鸟类羽毛色素的合成机理与调控机制

鸟类作为色彩最丰富的陆生脊椎动物,其体表覆盖着颜色多样的羽毛,在伪装、择偶、信号识别等多方面具有重要功能,因此羽毛颜色引起了研究者的极大兴趣。羽毛颜色总体分为由化学物质产生的色素色和由物理结构产生的结构色,其中常见色素有两大类。根据近年来对羽毛色素的研究进展,本文总结了黑色素和类胡萝卜素的类型、合成途径、获取途径以及相关基因,为深入研究羽毛色素合成、代谢的分子调控机制提供科学依据。     

昆虫体色多型的分子调控机制

体色多型普遍存在于各昆虫类群,体色多型不仅是生物多样性的体现,而且多样的着色模式对于昆虫本身具有重要的生物学意义.研究体色多型对探讨昆虫遗传多态性、适应机制及生物进化等具有重要的意义.本文主要从昆虫体色多型的分子调控机制进行综述,以期为今后探讨昆虫多态性、适应机制及生物进化提供参考.     

长白山苔原带昆虫群落组成与时间动态

【目的】苔原是一种极地景观类型,本研究调查了长白山苔原带昆虫的物种组成与时间动态,以期为苔原带昆虫保护以及昆虫与苔原植物协同进化研究提供基础依据。【方法】2005-2007年每年6-9月,在长白山北坡、西坡苔原带利用网捕、灯诱、巴氏罐法采集昆虫标本。【结果】2005-2007年从长白山苔原带共获得昆虫标本4 634头,隶属于11目105科550种,其中鳞翅目、鞘翅目、膜翅目、双翅目的种类和个体数量较为丰富,这4个类群的物种数与个体数的最高峰都出现在7月份。对应分析显示,鳞翅目昆虫对7月份,鞘翅目昆虫对8和9月,膜翅目和双翅目昆虫对6月的适应性较强。苔原带7月份昆虫的物种数(382种)、个体数(2 571个个体)和多样性指数(4.673)都最高,物种数和个体数在9月份最低,仅22种265个个体。不同月份昆虫的物种数与个体数之间呈显著正相关(R=0.992)。不同月份间昆虫的相似性低(相似性系数＜0.20)。【结论】长白山苔原带昆虫多样性较低,7月为昆虫的活跃高峰期,9月昆虫的个体数和物种数均较少。鳞翅目昆虫的物种最丰富,对7月份气侯的适应性相对较强,鞘翅目对季节变化的适应能力强于其他类群,在维持苔原带生态平衡中起着重要作用。     

家蚕Hox基因研究进展

Hox基因（homeobox genes）在昆虫躯体模式（body plan）的发育调控机制中扮演着重要角色,其表达具有严格的组织特异性和胚胎发育的程序性。家蚕Bombyx mori作为鳞翅目昆虫的代表,其Hox基因也陆续得到鉴定。在家蚕中存在一个拟复等位基因群--E群基因,其突变表型均与过剩斑纹和过剩附肢有关,这可能与Hox基因有着密切联系。家蚕全基因组测序完成后,发现其Hox基因簇中存在12个特有的homeobox基因（Bmshx1~Bmshx12）, 说明家蚕Hox基因可能具有独特的生物学意义。我们还利用家蚕基因芯片数据分析了Bmlab与Bmpb基因的组织表达特征。通过对家蚕Hox基因的研究,探索家蚕躯体模式建立机制,可望为解析其他鳞翅目昆虫的躯体模式的建立机制提供理论依据。本文就家蚕Hox基因的表达、功能及其与E群突变的关系等方面进行了综述。     

体色差异豹纹鳃棘鲈的色素及酶含量分析

鱼类体色发育在生物进化、生理生态等方面具有重要的意义,豹纹鳃棘鲈是一种体色变异丰富的珊瑚礁鱼类,在不同环境中呈现出显著差异的体色。本文选取了豹纹鳃棘鲈体色差异个体,并对不同部位的皮肤颜色、色素分布和相关色素酶含量进行了检测和分析。结果显示,鱼体表皮分布着大量黑色素细胞和红色素细胞。黑色个体的黑色素细胞密度较大、黑色素含量较高,黑色素酶含量较低;而红色个体的红色素细胞密度更大、胡萝卜素与类胡萝卜素含量更高,黑色素酶的含量也更高。实验结果表明,豹纹鳃棘鲈的体色差异与黑色素颗粒的聚集、分散程度以及黑色素代谢酶的含量相关,体色鲜艳程度与红色素细胞数量以及胡萝卜素和类胡萝卜素含量相关。本文解释了红黑豹纹鳃棘鲈体色在色素和酶含量方面的差异,为进一步研究其体色变异机制提供了理论依据。     

