduction of cellular thiol content during sulfur starvation. Analysis of the genetic organization of the LSP-encoding genes showed that 31% were potentially transcriptionally associated with at least one other gene encoding a protein defined as an LSP. In particular, 55 LSP genes were located in three large clusters, termed low-sulfur islands (LSIs) here. The predicted identities of the proteins encoded by the LSIs strongly suggest that the LSIs have a role in acquiring sulfur from organic sulfur sources during sulfur starvation. This hypothesis was supported by transcription fusion studies on a limited number of LSP promoters under low-sulfur conditions. In a wider survey of bacterial species, LSIs were found to be more prevalent in free-living, Gram-negative bacteria than in Gram-positive or obligately intracellular bacteria.

Latitudinal clines for nucleotide polymorphisms in the Esterase 6 gene of Drosophila melanogaster.

Previous studies have found non-neutral patterns of nucleotide polymorphism in the promoter and coding regions of Est6 in D. melanogaster. Coding region polymorphism peaks around two closely linked replacement differences associated with the EST6-F/EST6-S allozyme polymorphism. The promoter contains two common, highly diverged haplotype groups, P1 and P7, that differentially affect Est6 expression. Allozyme studies have also revealed latitudinal clines in EST6-F and EST6-S frequencies that recur across continents. Here we analyse nucleotide polymorphisms across the promoter and the region of peak coding sequence polymorphism in 10 Australian populations along a 25 degrees latitudinal gradient in order to examine the basis for the allozyme clines. As with the earlier studies, we find an excess of intermediate to high frequency variants in both the P1/P7 region and around the two EST6-F/EST6-S replacements in some populations. The two EST6-F/EST6-S replacement polymorphisms show latitudinal clines whereas the P1 and P7 groups of promoter haplotypes do not. However the strongest clines are for three co-segregating silent site polymorphisms in a 4 bp stretch at the 3' end of the sequenced region. Monte Carlo simulations show that the clines for those three sites can explain all others in the data but none of the others can explain those three. Thus the allozyme clines may not reflect selection on either the P1/P7 polymorphism or the two replacements previously associated with the EST6-F/EST-S difference.

Nucleotide polymorphism in the Est6 promoter, which is widespread in derived populations of Drosophila melanogaster, changes the level of Esterase 6 expressed in the male ejaculatory duct.

Previous analysis of an Australian population of D. melanogaster revealed two predominant Est6 promoter haplotypes, P1 and P7. These haplotypes, which differ at 14 sites over a 325-bp region, are associated with a 15-20% difference in male EST6 activity. Here we show that the P1/P7 sequence difference causes the male activity variation by recreating the activity difference among >60 independently transformed lines containing representative P1 or P7 promoter alleles fused to an identical Est6 coding region. Furthermore we find that the whole fly difference reflects about a twofold difference in EST6 activity in the anterior sperm ejaculatory duct. EST6 activity variation in this tissue is known to affect reproductive fitness. Using a combination of RFLP analysis and DNA sequencing, we show that P1 and P7 are predominant in six populations from America, Asia, and Australia, albeit less frequent in a population from the presumptively ancestral east African range of the species. The sequence data show significant departures from neutral expectations for the derived American and Australian populations but not the presumptively ancestral Zimbabwean population. Thus the P1/P7 difference could be a major source of adaptively significant EST6 activity variation through much of the now cosmopolitan range of D. melanogaster.