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.     

家蚕两种新的类鹑斑突变体的遗传分析和SSR标记定位

在家蚕品种选育过程中发现了两种斑纹突变体, 与普通斑相比, 其幼虫眼状纹不明显, 而半月纹和星状纹正常, 其间有点和线构成鹑状斑纹, 第6、7腹节背面布有纵向波纹状斑纹, 整体斑纹与鹑斑(quail,q)极其相似, 暂且命名为类鹑斑(quail-like, q-l)。其中一种突变体稚蚕期体色呈褐色, 蚕体发育正常, 蚕茧大小一致, 茧型正常, 称为褐色类鹑斑(brown quail-like, q-lb); 另一种突变体幼虫体色为浅粉紫色, 幼虫食桑量少, 发育缓慢, 体质较弱, 体型较小, 茧型偏小, 称为紫色类鹑斑(purple quail-like, q-lp)。遗传分析表明, 两个类鹑斑基因均为隐性基因; 褐色类鹑斑(q-lb)与紫色类鹑斑(q-lp) 为等位基因, 紫色类鹑斑(q-lp)对褐色类鹑斑(q-lb)为隐性。经与形态标记P3(2)、p(2)、Ze(3)、L(4)、re(5)、E(6)、q(7)、I-a(9)、ms(12)、ch(13)、oa(14)、cts(16)、mln(18)、 msn(19)、rb(21)、so(26)测验和SSR分子标记多态性分析, 新发现的两种类鹑斑不同于鹑斑(q), 其基因座位于第8连锁群。     

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.     

Hormonal control of larval coloration in the armyworm, Leucania separata

Leucania separata larvae show various degrees of darkening depending on the population density. A ligature applied behind the thorax of crowded or yellow solitary larvae caused black or reddish brown pigmentation in the anterior part after the larval ecdysis. Extirpation of the brain, the corpus cardiacumcorpus allatum complexes, or the suboesophageal ganglion reduced the degree of melanization in the crowded larvae, lack of the suboesophageal ganglion having a particularly striking effect. Transplantation of 3 complexes of brain-corpora cardiaca-corpora allata-suboesophageal ganglion induced intense black pigmentation in the isolated abdomens of crowded larvae and reddish brown pigmentation with some melanization in the isolated abdomens of yellow solitary larvae, though the melanization in the latter was weaker than in the former. Implantation of these organs or of the suboesophageal ganglia into yellow solitary larvae caused black and reddish brown pigmentation after a larval ecdysis. In the pieces of integument implanted into the body cavity of crowded larvae, melanization occurred after ecdysis, whereas it did not occur in most of the fragments implanted in yellow solitary larvae. Transplantation of corpora allata and other organs from solitary larvae or injection of juvenile hormone into crowded larvae did not inhibit melanization.     

Melanin-synthesis enzymes coregulate stage-specific larval cuticular markings in the swallowtail butterfly, <Emphasis Type="Italic">Papilio xuthus</Emphasis>

Like the adult wing, butterfly larvae are unique in their coloring. However, the molecular mechanisms underlying the formation of insect larval color patterns are largely unknown. The larva of the swallowtail butterfly Papilio xuthus changes its color pattern markedly during the 4th ecdysis. We investigated its cuticular color pattern, which is thought to be composed of melanin and related pigments derived from tyrosine. We cloned three enzymes involved in the melanin-synthesis pathway in P. xuthus: tyrosine hydroxylase (TH), dopa decarboxylase (DDC), and ebony. Whole-mount in situ hybridization showed that the expression of both TH and DDC is strongly correlated with the black markings. ebony is strongly expressed only in the reddish-brown area. The expression pattern of each enzyme coincides with the cuticular color pattern of the subsequent instar. We also investigated the uptake of melanin precursors into cultured integument. Inhibition of either TH or DDC activity prevents in vitro pigmentation completely. Addition of dopamine to integuments in the presence of TH inhibitor causes overall darkening without specific markings. From these results, specific larval cuticular color patterns are regulated by stage-specific colocalization of enzymes in epidermal cells rather than by the differential uptake of melanin precursors into individual epidermal cells. Epidermal cells expressing TH and DDC, but not ebony, produce the black cuticle, and epidermal cells expressing TH, DDC, and ebony produce the reddish-brown cuticle.     

