Caterpillar color patterns are determined by a two‐phase melanin gene prepatterning process: new evidence from tan and laccase2

SUMMARY The larval color patterns in Lepidoptera exhibit splendid diversity, and identifying the genes responsible for pigment distribution is essential to understanding color‐pattern evolution. The swallowtail butterfly, Papilio xuthus, is a good candidate for analyzing marking‐associated genes because its body markings change dramatically at the final molt. Moreover, the silkworm Bombyx mori is most suitable for identification of lab‐generated color mutants because genome information and many color mutants are available. Here, we analyzed the expression pattern of 10 melanin‐related genes in P. xuthus, and analyzed whether these genes were responsible for Bombyx larval color mutants. We found that seven genes correlated strongly with the stage‐specific larval cuticular markings of P. xuthus, suggesting that, compared with Drosophila, more genes showed marking specificity in lepidopteran larvae. We newly found that the expression of both tan and laccase2 is strongly correlated with the larval black markings in both P. xuthus and B. mori. The results of F2 linkage analysis and mutant analysis strongly suggest that tan is the responsible gene for Bombyx larval color mutant rouge, and that tan is important in emphasizing black markings of lepidopteran larvae. Detailed comparison of temporal and spatial expression patterns showed that larval cuticular markings were regulated at two different phases. Marking‐specific expression of oxidizing enzymes preceded the marking‐specific expression of melanin synthesis enzymes at mRNA level, which is the reverse of the melanin synthesis step.     

Species‐specific coordinated gene expression and trans‐regulation of larval color pattern in three swallowtail butterflies

SUMMARY The diversity of butterfly larval color pattern has been attracted to people since Darwin's time; however, its molecular mechanisms still remain largely unknown. Larval body markings often differ completely between closely related species under natural selection. The final instar larvae of the swallowtail butterflies Papilio xuthus and Papilio polytes show a green camouflage pattern, whereas those of Papilio machaon show a warning color pattern, although P. xuthus and P. machaon are closely related species. To identify the genes that contribute to species divergence, we compared the expression pattern of eight pigment‐associated genes between three Papilio species. The spatial expression pattern of melanin‐related genes coincided with the species‐specific cuticular markings. We newly found that the combination of bilin‐binding protein and yellow‐related gene (YRG) correlated perfectly with larval blue, yellow, and green coloration. To distinguish whether the interspecific differences in pigment‐associated genes are caused by cis‐regulatory changes or distribution differences in trans‐regulatory proteins, we compared species‐specific mRNA expression in an F1 hybrid specimen. Px‐YRG and Pp‐YRG showed a similar expression pattern, suggesting that the change in expression of YRG is caused mainly by changes in the distribution of trans‐regulatory proteins. Our findings shed light on the gene regulatory networks for butterfly larval color pattern.     

Expression of one isoform of GTP cyclohydrolase I coincides with the larval black markings of the swallowtail butterfly, Papilio xuthus

The larva of the swallowtail butterfly Papilio xuthus changes its body markings during the fourth ecdysis. We found that stage-specific cuticular black markings are mainly regulated by co-localization of two melanin synthesis enzymes; tyrosine hydroxylase (TH) and dopa decarboxylase (DDC). TH converts tyrosine to dihydroxyphenylalanine (dopa), and tyrosine itself is converted from phenylalanine by phenylalanine hydroxylase (PAH). Guanosine triphosphate cyclohydrolase I (GTPCHI) is essential for the synthesis of tetrahydrobiopterin (BH4) that is a cofactor of TH and PAH. In this report, we found that a GTPCHI inhibitor prevents pigmentation in cultured integuments, suggesting that the GTPCHI activity is also involved in cuticle pigmentation. We have cloned GTPCHI and PAH cDNAs from P. xuthus and investigated their spatial expression patterns in epidermis by whole-mount in situ hybridization. There are two isoforms of GTPCHI in larval epidermis (GTPCHIa and GTPCHIb). GTPCHIa is expressed at the black markings of the subsequent instar, similar to TH, whereas GTPCHIb is expressed uniformly, similar to PAH. This suggests that the region-specific expression of GTPCHIa supplies sufficient BH(4) reinforcing the TH activity in black marking area. Our results imply that larval markings are regulated by not only melanin synthesis enzymes but also the cofactor supplying enzyme.     

