Abstract
Curly, described almost a century ago, is one of the most frequently used markers in Drosophila genetics. Despite this the molecular identity of Curly has remained obscure. Here we show that Curly mutations arise in the gene dual oxidase (duox), which encodes a reactive oxygen species (ROS) generating NADPH oxidase. Using Curly mutations and RNA interference (RNAi), we demonstrate that Duox autonomously stabilizes the wing on the last day of pupal development. Through genetic suppression studies, we identify a novel heme peroxidase, Curly Su (Cysu) that acts with Duox to form the wing. Ultrastructural analysis suggests that Duox and Cysu are required in the wing to bond and adhere the dorsal and ventral cuticle surfaces during its maturation. In Drosophila, Duox is best known for its role in the killing of pathogens by generating bactericidal ROS. Our work adds to a growing number of studies suggesting that Duox’s primary function is more structural, helping to form extracellular and cuticle structures in conjunction with peroxidases.
Author Summary
Fruit fly geneticists rely on a handful of dominant mutations that modify adult morphology in a way that is easy to spot, like changing the shape of the fly’s wings, eyes or bristles. One of the first such mutants identified in the early days of fly genetics and to this day likely the most widely used mutation, is Curly, which causes an upward curvature in the adult wings. Despite its importance as a marker, the genetic cause of Curly has remained unknown. Here, we reveal that Curly mutations occur in the gene duox, which encodes a ROS-generating enzyme. ROS once thought to be merely harmful by-products of metabolism, can also have beneficial purposes. Here we provide evidence that Duox generates ROS to help form and stabilize the wings of fruit flies. Furthermore, we identify a second enzyme, Cysu, which uses the ROS generated by Duox to crosslink proteins in the wing, thereby stabilizing and shaping its structure. Duox occurs in numerous organisms, including humans and fulfills a number of other functions, in particular in immunity and pathogen defense. With this new knowledge, Curly mutations will provide an excellent tool to study and understand the roles Duox plays in a variety of biological contexts.
Introduction
Over 90 years ago, Lenore Ward first described a dominant mutation, Curly, that causes the wings of Drosophila melanogaster to bend upwards [1]. Since then, Curly has become a ubiquitous second chromosomal marker used by Drosophila geneticists on a daily basis to follow and track mutations. Despite its widespread use, how Curly mutations dominantly alter wing curvature has remained obscure. Waddington first proposed that Curly causes an unequal contraction of the dorsal and ventral wing surfaces during the drying period shortly after flies emerge from their pupal cases [2, 3]. Others have subsequently demonstrated that comparable alterations in wing curvature can be caused by differential growth of the dorsal and ventral epithelia [4]. Irrespective of the mechanism, that similar wing phenotypes have been described for D. pseudoobscura and D. montium mutants [5] suggests the underlying cause of curly wing formation is evolutionarily conserved among Drosophilids [2]. The major factor limiting our understanding of Curly’s function in wing morphogenesis, however, is the fact that its molecular identity has remained unknown.
In this manuscript we uncover the long unknown molecular nature of Curly. We show that mutations in the gene duox cause the Curly wing phenotype. Duox is a member of a highly conserved group of transmembrane proteins collectively referred to as NADPH oxidases. These enzymes function to transfer electrons across biological membranes to generate ROS by transferring electrons from NADPH to oxygen through flavin adenine dinucleotide (FAD) and heme cofactors [6]. Several biological functions have been described for Duox. Perhaps the best studied of these in Drosophila is its role in host defense where it is thought to generate ROS to kill pathogens [7]. However, Duox also plays an important role in providing ROS, specifically hydrogen peroxide, for heme peroxidases to catalyze the formation of covalent bonds between biomolecules. In mammals, Duox generates hydrogen peroxide for thyroid peroxidase to catalyze the iodination and crosslinking of tyrosine residues in the formation of thyroid hormones [8, 9]. Duox is also expressed in tissues other than the thyroid, such as the gastrointestinal tract, where its function is less clear [6]. In insects, worms and sea urchins, Duox participates in the formation of extracellular structures through the crosslinking of tyrosine residues [10–12]. Indeed, instead of its function in generating bactericidal ROS, the tyrosine crosslinking activity of Duox may be the primary ancestral function, as it appears to be conserved across phyla.
Here we show that specific mutations in the NADPH binding-domain encoding region of duox cause a Curly wing phenotype. Using Curly, we demonstrate that duox is required during the last day of pupal development to stabilize the wing. Furthermore, through suppression experiments, we identify a novel heme peroxidase, Curly Su (Cysu), that works with duox to adhere the dorsal surface of the wing to the ventral one. Uncovering the molecular identity of Curly not only provides an entry point for the functional understanding of this prominent wing mutant phenotype, but also will allow for the discovery of novel duox interacting genes and regulators through unbiased genetic screens. Only through these approaches can we hope to understand the precise molecular function of Duox in the myriad biological processes in which it is involved.