昆虫着色及体表黑色斑纹和斑点形成机制研究进展

昆虫在生长发育的过程中,会不断受到捕食者的攻击,为逃避被捕食在长期的适应进化中展现出各种适应性的形态特征,体色和斑纹的适应性变化是其中重要的防御策略。昆虫多样的着色模式常用于释放警告信号或者模仿宿主植物,避免被其他动物捕食并且加速逃避学习,而且在寻求伴侣、适应地理、调节体温和抵抗紫外线等方面发挥重要的生物功能,是昆虫学研究的热点之一。鳞翅目昆虫具有分布广、种类多的特点,大量的斑点和斑纹模式常见于鳞翅目昆虫中,其生物学功能比其他动物更明显。近年来研究发现色素色和结构色是昆虫主要的着色模式,眼色素、黑色素以及喋啶类色素是影响昆虫着色最重要的色素;而昆虫的寄主、环境因素、激素显著影响昆虫多样性着色模式的形成。利用定位克隆、经典遗传连锁图谱、RNA干涉、基因组编辑、高通量测序等技术分离鉴定出了多个调控鳞翅目昆虫着色的关键基因。研究表明, TH, DDC, yellow, laccase2, ebony, AA-NAT, tan和GTPCHI是昆虫色素合成信号通路中的关键基因,而多效性基因spz3, apt-like和wnt1以及20E诱导的转录因子E75A和spalt通过影响鳞翅目昆虫黑色素合成信号通路的活性从而调控黑色素的合成与沉积。本文对昆虫体色和斑纹多样性的形成和影响因素,昆虫着色类型及物质基础,以及黑色斑点和斑纹形成和调节机制方面的研究进展作了整理和总结,以期为今后着色基因的利用以及害虫防治提供理论参考。     

Effects of altered catecholamine metabolism on pigmentation and physical properties of sclerotized regions in the silkworm melanism mutant

Catecholamine metabolism plays an important role in the determination of insect body color and cuticle sclerotization. To date, limited research has focused on these processes in silkworm. In the current study, we analyzed the interactions between catecholamines and melanin genes and their effects on the pigmentation patterns and physical properties of sclerotized regions in silkworm, using the melanic mutant melanism (mln) silkworm strain as a model. Injection of β-alanine into mln mutant silkworm induced a change in catecholamine metabolism and turned its body color yellow. Further investigation of the catecholamine content and expression levels of the corresponding melanin genes from different developmental stages of Dazao-mln (mutant) and Dazao (wild-type) silkworm revealed that at the larval and adult stages, the expression patterns of melanin genes precipitated dopamine accumulation corresponding to functional loss of Bm-iAANAT, a repressive effect of excess NBAD on ebony, and upregulation of tan in the Dazao-mln strain. During the early pupal stage, dopamine did not accumulate in Dazao-mln, since upregulation of ebony and black genes led to conversion of high amounts of dopamine into NBAD, resulting in deep yellow cuticles. Scanning electron microscope analysis of a cross-section of adult dorsal plates from both wild-type and mutant silkworm disclosed the formation of different layers in Dazao-mln owing to lack of NADA, compared to even and dense layers in Dazao. Analysis of the mechanical properties of the anterior wings revealed higher storage modulus and lower loss tangent in Dazao-mln, which was closely associated with the altered catecholamine metabolism in the mutant strain. Based on these findings, we conclude that catecholamine metabolism is crucial for the color pattern and physical properties of cuticles in silkworm. Our results should provide a significant contribution to Lepidoptera cuticle tanning research.     

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.     