梨小食心虫幼虫中肠中高表达消化酶和解毒酶基因的筛选

【目的】挖掘梨小食心虫Grapholita molesta幼虫中肠中高表达消化酶和解毒酶基因,为今后研究以肠道为靶标的新型农药和转基因作物提供理论依据。【方法】基于梨小食心虫4龄幼虫中肠转录组高通量测序数据的FPKM值,筛选高表达基因,进行GO功能注释和KEGG通路富集分析,并使用BLAST软件进行比对筛选高表达的消化酶和解毒酶基因,利用MEGA对这些高表达的消化酶和解毒酶及其他鳞翅目昆虫的同源蛋白进行系统发育分析。利用qRT-PCR技术对梨小食心虫幼虫不同龄期中肠中的高表达代表性消化酶和解毒酶基因表达量进行定量分析和验证。【结果】在GO数据库中注释了103 677个在梨小食心虫4龄幼虫中肠中高表达基因,包括细胞组分、分子功能和生物学进程三大类功能共41个分支。KEGG通路分析表明,10 846个高表达基因参与了5类生化代谢通路。筛选到具有完整开放阅读框的消化酶基因17个［5个胰蛋白酶(trypsin, TRY)基因、3个氨肽酶(aminopeptidase, APN)基因和9个羧肽酶(carboxypeptidase, CP)基因］和解毒酶基因32个［11个谷胱甘肽S-转移酶(glutathione S-transferase, GST)基因、13个细胞色素P450(cytochrome P450, CYP450)基因和8个羧酸脂酶(carboxylesterase, CarE)基因］。系统发育分析结果表明,梨小食心虫的消化酶同源聚类分支较为分散,GSTs和CYP450s分支聚类较为集中,但都至少与1个鳞翅目昆虫同源蛋白聚在一支。qRT-PCR验证结果表明,消化酶和解毒酶基因在不同龄期梨小食心虫幼虫中肠中的表达量差异显著,表达量均在4龄幼虫期最高。【结论】本研究成功筛选和验证部分梨小食心虫幼虫中肠中高表达的消化酶和解毒酶基因,明确其与鳞翅目其他昆虫同源蛋白的进化关系。研究结果为鳞翅目其他近缘昆虫的转录组分析和以肠道为靶标的害虫防治提供了参考。     

哺乳动物毛色调控机制及其适应性进化研究进展

哺乳动物类群呈现出的丰富毛色是引人注目的一种生物现象,是研究和理解哺乳动物适应性进化的理想模型之一。哺乳动物的毛色多态在躲避天敌、捕食、求偶及抵御紫外线等方面都具有重要作用。哺乳动物毛发的色素化过程由体内黑色素的数量、质量和分布状况所决定。黑色素的形成过程复杂,包括黑素细胞的分化、成熟,黑素体等细胞器的形态发生及黑色素在黑素细胞中的合成代谢和转运等过程;而在细胞色素化的每个阶段/时相都伴随着一些重要功能基因的参与,并通过基因之间的相互作用形成了黑色素生物代谢的复杂调控网络,进而形成不同的毛色有助于哺乳动物适应不同生存环境。对哺乳动物不同毛色形成机制的探究一直以来都是遗传学及进化生物学的重要研究领域和聚焦热点。本文综述了哺乳动物毛色色素化过程的主要分子机制以及毛色适应性进化的遗传基础,以期为哺乳动物毛色多态及其适应性进化的分子机制研究提供参考。     

昆虫体细胞遗传性别决定信号通路的研究进展

昆虫遗传性别决定可分为体细胞性别决定、生殖细胞分化和剂量补偿效应3个层次。昆虫体细胞性别决定信号通路基本上都遵循从初始信号到关键基因,再到双性基因的信息流传递基本模式。不同昆虫间,体细胞性别决定初始信号(如X染色体剂量、M强雄基因、母系印迹及与PIWI相作用的RNA等)很复杂,关键基因(如sxl和tra/fem)有所变化,但双性基因(如dsx)很保守,且重要基因的剪接方式(如选择性剪接)非常保守。结合作者昆虫性别决定的研究工作,本文总结了双翅目、膜翅目和鳞翅目代表性昆虫种类的性别决定初始信号、关键基因及双性基因的研究进展及一般规律,为昆虫性别决定分子机制的进一步揭示、昆虫不育技术(SIT)的开发以及昆虫性别的人为操控提供理论基础。     

利用计算机视觉技术量化解析食物颜色与斜纹夜蛾幼虫体色变化的关系

【目的】为了明确食物颜色对不同日龄昆虫体色的影响,并推广利用计算机视觉研究昆虫体色的技术。【方法】本研究以斜纹夜蛾Prodenia litura幼虫为实验材料,采用计算机定量分析的方法,对取食不同颜色型人工饲料的斜纹夜蛾幼虫头部、胸部斑纹、胸腹部和背中线的红色(R)、绿色(G)、蓝色(B)和明度(L)值进行了定量化分析。【结果】结果表明:幼虫的斑纹、胸腹部背面及侧面主色和背中线的R,G,B和L值随日龄增加而下降;头部R,G,B和L值在1-3日龄增加,后随日龄的增加而下降。幼虫体色变化也受食物颜色的影响,以对1-7日龄的影响为最大;红色型食物r∶g∶b=(128~251)∶(3~129)∶(6~96)对幼虫各部位体色的影响大于黄色、绿色和紫色的食物;幼虫取食不同颜色型食物后,各部位的变异系数大小依次为:斑纹胸腹部头部背中线。最后,建立了幼虫体色与食物色彩r,g,b值及日龄的回归方程。【结论】斜纹夜蛾幼虫体色受到食物颜色的影响,且在低龄时更为显著。     

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.     