Results
Curly mutations occur within duox
In the course of genetically following a loss-of-function mutation in the gene duox, duox KG07745, using the standard Drosophila genetic tool Curly of Oster (CyO) balancer, we noticed that we were unable to recover progeny containing both duox KG07745 and CyO. Since a) duox and Curly mutations fail to complement one another and b) Curly roughly maps to 23A4-23B2 [13], the chromosomal region containing duox, we wondered whether Curly might be an allele of duox.
Balancer chromosomes contain numerous inversions and chromosomal aberrations. To exclude the possibility that our inability to recover progeny was due to some other lesion in the 23A4-23B2 region of CyO, we crossed duox KG07745 to various Curly mutations not associated with CyO [1, 13, 14]. Consistent with our earlier results, all the Curly alleles tested failed to complement duox KG07745, suggesting that Curly mutations indeed reside within the duox locus (Fig 1A). To provide conclusive evidence, however, that duox and Curly are one and the same, we expressed duox ubiquitously in a Curly mutant background. Ubiquitous expression of duox restored viability, allowing recovery of homozygous Curly mutants (Fig 1A). These results strongly suggest that the Curly phenotype is due to mutations in the duox gene.
Curly mutations occur in the NADPH-binding pocket encoding region of duox
To precisely determine how Curly mutations alter duox’s nucleotide sequence, we sequenced duox in two Curly mutants: Cy K, which was previously generated using ethyl methanesulfonate [14]; and Cy 1, the original spontaneous mutation identified by Ward [1]. Remarkably, we found that the same nucleotide was mutated in both Cy K and Cy 1 (Fig 1B). This single nucleotide mutation resulted in the conversion of a conserved glycine (number 1505) in the NADPH binding domain of Duox to a serine in Cy K and to a cysteine in Cy 1 (Fig 1C, red). Among the residues within the NADPH binding pocket of Duox, glycine 1505 is extraordinarily well conserved. It is present in all known NADPH oxidases from yeast to humans (Fig 1D), suggesting that it is functionally important. Therefore a conversion of a conserved glycine to a polar amino acid specifically in the NADPH binding pocket of Duox causes Curly. Taken together, our results demonstrate, after more than 90 years since its discovery, that the Curly phenotype is due to mutations within the duox gene.
Curly is likely a neomorphic allele of duox
Mutations in the NADPH binding encoding region of duox cause a Curly phenotype, but how exactly do they influence Duox’s function? From complementation experiments, it is clear that Curly mutations reduce Duox’s normal function as they are not viable in combination with either a loss-of-function duox mutation or a deficiency uncovering the duox locus (Fig 1A). However, Curly mutants also act dominantly, causing the wings of Curly flies to bend upwards (hence the name) in contrast to the straight wings of wild-type or duox heterozygous flies. One possible explanation is that Curly mutations act in opposition to Duox’s normal activity as dominant negatives or antimorphs. This, however, is unlikely because ubiquitous overexpression of wild-type Duox in a Curly mutant background failed to restore normal wing shape (S1 Fig). Another possibility is that Curly mutations increase the normal function of Duox either by increasing expression or constitutively activating Duox. However, this too seems implausible because removing wild-type Duox in Curly mutants worsened (causing lethality) rather than ameliorated the viability phenotype (Fig 1A). Instead, the most likely explanation is that Curly mutations are neomorphic, causing a dominant gain-of-function in Duox that is different from its normal function.
To further investigate the potential neomorphic nature of Curly mutations, we tested whether Curly mutations require NADPH, the substrate of Duox, to generate a wing phenotype. In the first instance, we attempted to alter the endogenous levels of NADPH by reducing the amount of niacinamide, a precursor of NADPH, in the diet of Curly flies. Interestingly, we found that a reduction of dietary niacinamide caused a dose-dependent decrease in the expressivity of the wing phenotype in Curly mutants (Fig 2A). To test this genetically, we next knocked down CG6145, which encodes a NAD+ kinase that phosphorylates NAD+ to generate NADP+ [15]. Specific knockdown of CG6145 in the wing using apterous-gal4 (apGal4) strongly suppressed the Curly wing phenotype (Fig 2B). Together these results suggest that Curly mutants require NADP+ and/or NADPH in order to cause changes in wing curvature. Therefore, not only do Curly mutations reduce Duox’s normal function, they also endow it with a new function that requires sufficient substrate to dominantly alter wing shape.