Drosophila wing melanin patterns form by vein-dependent elaboration of enzymatic prepatterns

BACKGROUND: Animal melanin patterns are involved in diverse aspects of their ecology, from thermoregulation to mimicry. Many theoretical models have simulated pigment patterning, but little is known about the developmental mechanisms of color pattern formation. In Drosophila melanogaster, several genes are known to be necessary for cuticular melanization, but the involvement of these genes in melanin pattern evolution is unknown. We have taken a genetic approach to elucidate the developmental mechanisms underlying melanin pattern formation in various drosophilids. RESULTS: We show that, in D. melanogaster, tyrosine hydroxylase (TH) and dopa decarboxylase (DDC) are required for melanin synthesis. Ectopic expression of TH, but not DDC, alone was sufficient to cause ectopic melanin patterns in the wing. Thus, changes in the level of expression of a single gene can result in a new level of melanization. The ontogeny of this ectopic melanization resembled that found in Drosophila species bearing wing melanin patterns and in D. melanogaster ebony mutants. Importantly, we discovered that in D. melanogaster and three other Drosophila species these wing melanin patterns are dependent upon and shaped by the circulation patterns of hemolymph in the wing veins. CONCLUSIONS: Complex wing melanin patterns are determined by two distinct developmental mechanisms. Spatial prepatterns of enzymatic activity are established late in wing development. Then, in newly eclosed adults, melanin precursors gradually diffuse out from wing veins and are oxidized into dark brown or black melanin. Both the prepatterning and hemolymph-supplied components of this system can change during evolution to produce color pattern diversity.     

Butterfly wing pattern mutants: developmental heterochrony and co-ordinately regulated phenotypes

Butterfly wings are colored late in development, when pigments are synthesized in specialized wing scale cells in a fixed developmental succession. In this succession, colored pigments are deposited first and the remaining areas are later melanized black or brown. Here we studied the developmental changes underlying two wing pattern mutants, firstly melanic mutants of the swallowtail Papilio glaucus, in which the yellow background is turned black, and secondly a Spotty mutant of the satyrid Bicyclus anynana, which carries two additional eyespots. Despite the very different pattern changes in these two mutants, they are both associated with changes in rates of scale development and correspondingly, the final color pattern. In the melanic swallowtail, background scales originally destined to become yellow (normally developing early and synthesizing papiliochrome) show delayed development, fail to make papiliochrome, and subsequently melanize at the same time as scales in the wild-type black pattern. In the B. anynana eyespot, scale maturation begins with the central white focus, then progresses to the surrounding gold ring and later finishes with melanization of the black center. Mutants showing additional eyespots display accelerated rates of scale development (corresponding to new eyespots) in wing cells not normally occupied by eyespots. Thus by either delaying or accelerating rates of scale development, the final color, or position, of a wing pattern element can be changed. We propose that this heterochrony of scale development is a basic mechanism of color pattern formation on which developmental mutants act to change lepidopteran color patterns. Received: 20 April 2000 / Accepted: 19 July 2000     

Effects of anti-juvenile hormone “ETB” on the development and metamorphosis of the silkworm, Bombyx mori

As in the tobacco hornworm Manduca sexta, the synthetic juvenile hormone analogue ETB (ethyl 4-[2-(tert-buthylcarbonyloxy)butoxy]benzoate) showed both juvenile hormone-like and anti-juvenile hormone activities in the silkworm, Bombyx mori. When ETB was topically applied to allatectomized 4th-instar larvae, the compound counteracted the effects of allatectomy, such as induction of precocious metamorphosis and black pigmentation in the larval markings. Therefore, ETB had juvenile hormone activity, but it could neither induce brown pigmentation in the markings nor induce an extra-larval moult as can juvenile hormone.When intact 3rd-instar larvae were treated with the compound, the majority underwent precocious metamorphosis in the 4th-instar, and later formed fertile miniature adults. Some moulted into larval-pupal intermediates or 5th-instar larvae with darkened larval markings and/or with abnormality of specific regions of the silk-gland. The optimal dose for such anti-juvenile effects was about 1–10 μg/larva, and higher doses showed less activity. Such anti-juvenile hormone effects of ETB were counteracted by administration of the juvenile hormone analogue, methoprene, before a certain critical time in the 4th-instar. The corpora allata of treated larvae appeared cytologically normal, and the corpora allata from ETB-induced miniature moths secreted juvenile hormone when implanted into allatectomized 4th-instar larvae.     