Functional Significance of Vertebrate lntegumental Pigmentation

SYNOPSIS Pigment cells and their synthesized products play animportant functional role in the skin of most all vertebrates,from cyclostomes to man Both dermal and epidermal pigment cellsfunction in physiological and morphological color changes andprovide the cellular basis for vertebrate pigment patterns anddifferences in racial coloration Epidermal melanization is ofparticular importance in homeotherms in the regulation of seasonalpelage and feather color changes In addition, melanin pigmentation may have a photoprotective function, influence vitaminD synthesis in the skin protect or influence neivous systemfunction, affect heat absorption and consenition, play an intracellularhomeostatic role in the skin and (by leucocytic transport) elsewherein the bodv and provide a structural element to the integumentA consideration of the comparative evolution of the vertebratelntegumental pigmental) system may be necessary for a pioperinterpretation of the supposed roles ot melanin and other lntegumentalpigments     

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.     

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.     

Evidence of selection at melanin synthesis pathway loci during silkworm domestication

The domesticated silkworm (Bombyx mori) was domesticated from wild silkworm (Bombyx mandarina) more than 5,000 years ago. During domestication, body color between B. mandarina and B. mori changed dramatically. However, the molecular mechanism of the silkworm body color transition is not known. In the present study, we examined within- and between-species nucleotide diversity for eight silkworm melanin synthesis pathway genes, which play a key role in cuticular pigmentation of insects. Our results showed that the genetic diversity of B. mori was significantly lower than that of B. mandarina and 40.7% of the genetic diversity of wild silkworm was lost in domesticated silkworm. We also examined whether position effect exists among melanin synthesis pathway genes in B. mandarina and B. mori. We found that the upstream genes have significantly lower levels of genetic diversity than the downstream genes, supporting a functional constraint hypothesis (FCH) of metabolic pathway, that is, upstream enzymes are under greater selective constraint than downstream enzymes because upstream enzymes participate in biosynthesis of a number of metabolites. We also investigated whether some of the melanin synthesis pathway genes experienced selection during domestication. Neutrality test, coalescent simulation, as well as network and phylogenetic analyses showed that tyrosine hydroxylase (TH) gene was a domestication locus. Sequence analysis further suggested that a putative expression enhancer (Abd-B-binding site) in the intron of TH gene might be disrupted during domestication. TH is the rate-limiting enzyme of melanin synthesis pathway in insects. Real-time polymerase chain reaction assay did show that the relative expression levels of TH gene in B. mori were significantly lower than that in B. mandarina at three different developmental stages, which is consistent with light body color of domesticated silkworm relative to wild silkworm. Therefore, we speculated that expression change of TH gene may contribute to the body color transition from B. mandarina to B. mori. Our results emphasize the exceptional role of gene expression regulation in morphological transition of domesticated animals.     

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.     

Testing the effect of individual color morphology on immune response in bush-crickets

Abstract Despite the growing interest in how an individual's immune response is correlated to morphological and ecological factors, little empirical data has been available from wild insect populations. Many insects have different color morphs and exhibit differences in immune responses. Links are expected to exist between body colors and immune function in insects, because the same biochemical precursors involved in the immune response are responsible for melanin-based color markings. In this study, I assay the immune response of two different color morphs of 377 wild-caught bush-crickets, Metrioptera roeseli, from 20 populations by measuring individual encapsulation responses to a surgically implanted nylon monofilament. There was no difference between green and brown bush-cricket morphs (low melanin vs high melanin investment in cuticula color respectively) and their ability to mount an immune response to the implant. Further study is needed on the relationship between color morphology and immune response in wild insects, and whether trade-offs occur between factors during an insect's development phase and long-term health.     

Molecular and biochemical mechanisms of human iris color: A comprehensive review

Eye color is determined as a polymorphism and polygenic trait. Brown is the most common eye color in the world, accounting for about 79%, blue eye color for about 8–10%, hazel for 5%, and green for 2%. Rare-colored eyes include gray and red/violet. Different factors are involved in determining eye color. The two most important factors are the iris pigment and the way light is scattered from the iris. Gene expression determines the iris pigmentation and how much melanin is present in the eye, which is the number of melanin subunits that identify eye color. The genes involved in the pigmentation of single-nucleotide polymorphism (SNP) have a significant role; and even some genes are included only in the eye color through SNP. MicroRNAs also affect melanocyte synthesis, which is usually affected by the downregulation of essential genes involved in pigmentation. In this study, we assess the biochemical pathways of melanin synthesis, and the role of each gene in this pathway also has been examined in the signaling pathway that stimulates melanin synthesis.