Duox is required autonomously in the wing during the last day of development to stabilize the wing
Having determined that Curly is most likely a neomophoric allele of duox, we decided to use Curly mutations to explore duox’s function in vivo in the wing. To do this, we generated a mutant form of duox, henceforth referred to as duox CyK, in which glycine 1505 was mutated to a serine, as in the Cy K mutant. In order to express duox CyK conditionally we fused it to an Upstream Activating Sequence (UAS) element so that we could control its expression in a time-dependent and tissue-specific manner using the Gal4 system [16]. To demonstrate that this transgene was functional and able to recreate the Curly phenotype, we expressed it ubiquitously throughout the fly using tubpGal4 [17]. Indeed, ubiquitous expression of duox CyK, but not wild-type duox, resulted in upward bent wings resembling those of Cy K mutants (Fig 2C and 2D). This not only demonstrates that the duox CyK transgene is functional, but also provides further evidence that Curly is an allele of duox.
Duox could be required autonomously within the wing for its formation, or instead act non-autonomously in other tissues, as is the case for curled, a mutation that causes similar changes in wing morphology [2]. To determine where duox is required, we first expressed duox CyK or duox RNAi in the wing using apGal4. Expression of duox CyK, but not wild-type duox, caused the upward wing curvature, whereas knockdown of duox in the wing caused a slight downward curvature or cupping of the wing (Fig 3A). This demonstrates that duox is required autonomously in the wing for its formation.
Changes in wing curvature can be caused by differential growth between the dorsal and ventral wing surfaces, or could be caused by changes in cuticle structure [3, 4]. If duox CyK were differentially influencing growth, we would expect it to be required early in pupal development, but not later, when proliferation and growth of the ventral and dorsal wing surfaces is largely complete [18]. To determine when in development duox CyK is acting, we conditionally expressed it at various developmental stages using a heat shock-inducible driver. Expression of duox CyK, but not duox, on the last day of pupal development, but not before then, resulted in upturned wings (Fig 3B). This suggests that Duox does not influence wing growth and instead perhaps plays a role in the formation of the wing cuticle. Taken together, our results demonstrate that duox acts autonomously in the wing to stabilize the cuticle during the last day of pupal development concurrent with the formation of the wing cuticle.
Duox works with the heme peroxidase Cysu to stabilize the wing
Hydrogen peroxide generated by NADPH oxidases is often used by peroxidases, most frequently heme peroxidases, to crosslink proteins and kill pathogens [6]. Heme peroxidases are essential for NADPH oxidase-dependent crosslinking reactions, but largely dispensable to their other functions [6]. To test whether Duox acts with a heme peroxidase in the wing to crosslink proteins and stabilize it, we individually knocked down all known D. melanogaster heme peroxidases (Fig 4A) [19] using RNAi in the wings of duox CyK flies. If duox CyK acts alone in the wing and does not participate in crosslinking reactions, then knockdown of heme peroxidases should not affect wing curvature. If, however, duox CyK requires a heme peroxidase to function, then knockdown should suppress the Curly phenotype. Consistent with this, knockdown of one peroxidase, CG5873, fully suppressed the Curly phenotype in a manner resembling duox knockdowns, suggesting that Duox functions together with CG5873 to crosslink molecules to form the wing (Fig 4A). As CG5873 is a suppressor of Curly we have named it Curly Su, or cysu for short.
If cysu acts with duox to form the wing then one would expect it to: a) be expressed in the wing on the last day of development–the period in which Duox functions to form the wing; and b) have a similar phenotype to Duox when silenced in the wing. To test this first prediction, we generated a strain expressing endogenously mCherry-tagged Cysu. Consistent with Cysu functioning in the wing, we observed expression of mCherry-tagged Cysu in the wing on the last day of development using confocal microscopy (Fig 4B). To test our second prediction, we knocked down Cysu in the wing using RNAi. Cysu knockdown caused a slight downturning and cupping of the wing resembling Duox knockdown wings, further suggesting that Cysu and Duox function together to shape the wing (Fig 4C). Interestingly, defects in scutellum and notum formation were also observed in Duox and Cysu knockdowns, suggesting that they might play a broader role in cuticle formation (Fig 4D). Consistent with this, Cysu was expressed in the thorax of wild-type flies, but not Cysu knockdowns (Fig 4E). In summary, Duox and the heme peroxidase Cysu act together to stabilize the wing during development.
Duox is required for adhesion of the dorsal and ventral wing cuticles
The Drosophila adult wing is made up of two cuticle panels that are synthesized and secreted in a step-wise fashion by the dorsal and ventral ectodermal epithelial cells toward the end of pupal development [20, 21]. Upon eclosion, the dorsal and ventral cuticular surfaces of each wing expand and within an hour or so become bonded and adherent to one another [18]. To determine how altering Duox influences wing cuticle formation, we imaged wild-type and duox mutant wings using transmission electron microscopy (Fig 5). In wild-type wings, the ventral and dorsal cuticles are closely apposed and tightly bonded (Fig 5A). By contrast, in Duox knockdown wings the ventral and dorsal cuticles rarely directly contact one another, and instead are separated by a gap filled with disordered, electron poor material (Fig 5B). Interestingly, Curly mutant wings on the other hand appeared much more similar to wild-type wings with occasional abnormal bunching of the dorsal cuticle (Fig 5C). Whether this pinching and bunching reduces the surface area of the dorsal wing causing the wing to curve upward remains unknown. However, ultrastructure experiments clearly demonstrate a role for Duox in the adhesion and bonding of the two cuticle wing surfaces during wing formation.