Convergent, modular expression of ebony and tan in the mimetic wing patterns of Heliconius butterflies

The evolution of pigmentation in vertebrates and flies has involved repeated divergence at a small number of genes related to melanin synthesis. Here, we study insect melanin synthesis genes in Heliconius butterflies, a group characterised by its diversity of wing patterns consisting of black (melanin), and yellow and red (ommochrome) pigmented scales. Consistent with their respective biochemical roles in Drosophila melanogaster, ebony is upregulated in non-melanic wing regions destined to be pigmented red whilst tan is upregulated in melanic regions. Wing regions destined to be pigmented yellow, however, are downregulated for both genes. This pattern is conserved across multiple divergent and convergent phenotypes within the Heliconii, suggesting a conserved mechanism for the development of black, red and yellow pattern elements across the genus. Linkage mapping of five melanin biosynthesis genes showed that, in contrast to other organisms, these genes do not control pattern polymorphism. Thus, the pigmentation genes themselves are not the locus of evolutionary change but lie downstream of a wing pattern regulatory factor. The results suggest a modular system in which particular combinations of genes are switched on whenever red, yellow or black pattern elements are favoured by natural selection for diverse and mimetic wing patterns.     

Inheritance of seed coat color genes in <Emphasis Type="Italic">Brassica napus</Emphasis> (L.) and tagging the genes using SRAP,SCAR and SNP molecular markers

Seed coat color inheritance in Brassica napus was studied in F₁, F₂, F₃ and backcross progenies from crosses of five black seeded varieties/lines to three pure breeding yellow seeded lines. Maternal inheritance was observed for seed coat color in B. napus, but a pollen effect was also found when yellow seeded lines were used as the female parent. Seed coat color segregated from black to dark brown, light brown, dark yellow, light yellow, and yellow. Seed coat color was found to be controlled by three genes, the first two genes were responsible for black/brown seed coat color and the third gene was responsible for dark/light yellow seed coat color in B. napus. All three seed coat color alleles were dominant over yellow color alleles at all three loci. Sequence related amplified polymorphism (SRAP) was used for the development of molecular markers co-segregating with the seed coat color genes. A SRAP marker (SA12BG18388) tightly linked to one of the black/brown seed coat color genes was identified in the F₂ and backcross populations. This marker was found to be anchored on linkage group A9/N9 of the A-genome of B. napus. This SRAP marker was converted into sequence-characterized amplification region (SCAR) markers using chromosome-walking technology. A second SRAP marker (SA7BG29245), very close to another black/brown seed coat color gene, was identified from a high density genetic map developed in our laboratory using primer walking from an anchoring marker. The marker was located on linkage group C3/N13 of the C-genome of B. napus. This marker also co-segregated with the black/brown seed coat color gene in B. rapa. Based on the sequence information of the flanking sequences, 24 single nucleotide polymorphisms (SNPs) were identified between the yellow seeded and black/brown seeded lines. SNP detection and genotyping clearly differentiated the black/brown seeded plants from dark/light/yellow-seeded plants and also differentiated between homozygous (Y2Y2) and heterozygous (Y2y2) black/brown seeded plants. A total of 768 SRAP primer pair combinations were screened in dark/light yellow seed coat color plants and a close marker (DC1GA27197) linked to the dark/light yellow seed coat color gene was developed. These three markers linked to the three different yellow seed coat color genes in B. napus can be used to screen for yellow seeded lines in canola/rapeseed breeding programs.     