Temporal programming of epidermal cell protein synthesis during the larval-pupal transformation ofManduca sexta

Summary During the final larval instar the epidermis of the tobacco hornworm,Manduca sexta, synthesizes the larval cuticular proteins and the pigment insecticyanin. Then at the onset of metamorphosis the cells first become pupally-committed, then later produce the pupal cuticle. The changes in the pattern of epidermal protein synthesis during this period were followed by incubating the integument in vitro with either³H-leucine or³⁵S-methionine, then analyzing the proteins by 2-dimensional gel electrophoresis. Precipitation by larval and pupal cuticular antisera and by insecticyanin antibody identified these proteins. Three distinct changes in epidermal protein synthesis were noted: 1) Stage-specific proteins, some of which are larval cuticular proteins, appear just before and during the change of commitment on day 3. (2) By late the following day (wandering stage), synthesis of these and many other proteins including all the identified larval cuticular proteins and insecticyanin was undetectable. Several noncuticular proteins were transiently synthesized by this pupally committed cell during wandering and sometimes the following day. (3) During the production of pupal cuticle a new set of pupal-specific cuticular proteins as well as some common cuticular proteins (precipitated by both antisera) were synthesized. Some of the latter were also synthesized during the period between pupal commitment and pupal cuticle deposition.In spite of an apparent absence of methionine in both larval and pupal cuticle, many cuticular proteins incorporated³⁵S-methionine. Thus they may be synthesized as proproteins.Insecticyanin was shown to have two forms differing in isoelectric point, the cellular form being more acidic than the hemolymph form. Synthesis of the cellular form ceased before that of the hemolymph form.     

MELANIN AND URATE ACT TO PREVENT ULTRAVIOLET DAMAGE IN THE INTEGUMENT OF THE SILKWORM,BOMBYX mori

The phenomenon that epidermal cells under the white stripes rather than black stripes contain many uric acid granules was found in larvae of several Lepidopteran species. However, the biological mechanism of this phenomenon is still unknown. In the present study, we take advantage of several silkworm (Bombyx mori) body color mutant strains to investigate the deposition patterns and biological mechanism of urate and melanin in the integuments of these mutant larvae. By imaging with transmission electron microscope, we found that there were some melanin granules in the larval cuticle in black body color mutant plain Black (p^B), but not in background strain plain (p) with white larval body color. In contrast, the larval epidermal cell of background strain had much more urate granules than that of black one. Furthermore, the uric acid content under the black stripes was significantly lower than that under the white stripes in a single individual of mottled stripe (p^S) with black and white stripes in each segment. Ultraviolet A (UVA) exposure experiments showed that the distinct oily (od) mutant individuals with translucent larval integument were more sensitive to the UVA damage than black body color mutant and background strain without any pigmentation in the larval cuticle. This is likely due to the absence of melanin granules and few urate granules in the integument of od mutant. Thus, both the deposited melanin granules in the cuticle and the abundant urate granules in the epidermis cells constitute effective barriers for the silkworm to resist UVA‐induced damage.     

The TSC1/2 Complex Controls Drosophila Pigmentation through TORC1-Dependent Regulation of Catecholamine Biosynthesis

In Drosophila, the pattern of adult pigmentation is initiated during late pupal stages by the production of catecholamines DOPA and dopamine, which are converted to melanin. The pattern and degree of melanin deposition is controlled by the expression of genes such as ebony and yellow as well as by the enzymes involved in catecholamine biosynthesis. In this study, we show that the conserved TSC/TORC1 cell growth pathway controls catecholamine biosynthesis in Drosophila during pigmentation. We find that high levels of Rheb, an activator of the TORC1 complex, promote premature pigmentation in the mechanosensory bristles during pupal stages, and alter pigmentation in the cuticle of the adult fly. Disrupting either melanin synthesis by RNAi knockdown of melanogenic enzymes such as tyrosine hydroxylase (TH), or downregulating TORC1 activity by Raptor knockdown, suppresses the Rheb-dependent pigmentation phenotype in vivo. Increased Rheb activity drives pigmentation by increasing levels of TH in epidermal cells. Our findings indicate that control of pigmentation is linked to the cellular nutrient-sensing pathway by regulating levels of a critical enzyme in melanogenesis, providing further evidence that inappropriate activation of TORC1, a hallmark of the human tuberous sclerosis complex tumor syndrome disorder, can alter metabolic and differentiation pathways in unexpected ways.     

