首页 | 本学科首页   官方微博 | 高级检索  
相似文献
 共查询到18条相似文献,搜索用时 191 毫秒
1.
【目的】了解小红珠绢蝶Parnassius nomion线粒体基因组的特征,并从线粒体基因组水平探究蝶类高级阶元的系统发育关系。【方法】采用PCR扩增技术及Sequencher 4.8拼接软件获得小红珠绢蝶线粒体基因组全序列。参考鳞翅目昆虫已知线粒体基因组全序列并使用MEGA6.0软件对小红珠绢蝶线粒体基因组中各基因进行定位和注释。采用tRNA Scan-SE 1.21在线预测小红珠绢蝶线粒体基因组tRNA基因的二级结构。基于线粒体基因组13个蛋白质编码基因的核苷酸序列重建了包含凤蝶总科中凤蝶科(Papilionidae)、绢蝶科(Parnassiidae)、粉蝶科(Pieridae)、眼蝶科(Satyridae)、蛱蝶科(Nymphalidae)、灰蝶科(Lycaenidae)、斑蝶科(Danaidae)、珍蝶科(Acraeidae)、喙蝶科(Libyheidae)和蚬蝶科(Riodinidae)10个科28种蝴蝶的系统发育关系。【结果】结果表明,小红珠绢蝶线粒体基因组全序列总长度为15 362 bp(Gen Bank登录号:MF496134),包含13个蛋白质编码基因、22个tRNA基因、2个rRNA基因和1个A+T富含区。小红珠绢蝶线粒体基因组中存在较高的A+T含量(79.6%)。小红珠绢蝶线粒体基因组13个蛋白质编码基因中UUA的相对同义密码子使用频率(RSCU)最高(5.08),而AGG和CCG相对同义密码子使用频率(RSCU)均较低(0),这与大紫蛱蝶Sasakia charonda coreana的分析结果一致。在所测得的22个tRNA基因中,除tRNASer(AGN)缺少DHU臂外,其余tRNA基因均能形成典型的三叶草结构,这与鳞翅目中目前已得到的其他昆虫线粒体基因组中tRNA基因的二级结构一致。系统发育分析结果显示,凤蝶总科内蚬蝶科与灰蝶科的亲缘关系最近;粉蝶科与蛱蝶科、珍蝶科、眼蝶科、斑蝶科、喙蝶科、蚬蝶科和灰蝶科的系统发育关系更近;绢蝶科与凤蝶科锯凤蝶亚科亲缘关系最近,随后二者与凤蝶亚科物种聚为一支。在绢蝶科中,小红珠绢蝶与依帕绢蝶Parnassius epaphus的亲缘关系最近。【结论】本研究支持绢蝶科物种归为绢蝶亚科,绢蝶亚科、锯凤蝶亚科和凤蝶亚科归入凤蝶科,且绢蝶亚科与锯凤蝶亚科为姐妹群。  相似文献   

2.
本文测定了蛱蝶科7亚科27种蛱蝶和斑蝶科2种蝴蝶的线粒体16S rRNA基因部分序列,并从GenBank中下载了6种蛱蝶的同源序列。以斑蝶科的幻紫斑蝶和绢斑蝶作外群,通过遗传分析软件对这些序列进行了比较分析,用邻接法和贝叶斯法重建了蛱蝶科的系统发育树,探讨了蛱蝶科主要类群间的系统发育关系。序列分析的结果显示:经比对处理后获得494bp长度序列,其中有可变位点206个,简约信息位点145个;A T平均含量78.4%,C G平均含量为21.6%,具A、T偏倚性。分子系统树显示:蛱蝶亚科并非单系群;蛱蝶族中眼蛱蝶属应移入斑蛱蝶族;闪蛱蝶和蛱蝶亚科与蛱蝶亚科具有较近的系统关系;结果支持豹蛱蝶和釉蛱蝶合为一亚科即釉蛱蝶亚科;支持将秀蛱蝶和蛱蝶亚科从线蛱蝶亚科中分离出来。  相似文献   

3.
凤蝶亚科(凤蝶科,鳞翅目)16S rRNA基因的分子系统发生分析   总被引:2,自引:0,他引:2  
对15种凤蝶亚科蝶类线粒体16S rRNA基因部分序列进行了测定,并结合GenBank中其它相关类群的序列,采用邻接法(NJ)、最大简约法(MP)、最大似然法(ML)和贝叶斯法构建凤蝶亚科的分子系统树,探讨该亚科各类群间的系统发生关系.结果表明,燕凤蝶族构成凤蝶亚科蝶类系统树基部的一个独立分支;燕凤蝶族和裳凤蝶族为单系发生,且裳凤蝶族聚在凤蝶族内部;喙凤蝶族的单系性尚不能确定.综合分子系统学、形态学及寄主植物等相关证据,推测斑凤蝶类为凤蝶族中早期分化的一支;较之裳凤蝶类,斑凤蝶类可能更早从二者最近的共同祖先中分化出来.  相似文献   