A mutant affecting the crystal cells inDrosophila melanogaster

Summary Black cells (Bc, 2-80.6±) mutant larvae ofDrosophila melanogaster have pigmented cells in the hemolymph and lymph glands. In this report we present evidence that these melanized cells are a mutant form of the crystal cells, a type of larval hemocyte with characteristic paracrystalline inclusions.Bc larvae lack crystal cells. Furthermore, the distribution pattern of black cells inBc larvae parallels that of experimentally-blackened crystal cells in normal larvae (phenocopy).InBc/Bc zygotes black cells appear during mid embryonic development but inBc ⁺/Bc zygotes pigmented cells are not found until late in the first larval instar.Crystal cells are present in the heterozygous larvae until this time, and paracrystalline inclusions can be seen in some of the cells undergoing melanization in these larvae.The rate of phenol oxidase activity inBc ⁺/Bc larval cell-free extracts is less than half that ofBc ⁺/Bc ⁺extracts whereas enzyme activity is undetectable inBc/Bc larvae. We propose that theBc ⁺gene product is required for maintaining the integrity of the paracrystalline inclusions; inBc/Bc larvae either the product is absent or nonfunctional so an effective contact between substrate and enzyme results in melanization of the cells.Phenol oxidase itself is either destroyed or consumed in the melanization process accounting for the absence of enzyme activity inBc/Bc larvae. These studies confirm that the crystal cells store phenolic substrates and are the source of the hemolymph phenol oxidase activity in the larva ofD. melanogaster.     

Selective breeding and characterization of a black mealworm strain of Tenebrio molitor Linnaeus (Coleoptera: Tenebrionidae)

Larvae of Tenebrio molitor Linnaeus are edible insects and are approved as a food ingredient in Korea. They are typically yellow; however, rare black larvae have been found in breeding boxes at insect farms. It is not clear whether black larvae represent a different species that invaded and hybridized with the yellow larvae of T. molitor or whether T. molitor shows intraspecific color variation. In this study, we characterized and identified black larvae for applications in industrial fields as well as accurate breeding and management. First, in a comparative analysis, we did not detect differences in the morphological characteristics of yellow and black larvae and adults, with the exception of larval body color. For accurate species identification, molecular analyses (p-distances and neighbor-joining) were performed based on partial COI sequences of 33 yellow and seven black larvae. Genetic divergence between yellow and black larvae ranged from 0.0% to 2.1%, revealing intraspecific variation. A neighbor-joining analysis strongly supported the classification of the two morphs as a single species. Black larvae were separated from yellow larvae and maintained by selective breeding. As a result, black larvae were completely fixed in the F2 generation (F1 = 96% and F2 = 100%). Yellow and black larvae showed no significant differences in developmental characteristics and fecundity. These findings improve our understanding of diversity within an important edible insect species and contribute to quality assurance in the food industry based on clear species identification.     

Reciprocal functions of the Drosophila yellow and ebony proteins in the development and evolution of pigment patterns

Body coloration affects how animals interact with the environment. In insects, the rapid evolution of black and brown melanin patterns suggests that these are adaptive traits. The developmental and molecular mechanisms that generate these pigment patterns are largely unknown. We demonstrate that the regulation and function of the yellow and ebony genes in Drosophila melanogaster play crucial roles in this process. The Yellow protein is required to produce black melanin, and is expressed in a pattern that correlates with the distribution of this pigment. Conversely, Ebony is required to suppress some melanin formation, and is expressed in cells that will produce both melanized and non-melanized cuticle. Ectopic expression of Ebony inhibits melanin formation, but increasing Yellow expression can overcome this effect. In addition, ectopic expression of Yellow is sufficient to induce melanin formation, but only in the absence of Ebony. These results suggest that the patterns and levels of Yellow and Ebony expression together determine the pattern and intensity of melanization. Based on their functions in Drosophila melanogaster, we propose that changes in the expression of Yellow and/or Ebony may have evolved with melanin patterns. Consistent with our hypothesis, we find that Yellow and Ebony are expressed in complementary spatial patterns that correlate with the formation of an evolutionary novel, male-specific pigment pattern in Drosophila biarmipes wings. These findings provide a developmental and genetic framework for understanding the evolution of melanin patterns.     

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.