Melanin pigmentation gives rise to black spots on the wings of the silkworm Bombyx mori

Several mutants of the silkworm Bombyx mori show body color variation at the larval and adult stages. The Wild wing spot (Ws) mutant exhibits a phenotype in which the moth has a spot on the apex of the forewing. In this study, we investigated this trait to elucidate the molecular mechanism underlying the color pattern. Microscopy of the black spot of Ws mutants showed that the pigment emerges in the scales of the wing, and accumulation of the pigment becomes strong just before eclosion. We next examined the relationship between the black spot of the Ws mutant and melanin. The spectrophotometry using alkaline extracts from the black spot in the wing showed the highest absorption intensity at 405 nm, which is the absorbance wavelength of melanin. Moreover, inhibition assays for enzymes implicated in melanin synthesis using 3-iodo-l-tyrosine (a tyrosine hydroxylase inhibitor) and L-α-methyl-DOPA (a dopa decarboxylase inhibitor) revealed that treatment with each inhibitor disrupted the pigmentation of the wing of the Ws mutant. On the basis of these results, we analyzed the expression pattern of five genes involved in melanin formation, and found that the expression levels of yellow and laccase2 were increased just before pigmentation, whereas those of DDC, tan, and TH were increased when the apex of the wing turned black. These results showed that melanin pigmentation gives rise to the black spot on the wing.     

Regulation of 20-hydroxyecdysone on the larval pigmentation and the expression of melanin synthesis enzymes and yellow gene of the swallowtail butterfly, Papilio xuthus

The swallowtail butterfly, Papilio xuthus, changes its larval body pattern dramatically during the fourth ecdysis. Cuticular pigmentation occurs with precise timing just before ecdysis. We previously found that the cuticular pigmentation was regulated by three melanin synthesis genes, tyrosine hydroxylase (TH), dopa decarboxylase (DDC), and ebony. We discovered that yellow is strongly expressed in the presumptive black markings earlier than TH and DDC. Because the ecdysis is triggered by 20-hydroxyecdysone (20E), the effects of 20E on the pigmentation and expression of the melanin synthesis genes were examined. Here, we established a method for the topical application of 20E to molting specimens, so that 20E has only a partial effect, resulting in successful ecdysis. When we applied 20E during the mid-phase of the molting period, when the 20E titer is declining, cuticular pigmentation was completely inhibited. The cessation of hormonal treatments caused delayed pigmentation. yellow expression was promoted by a high titer of 20E, whereas the expression of TH, DDC, and ebony was suppressed, suggesting that a decline in the 20E concentration is necessary for the induction of the expression of the latter three genes. These results indicate that cuticular pigmentation is controlled by the exposure to 20E and its removal.     

Mechanisms of black and white stripe pattern formation in the cuticles of insect larvae

Molecular mechanisms that produce pigment patterns in the insect cuticle were studied. Larvae of the armyworm Pseudaletia separata have stripe patterns that run longitudinally along the body axis. The pattern in the cuticle became clear by being emphasized by the increasing contrast between the black and white colors of the lines after the last larval molt. We demonstrated that dopa decarboxylase (DDC) mRNA as well as protein are expressed specifically in the epidermal cells under the black stripes. The pigmentation on the stripes was clearly diminished by injection of a DDC inhibitor (m-hydroxybenzylhydrazine) to penultimate instar larvae for 1 day before molting, suggesting that DDC contributes to the production of melanin. Further, electron microscopic observation showed that the epidermal cells under the gap cuticle region (white stripe) between the black stripes contain many uric acid granules, which gives a white color. Our findings suggest that the spatially regulated expression of DDC in the epidermal cells produces the black stripes while abundant granules of uric acid in the cells generate the white stripes in the cuticle. Based on these results, we concluded that this heterogeneity in the epidermal cells forms cuticular stripe patterns in the armyworm larvae.     

The contribution of the melanin pathway to overall body pigmentation during ontogenesis of Periplaneta americana

The most prominent colors observed in insects are black or brown, whose production is attributed to the melanin pathway. At present, though, the contribution of this pathway to overall body pigmentation throughout ontogenesis is still lacking. To address this question we examined the roles of 2 key melanin genes (TH and DDC), in embryonic and postembryonic development of the American cockroach, Periplaneta americana. Our results show that the melanin pathway does not contribute to the light brown coloration observed in the first nymphs. However, the dark brown coloration in mid nymphs and adults is produced solely from the melanin pathway. In addition, the DDC RNAi results reveal that it is dopamine melanin, not DOPA melanin, acts as the main contributor in this process. Overall, present study provides a new insight into insect pigmentation suggesting that genetic mechanisms of coloration can change during ontogenesis. Future studies of additional basal insect lineages will be required to assess in more details the generality of this phenomenon.     