Discussion
Here we have shown that the Curly mutation arises in the NADPH-binding pocket encoding region of duox. Using Curly mutations and duox RNAi, we show that Duox is required within the wing to maintain its shape beginning on the last day of pupal development. Results from our genetic studies suggest Duox does this by supplying hydrogen peroxide to the heme peroxidase Cysu to facilitate the bonding of the two wing cuticle surfaces, likely by physically crosslinking them, during wing formation.
In all Curly mutants sequenced, a glycine residue, 1505, in the NADPH-binding pocket of Duox is mutated. This glycine is present in all NADPH oxidases from microbial eukaryotes to humans, and more broadly in oxidoreductase and ferric reductase NAD-binding domains (PFAM PF00175 and PF08030, respectively). Though mutagenesis studies have not been conducted on this residue itself, it sits beside an equally conserved cysteine residue, which has been studied in detail because mutations in it cause chronic granulomatous disease in humans [22]. This cysteine residue does not appear to be important for NADPH oxidase assembly or binding NADPH [22, 23]. Instead it is thought to be required for orienting bound NADPH for efficient electron transfer (via hydride) to FAD, and eventually oxygen [22]. Given glycine 1505’s proximity, it is possible that mutations in it similarly affect the transfer of electrons from NADPH to FAD. Consistent with this is the observation that Curly mutants are neither homozygous viable nor viable over a deficiency, suggesting that mutation of glycine 1505 causes a reduction in Duox’s normal function.
Although Curly mutations reduce Duox’s normal function, they also endow it with a new function. Precisely what this new function is remains obscure, however it likely requires a source of electrons because altering the NADPH/NADP+ by removing niacinamide from the food or knocking down NAD+ kinase suppressed the wing phenotype. It is known that the expressivity of the Curly wing phenotype can be suppressed by larval crowding and/or starving larvae [24]. Given this, it is possible that reduced uptake of niacinamide is a cause of the decreased expressivity of the Curly wing phenotype in starved larvae. Riboflavin shortage during the larval stage has also been suggested to be a cause of this suppression [2, 25]. Since riboflavin is a precursor of FAD, a co-factor also necessary for Duox’s function, it too may suppress the wing phenotype by reducing endogenous FAD and in turn reducing Duox’s activity. Regardless, Curly mutations are likely neomorphic and their sensitivity to environmental factors is likely mediated by changes in substrate availability.
Duox is required autonomously for wing stabilization. Results from this study and another strongly support this assertion [10]. Expression of duox CyK or knockdown of duox on the last day prior to eclosion, but not earlier, caused defects in wing morphogenesis. This suggests that Duox and Curly do not influence growth or proliferation of the wing epithelia because these processes are complete by this time [18]. Instead, ultrastructural analysis suggests that Duox plays an important role in forming the cuticle of the wing. In duox knockdowns, frequent gaps between the two wing cuticle surfaces were observed, in contrast to the wild-type wings. Defects in adhesion of the two cuticle surfaces were also apparent in Curly mutants. Unlike wings from duox knockdowns, however, the cuticle surfaces in Curly wings were most often tightly apposed with occasional bunching of the dorsal surface. It is possible that in the Curly mutants this aberrant pinching of the dorsal surface decreases its area relative to the ventral surface causing the wing to bend, as first intimated by Waddington 75 years ago [3]. However, we do not know whether this is the cause of the curling or just a consequence of it.
Duox is known to be involved in the formation of extracellular matrices and cuticles [10–12]. Typically, it does this by supplying hydrogen peroxide to heme peroxidases, which use the hydrogen peroxide to perform crosslinking reactions. Consistent with Duox playing a role in crosslinking the cuticle we found that the heme peroxidase Cysu was essential for Duox function in the wing. Duox is unusual among NADPH oxidases in that it contains its own peroxidase homology domain, which in Caenorhabditis elegans and D. melanogaster has been proposed to fulfill the function of heme peroxidases, thereby obviating their need [7, 26, 27]. However, given that the peroxidase homology domain of Drosophila Duox lacks many amino acid residues, including the proximal and distal histidines, essential for efficient peroxidase function it is unclear how well it functions in this capacity [27]. Indeed, our results suggest that in D. melanogaster, Duox requires the heme peroxidase Cysu not only for stabilizing the wing cuticle, but also in the formation of the notum and scutellum. These findings point to a more general role for Duox and Cysu in cuticle formation.
In Drosophila, Duox has been intensely studied in the context of host defense and gut immunity. In the gut, Duox is thought to generate ROS to kill pathogens; flies that have reduced Duox activity have increased susceptibility to infection [7, 26]. Upon infection ROS generated by Duox kill pathogens, and possibly signal intestinal epithelial cells to proliferate and renew [7, 28]. Our results, as well as others, demonstrate that Duox is also critical in the formation of cuticle structures and extracellular matrices [10–12]. It is possible that Duox performs a similar function in the Drosophila intestine, perhaps by forming extracellular barriers or structures to protect against infection. Indeed, Duox in conjunction with heme peroxidases has been shown to form such barriers in guts of ticks and mosquitos [29, 30]. It would therefore be interesting to explore whether Duox and possibly Cysu are also involved in forming barriers to protect against infection in the Drosophila intestine.
Duox is an important protein that has a number of diverse functions, which we are only beginning to understand. Curly mutations provide an excellent opportunity to further explore Duox’s functions by identifying unknown interactors and regulators through unbiased genetic suppressor screens. The identification of Cysu through such an approach demonstrates its feasibility and utility. Such approaches will not only tell us about Duox’s function in the wing, but also about its role in immunity and beyond.
Materials and Methods
Drosophila husbandry and strains
Flies were propagated in polystyrene vials (28.5 mm diameter) containing cornmeal molasses yeast medium at 25°C. For most crosses 5 virgin females were mated with 3 to 5 males. Fly strains used are shown in Table 1.
Table 1. Drosophila strains.
Name | Genotype | Reference/source |
---|---|---|
duox KG07745 | y[1];P{y[+mDint2]w[BR.E.BR] = SUPor-P} | BDSC (16468) |
Duox[KG07745]/In(2LR)Gla,wg[Gla-1]Bc[1] | ||
duox Df | Df(2L)C144,dpp[d-ho] ed[1]/ | BDSC (90) |
In(2LR)Gla,wg[Gla-1]Bc[1] Egfr[E1] | ||
Cy 1 | T(2;3)Scar, Scar[1]/Cy[1] | BDSC (880) |
Cy K | Cy[K]/In(2LR)Gla | BDSC (26167) |
act5C-gal4 | y[1]w[*];P{w[+mC] = Act5C-GAL4}17bFO1/TM6B, Tb[1] | BDSC (3954) |
apGal4 | y w; P[w +, ap-GAL4]/CyO | J. Treisman lab |
uas-duox | y[-]v[-];;attP2-pVALIUM22-duox/TM3 Ser (colony 12042-1-1M) | This study |
uas-duox CyK | y[-]v[-];;attP2-pVALIUM22-duox[CyK]/TM3 Ser (colony 12042-4-1M) | This study |
uas-duox RNAi | ;UASt-dDuoxIR976-1145/CyO | Won-Jae Lee |
HS-gal4 | ;hs-gal4/CyO | R. Lehmann lab |
CG6145 RNAi | P{KK106577}VIE-260B | VDRC (104271/KK) |
Pxn RNAi | P{KK108816}VIE-260B | VDRC (107180/KK) |
w 1118 ; P{GD5987}v15276 | VDRC (15276/GD) | |
w 1118 P{GD5987}v15277 | VDRC (15277/GD) | |
CG10211 RNAi | w 1118 ; P{GD5320}v12352/TM3 | VDRC (12352/GD) |
cysu RNAi | w 1118 ; P{GD6190}v14374 | VDRC (14374/GD) |
Pxt RNAi | w 1118 ; P{GD6192}v14377 | VDRC (14377/GD) |
w 1118 ; P{GD6192}v14379 | VDRC (14379/GD) | |
P{KK103684}VIE-260B | VDRC (104446/KK) | |
cd RNAi | w 1118 ; P{GD3115}v6831/CyO | VDRC (6831/GD) |
CG42331 RNAi | w 1118 P{GD12065}v22456 | VDRC (22456/GD) |
P{KK110316}VIE-260B | VDRC (104585/KK) | |
P{KK105949}VIE-260B | VDRC (104226/KK) | |
Pxd RNAi | w 1118 ; P{GD16228}v48587 | VDRC (48587/GD) |
w 1118 ; P{GD16228}v48588 | VDRC (48588/GD) | |
Irc RNAi | P{KK106899}VIE-260B | VDRC (101098/KK) |
cysu::mCherry | ;;Mi{pBS-KS-attB1-PT-SA-SD-2-mCherry}CG5873[MI11428] | This study |
tubpGal4 | y[1]w[*];P{w[+mC] = tubP-GAL4}LL7/TM3, Sb[1] | BDSC (5138) |
uast-duox | ;uast-duox | Won-Jae Lee |
Conditional expression of duox and duoxCyK
duox and duox CyK were conditionally expressed using a gal4 driver downstream of the heat-shock (HS) protein 70 promoter (HS-gal4). At various times during development Drosophila were incubated at 37°C for 2 hours to induce expression.
duoxKG07745 (BDSC 16468)
To verify the location of P{SUPor-P}Duox KG07745 we performed inverse PCR. Consistent with the FlyBase report (FBal0226250) the 3’ flanking sequence was at genomic position 2L:2,826,884. However, unexpectedly, we found the 5’ flanking sequence to be at position 2L:2,755,447. This suggests that P{SUPor-P}Duox KG07745 contains a deletion that perturbes 17 genes from Bacc to duox.