Live Cell Imaging of Butterfly Pupal and Larval Wings In Vivo

Butterfly wing color patterns are determined during the late larval and early pupal stages. Characterization of wing epithelial cells at these stages is thus critical to understand how wing structures, including color patterns, are determined. Previously, we successfully recorded real-time in vivo images of developing butterfly wings over time at the tissue level. In this study, we employed similar in vivo fluorescent imaging techniques to visualize developing wing epithelial cells in the late larval and early pupal stages 1 hour post-pupation. Both larval and pupal epithelial cells were rich in mitochondria and intracellular networks of endoplasmic reticulum, suggesting high metabolic activities, likely in preparation for cellular division, polyploidization, and differentiation. Larval epithelial cells in the wing imaginal disk were relatively large horizontally and tightly packed, whereas pupal epithelial cells were smaller and relatively loosely packed. Furthermore, larval cells were flat, whereas pupal cells were vertically elongated as deep as 130 μm. In pupal cells, many endosome-like or autophagosome-like structures were present in the cellular periphery down to approximately 10 μm in depth, and extensive epidermal feet or filopodia-like processes were observed a few micrometers deep from the cellular surface. Cells were clustered or bundled from approximately 50 μm in depth to deeper levels. From 60 μm to 80 μm in depth, horizontal connections between these clusters were observed. The prospective eyespot and marginal focus areas were resistant to fluorescent dyes, likely because of their non-flat cone-like structures with a relatively thick cuticle. These in vivo images provide important information with which to understand processes of epithelial cell differentiation and color pattern determination in butterfly wings.     

Development of plant cuticles: fine structure and cutin composition of Clivia miniata Reg. leaves

The fine structure and monomeric composition of the ester-cutin fraction (susceptible to BF₃/CH₃OH transesterification) of the adaxial leaf cuticle of Clivia miniata Reg. were studied in relation to leaf and cuticle development. Clivia leaves grow at their base such that cuticle and tissues increase in age from the base to the tip. The zone of maximum growth (cell expansion) was located between 1 and 4 cm from the base. During cell expansion, the projected surface area of the upper epidermal cells increased by a factor of nine. In the growth region the cuticle consists mainly of a polylamellate cuticle proper of 100–250 nm thickness. After cell expansion has ceased both the outer epidermal wall and the cuticle increase in thickness. Thickening of the cuticle is accomplished by interposition of a cuticular layer between the cuticle proper and the cell wall. The cuticular layer exhibits a reticulate fine structure and contributes most of the total mass of the cuticle at positions above 6 cm from the leaf base. The composition of ester cutin changed with the age of cuticles. In depolymerisates from young cuticles, 26 different monomers could be detected whereas in older ones their number decreased to 13. At all developmental stages, 9,16-/10,16-dihydroxyhexadecanoic acid (positional isomers not separated), 18-hydroxy-9-octadecenoic acid, 9,10,18-trihydroxyoctadecanoic acid and 9,10-epoxy-18-hydroxyoctadecanoic acid were most frequent with the epoxy alkanoic acid clearly predominating (47% at 16 cm). The results are discussed as to (i) the age dependence of cutin composition, (ii) the relationship between fine structure and composition, (iii) the composition of the cuticle proper, the cuticular layer and the non-depolymerizable cutin fraction, and (iv) the polymeric structure of cutin.Abbreviations CL cuticular layer - CP cuticle proper - MX cutin polymer matrix     

Identification of a cuticle protein with unique repeated motifs in the silkworm,Bombyx mori

The insect cuticle is non-cellular matrix secreted from a monolayer of epidermal cells. After abrasion of the larval cuticle of the silkworm, Bombyx mori, a protein with molecular mass of 135 kDa is newly detected in the cuticle. Mass spectrometric analysis of the tryptic fragments from this protein revealed that the 135-kDa protein is encoded by the Cb10 gene. In the predicted amino acid sequence of Cb10, three repeated motifs with [YxGGFGGppG(L/V)L] sequence are found in the C-terminal region. In addition to the repeated motifs, Cb10 has seventeen CxxxxC motifs randomly distributed throughout the polypeptide chain and serine rich region at the N-terminal region. The Cb10 gene is strongly expressed in epidermal cells after pupal ecdysis, and its expression in the larval epidermal cells is induced not only by cuticular abrasion, but also by bacterial infection. These expression patterns suggest some specific roles of this protein in pupal cuticle formation and defense reactions.     