Generation of uas-duox and uas-duoxCyK strains
The duox open reading frame was amplified from cDNA and cloned into the pVALIUM22 vector [31] between XbaI and EcoRI restriction sites using standard methods. The Cy K mutation was generated by site-directed mutagenesis using a QuikChange site-directed mutagenesis kit. Constructs were integrated into the attP2 site on the third chromosome using phiC31 integrase by BestGene.
Generation of Cysu::mCherry strain
mCherry-tagged Cysu expressing flies were made by BestGene by injecting mimic construct #1315 into Mi{MIC}CG5873MI11428 (BDSC 56608) [32].
DNA sequencing
Genomic DNA was crudely isolated by homogenizing one to two flies in 0.2 mg/ml Proteinase K (Roche MC00079), 10 mM Tris pH 8.0, 1 mM EDTA and 25 mM NaCl and incubating for 25 min at 55°C. Proteinase K was subsequently inactivated by boiling the samples for 5 min. duox was then PCR amplified from genomic DNA and sequenced by Genewiz.
Niacinamide medium
Flies were raised on a defined medium with various concentration of niacinamide from embryo to adult. A solution was prepared as described in Table 2 and the pH was adjusted to 7.0 with NaOH. 20 mg/ml agar yeast culture grade (Sunrise Science Products 1910) was dissolved in the solution by heating before adding 0.4 mg/ml cholesterol (Sigma C3045) and niacinamide (Sigma N0636).
Table 2. Niacinamide medium.
Material | Volume | Concentration |
---|---|---|
H2O | to 500 ml | |
50x BME amino acid solution (Sigma B6766) | 50 ml | 5X |
L-glutamate potassium salt (Sigma G1149) | 500 mg | 1.0 mg/ml |
Glycine (Sigma G-7126) | 200 mg | 0.4 mg/ml |
Sucrose (Sigma | 3.75 g | 7.5 mg/ml |
Biotin (Sigma B4639) | 500 μl 10 mg/ml stock | 0.02 μg/ml |
B12 (Sigma V6629) | 500 μl 14 mg/ml stock | 0.028 μg/ml |
Choline chloride (Sigma C7527) | 37.5 mg | 75 μg/ml |
Ca-pantothenate (Sigma C8731) | 3 mg | 6 μg/ml |
Pyridoxin-HCl (Sigma P6280) | 1.5 mg | 3 μg/ml |
Riboflavin (Sigma R-0508) | 1.2 mg | 2.4 μg/ml |
Thiamine-HCl (Sigma T1270) | 0.75 mg | 1.5 μg/ml |
Folic acid (Sigma F858) | 18 mg | 36 μg/ml |
MnCl2.4 H2O (Sigma M3634) | 24 mg | 48 μg/ml |
MgSO4.7 H2O (Sigma M-9397) | 123 mg | 0.246 mg/ml |
K2HPO4 (P285-500 Fischer) | 303 mg | 0.606 mg/ml |
KH2PO4 (P288-500 Fischer) | 303 mg | 0.606 mg/ml |
NaCl (Sigma S7653) | 6.45 mg | 0.0129 mg/ml |
CaCl2 (Sigma C-5080) | 6.45 mg | 0.0129 mg/ml |
FeSO4.6 H2O (Sigma F8633) | 11.8 mg | 0.0129 mg/ml |
Imaging
Fluorescent images were acquired with a 10X/NA objective on a Zeiss LSM 780 confocal microscope. All other images were obtained with a Zeiss SteREO Discovery.V8 microscope.
Transmission electron microscopy
For transmission electron microscopy, whole flies were immersed in 95% ethanol briefly to get rid of any air bubbles, decapitated and immersed into fixative containing 4% glutaraldehyde in 0.1M PIPES buffer, pH 7.2 at room temperature for 2 hours, and then overnight at 4°C. Flies were next embedded in 1% agar and post-fixed with 2% osmium tetroxide with 1.5% potassium ferricyanide in 0.1M PIPES buffer for 1 hour then en block stained with 1% uranyl acetate in ddH2O at 4°C overnight. Samples were dehydrated with ethanol at room temperature before incubation with propylene oxide and embedment in Spurr resin (Electron Microscopy Sciences, Hatfield, PA). 500nm semi-thin sections were stained with 0.1% toluidine blue to evaluate the area of interest. 60nm ultrathin sections were cut, mounted on formvar coated slotted copper grids and stained with uranyl acetate and lead citrate by standard methods. Stained grids were examined under Philips CM-12 electron microscope (FEI; Eindhoven, The Netherlands) and photographed with a Gatan (4k x2.7k) digital camera (Gatan, Inc., Pleasanton, CA).