Cuticular and non-cuticular substrate influence on expression of cuticle-degrading enzymes from conidia of an entomopathogenic fungus,Nomuraea rileyi

Larval cuticle fromTrichoplusia ni, Helicoverpa (=Heliothis)zea, andHeliothis virescens and a cellulose substrate were used to quantify release of proteolytic, chitinolytic, and lipolytic enzymes by germinating conidia of the entomopathogenic fungus,Nomuraea rileyi. There was no significant difference in conidial viability incubated withT. ni, H. zea or cellulose substrates. Conidial viability onH. virescens cuticle, however, was significantly lower (ca. 19–25%) than the other three substrates. The presence of cuticle substrates, especially cuticle ofT. ni, stimulated germination. The nature of the substrate influenced both the time and quantity of the enzymes expressed. Specific proteases (aminopeptidase, chymoelastase, trypsin) generally were expressed earlier and/or in greater quantities on cuticular than on the cellulose substrate. Although both chitinolytic enzymes (endochitinase, N-acetylglucosaminidase) were detected on all three cuticular substrates, their activity was substantially lower than that of the proteolytic enzymes. Lipase activity was only minimally present. Early concurrent release of both proteases and chitinases suggested that both may be important in the penetration of the larval integument by germinating conidia ofN. rileyi. Expression of proteases and chitinases, especially aminopeptidase and endochitinase was probably a specific response to cuticle, because little or no activity was expressed on the non-host, cellulose substrate.This article reports the results of research only. Mention of a proprietary product in this paper does not constitute a recommendation for use by the US Department of Agriculture.     

Segmental organisation of the tail region in the embryo of Drosophila melanogaster

Summary The segmental organisation of the tail region in the embryo of Drosophila melanogaster, which is defined here as the epidermal region posterior to the boundary between abdominal segments A7 and A8, has been investigated by means of ultraviolet (UV) laser fate-mapping and phenotypic analysis of embryonic mutants that alter the segmental pattern of the larval cuticle. Wild-type embryos were irradiated in the presumptive tail region with a UV- laser microbeam of 20 m diameter at the blastoderm stage. The ensuing defects were scored in the cuticle pattern of the tail region of the first-instar larva, which is described in detail in this paper. The spatial distribution of defect frequencies was used to construct a blastoderm fate-map of the cuticle structures of the larval tail region. The segmental origin of the larval tail structures was inferred from the phenotypic analysis of segmentation and homoeotic mutants, which revealed pattern repetition throughout the embryonic tail region corresponding to four segment anlagen, A8 to A11, and a non-segmental telson. These data enabled the transformation of the blastoderm fate-map of cuticle structures into a map of tail segment anlagen. The tail anlage occupies about 10% of the egg length (EL), bounded by segment A7 anteriorly at 20% EL and by the proctodaeum posteriorly at 10% EL, as measured from the posterior pole. The anlagen of segments A8 and A9 appear to be narrow dorso-ventral strips of blastoderm cells similar to the anlagen of the trunk segments, whereas the anlagen of A10 and A11 are smaller and produce fewer pattern elements. The telson is represented in the cuticle by the tuft which derives from a very dorsal posterior position. The antero-posterior axis of the entire tail anlage appears curved upward posteriorly. Differences in the mode of development between tail and trunk segments are discussed, as are similarities of larval and imaginal tail development in Drosophila. Comparison with tail development in other insects suggests that, during evolution, the transition from semi-long-germ to long-germ development modified the organisation of the tail region without affecting its primary subdivision into metameric units.     

CRISPR/Cas9‐mediated ebony knockout results in puparium melanism in Spodoptera litura

Insect body pigmentation and coloration are critical to adaption to the environment. To explore the mechanisms that drive pigmentation, we used the clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR-associated protein 9 (Cas9) genome editing system to target the ebony gene in the non-model insect Spodoptera litura. Ebony is crucial to melanin synthesis in insects. By directly injecting Cas9 messenger RNA and ebony-specific guide RNAs into S. litura embryos, we successfully induced a typical ebony-deficient phenotype of deep coloration of the puparium and induction of melanin formation during the pupal stage. Polymerase chain reaction-based genotype analysis demonstrated that various mutations had occurred at the sites targeted in ebony. Our study clearly demonstrates the function of ebony in the puparium coloration and also provides a potentially useful marker gene for functional studies in S. litura as well as other lepidopteran pests.