Supporting Information
Acknowledgments
We would like to thank Jessica Treisman and Won-Jae Lee for kindly providing Drosophila strains. We thank Allison Blum and Lacy Barton for their critical reading of the manuscript. We thank Chris Petzold and Kristen Manning-Dancel of the NYULMC OCS Microscopy Core for their assistance with transmission electron microscopy. We acknowledge the DGRC and Bloomington Stock Center for reagents.
Data Availability
All data are contained within this manuscript.
Funding Statement
TRH was supported by a fellowship from the Canadian Institute of Health Research. RL is an investigator of the Howard Hughes Medical Institute. The funders had no role in study design, data collection andanalysis, decision to publish, or preparation of the manuscript.
References
- 1. Ward L. The Genetics of Curly Wing in Drosophila. Another Case of Balanced Lethal Factors. Genetics. 1923;8(3):276–300. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 2. Gronke S, Bickmeyer I, Wunderlich R, Jackle H, Kuhnlein RP. Curled encodes the Drosophila homolog of the vertebrate circadian deadenylase Nocturnin. Genetics. 2009;183(1):219–32. 10.1534/genetics.109.105601 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 3. Waddington C. The genetic control of wing development in Drosophila. Journal of Genetics. 1940;41:75–139. [Google Scholar]
- 4. Lee JH, Budanov AV, Park EJ, Birse R, Kim TE, Perkins GA, et al. Sestrin as a feedback inhibitor of TOR that prevents age-related pathologies. Science. 2010;327(5970):1223–8. 10.1126/science.1182228 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 5. Sturtevant AH, Novitski E. The Homologies of the Chromosome Elements in the Genus Drosophila. Genetics. 1941;26(5):517–41. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 6. Bedard K, Krause KH. The NOX family of ROS-generating NADPH oxidases: physiology and pathophysiology. Physiological reviews. 2007;87(1):245–313. 10.1152/physrev.00044.2005 [DOI] [PubMed] [Google Scholar]
- 7. Kim SH, Lee WJ. Role of DUOX in gut inflammation: lessons from Drosophila model of gut-microbiota interactions. Frontiers in cellular and infection microbiology. 2014;3:116 10.3389/fcimb.2013.00116 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 8. De Deken X, Wang D, Many MC, Costagliola S, Libert F, Vassart G, et al. Cloning of two human thyroid cDNAs encoding new members of the NADPH oxidase family. J Biol Chem. 2000;275(30):23227–33. 10.1074/jbc.M000916200 [DOI] [PubMed] [Google Scholar]
- 9. Dupuy C, Ohayon R, Valent A, Noel-Hudson MS, Deme D, Virion A. Purification of a novel flavoprotein involved in the thyroid NADPH oxidase. Cloning of the porcine and human cdnas. J Biol Chem. 1999;274(52):37265–9. [DOI] [PubMed] [Google Scholar]
- 10. Anh NT, Nishitani M, Harada S, Yamaguchi M, Kamei K. Essential role of Duox in stabilization of Drosophila wing. J Biol Chem. 2011;286(38):33244–51. 10.1074/jbc.M111.263178 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 11. Edens WA, Sharling L, Cheng G, Shapira R, Kinkade JM, Lee T, et al. Tyrosine cross-linking of extracellular matrix is catalyzed by Duox, a multidomain oxidase/peroxidase with homology to the phagocyte oxidase subunit gp91phox. J Cell Biol. 2001;154(4):879–91. 10.1083/jcb.200103132 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 12. Wong JL, Creton R, Wessel GM. The oxidative burst at fertilization is dependent upon activation of the dual oxidase Udx1. Dev Cell. 2004;7(6):801–14. 10.1016/j.devcel.2004.10.014 [DOI] [PubMed] [Google Scholar]
- 13. Littleton JT, Bellen HJ. Genetic and phenotypic analysis of thirteen essential genes in cytological interval 22F1-2; 23B1-2 reveals novel genes required for neural development in Drosophila. Genetics. 1994;138(1):111–23. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 14.Cook K. Mutations from Jim Kennison. In: FlyBase, editor. http://flybase.org/reports/FBrf0206482.html2008.
- 15. Magni G, Orsomando G, Raffaelli N. Structural and functional properties of NAD kinase, a key enzyme in NADP biosynthesis. Mini Rev Med Chem. 2006;6(7):739–46. [DOI] [PubMed] [Google Scholar]
- 16. Brand AH, Perrimon N. Targeted gene expression as a means of altering cell fates and generating dominant phenotypes. Development. 1993;118(2):401–15. [DOI] [PubMed] [Google Scholar]
- 17. Bello BC, Hirth F, Gould AP. A pulse of the Drosophila Hox protein Abdominal-A schedules the end of neural proliferation via neuroblast apoptosis. Neuron. 2003;37(2):209–19. [DOI] [PubMed] [Google Scholar]
- 18. Kiger JA Jr., Natzle JE, Kimbrell DA, Paddy MR, Kleinhesselink K, Green MM. Tissue remodeling during maturation of the Drosophila wing. Dev Biol. 2007;301(1):178–91. 10.1016/j.ydbio.2006.08.011 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 19. Hughes AL. Evolution of the Heme Peroxidases of Culicidae (Diptera). Psyche. 2012;2012. [Google Scholar]
- 20. Moussian B. Recent advances in understanding mechanisms of insect cuticle differentiation. Insect Biochem Mol Biol. 2010;40(5):363–75. 10.1016/j.ibmb.2010.03.003 [DOI] [PubMed] [Google Scholar]
- 21. Doctor J, Fristrom D, Fristrom JW. The pupal cuticle of Drosophila: biphasic synthesis of pupal cuticle proteins in vivo and in vitro in response to 20-hydroxyecdysone. J Cell Biol. 1985;101(1):189–200. [DOI] [PMC free article] [PubMed] [Google Scholar]
- 22. Debeurme F, Picciocchi A, Dagher MC, Grunwald D, Beaumel S, Fieschi F, et al. Regulation of NADPH oxidase activity in phagocytes: relationship between FAD/NADPH binding and oxidase complex assembly. J Biol Chem. 2010;285(43):33197–208. 10.1074/jbc.M110.151555 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 23. Aliverti A, Piubelli L, Zanetti G, Lubberstedt T, Herrmann RG, Curti B. The role of cysteine residues of spinach ferredoxin-NADP+ reductase As assessed by site-directed mutagenesis. Biochemistry. 1993;32(25):6374–80. [DOI] [PubMed] [Google Scholar]
- 24. Nozawa K. The effects of the environmental conditions on Curly expressivity in Drosophila melanogaster. The Japanese Journal of Genetics. 1965;31(6):163–71. [Google Scholar]
- 25. Pavelka J, Jindrak L. Mechanism of the fluorescent light induced suppression of Curly phenotype in Drosophila melanogaster. Bioelectromagnetics. 2001;22(6):371–83. [DOI] [PubMed] [Google Scholar]
- 26. Ha EM, Oh CT, Bae YS, Lee WJ. A direct role for dual oxidase in Drosophila gut immunity. Science. 2005;310(5749):847–50. 10.1126/science.1117311 [DOI] [PubMed] [Google Scholar]
- 27. Meitzler JL, Brandman R, Ortiz de Montellano PR. Perturbed heme binding is responsible for the blistering phenotype associated with mutations in the Caenorhabditis elegans dual oxidase 1 (DUOX1) peroxidase domain. J Biol Chem. 2010;285(52):40991–1000. 10.1074/jbc.M110.170902 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 28. Buchon N, Broderick NA, Chakrabarti S, Lemaitre B. Invasive and indigenous microbiota impact intestinal stem cell activity through multiple pathways in Drosophila. Genes Dev. 2009;23(19):2333–44. 10.1101/gad.1827009 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 29. Kumar S, Molina-Cruz A, Gupta L, Rodrigues J, Barillas-Mury C. A peroxidase/dual oxidase system modulates midgut epithelial immunity in Anopheles gambiae. Science. 2010;327(5973):1644–8. 10.1126/science.1184008 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 30. Yang X, Smith AA, Williams MS, Pal U. A dityrosine network mediated by dual oxidase and peroxidase influences the persistence of Lyme disease pathogens within the vector. J Biol Chem. 2014;289(18):12813–22. 10.1074/jbc.M113.538272 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 31. Ni JQ, Liu LP, Binari R, Hardy R, Shim HS, Cavallaro A, et al. A Drosophila resource of transgenic RNAi lines for neurogenetics. Genetics. 2009;182(4):1089–100. 10.1534/genetics.109.103630 [DOI] [PMC free article] [PubMed] [Google Scholar]
- 32. Venken KJ, Schulze KL, Haelterman NA, Pan H, He Y, Evans-Holm M, et al. MiMIC: a highly versatile transposon insertion resource for engineering Drosophila melanogaster genes. Nat Methods. 2011;8(9):737–43. [DOI] [PMC free article] [PubMed] [Google Scholar]
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