4.
菜粉蝶线粒体基因组的全序列测定和分析   总被引:2,自引:0,他引:2  
目前关于蝶类线粒体基因组全序列及其分子进化的研究还不多见。本研究通过长PCR和引物步移法对菜粉蝶Pieris rapae Linnaeus线粒体基因组全序列进行了测定和初步分析。结果表明:菜粉蝶线粒体基因组全长15 157 bp, 包含13个蛋白编码基因、22个tRNA和2个rRNA基因以及1个非编码的控制区域, 它们的长度分别是11 196 bp, 1 474 bp, 2 093 bp和393 bp。37个基因的位置与已报道的其他蝶类基本一致, 共有10对基因间存在总共59 bp的重叠, 重叠碱基数在1~35 bp之间; 基因间隔序列共计13处120 bp, 间隔长度1~46 bp不等, 最大的基因间隔46 bp, 位于tRNAIle和tRNAGln基因之间。另外, 基于13个蛋白质编码基因的氨基酸序列, 重建了基于蛋白质编码基因序列数据的11种代表性蝶类的NJ和MP系统树。结果表明:凤蝶类(包括凤蝶和绢蝶)为一大支系, 粉蝶类、 灰蝶类与蛱蝶类(包括蛱蝶、 珍蝶)构成另一大支系。结果不支持粉蝶科与凤蝶科(包括凤蝶类和绢蝶类)构成单系群, 却显示粉蝶科、 灰蝶科和蛱蝶科的组合为单系群。  相似文献   

5.
通过2008—2017年夏季在峨眉山地区的调查,共采集蝶类标本1 860号,隶属10科73属154种,结合前人报道,峨眉山共有蝶类11科126属279种。本次调查显示,蛱蝶科Nymphalidae物种数(55种)和个体数(645只)均最多,珍蝶科Acraeidae物种数(1种)和个体数(6只)均最少;常见种(数量占比大于5%)包括嘉翠蛱蝶Euthalia kardama、斑星弄蝶Celaenorrhinus maculosus、东方菜粉蝶Pieris canidia、素饰蛱蝶Stibochiona nicea、灰翅串珠环蝶Faunis aerope和黑纹粉蝶P.melete,这6种蝶类占蝶类总数的41.10%;珍稀种包括金裳凤蝶Troides aeacus、裳凤蝶T.helena、燕凤蝶Lamproptera curia、三尾凤蝶Bhutanitis thaidina、双星箭环蝶Stichophthalma neumogeni、白袖箭环蝶S.louisa、箭环蝶S.howqua、黑紫蛱蝶Sasakia funebris、枯叶蛱蝶Kallima inachus和朴喙蝶Libythea celtis,这些珍稀蝶类值得重点关注和保护。建议加强峨眉山蝶类资源的长期监测和调查研究,为科学合理地开发蝶类资源和进行濒危珍稀特有蝶类的保护提供基础数据。  相似文献   

6.
秦峰  付文博  周善义 《昆虫学报》2011,54(3):339-351
对凤蝶科6属25种的COⅠ基因和20种Cyt b基因的部分序列进行测定和分析, 探讨它们之间的系统发育关系; 以茶小卷叶蛾Adoxophyes honmai为外群, 用邻接法(neighbor-joining, NJ)、 最大简约法(maximum parsimony, MP)和贝叶斯法(Bayesian inference, BI)重建了凤蝶科6属的分子系统树。结果表明: COⅠ基因部分序列长度为661 bp, 其中保守位点417个, 可变位点244个, 简约信息位点191个; A+T的平均含量为70.3%, 明显高于C+G的平均含量29.6%。Cyt b基因部分序列长度为433 bp, 其中保守位点239个, 可变位点194个, 简约信息位点135个; A+T的平均含量为74.2%, 明显高于C+G的平均含量25.7%。分子系统树表明, 凤蝶属Papilio、 斑凤蝶属Chilasa、 尾凤蝶属Bhutanitis、 珠凤蝶属Pachliopta和喙凤蝶属Teinopalpus为单系性, 与传统形态分类结果相一致。但青凤蝶属Graphium单系性不够明确, 需要进一步探讨。研究结果为我国凤蝶科分子系统学研究积累了资料。  相似文献   

7.
为了探讨中国蝶类科间系统发生关系,本文对细胞色素氧化酶Ⅱ(COⅡ)的部分序列(620bp)和延伸因子基因(EF-1α)部分序列(595bp)进行了分析(共1215bp)。其中有464个变异位点,330个简约信息位点。COⅡ基因部分序列表现出明显的A T含量(76.3%)偏高。分别采用最大简约法(Maximum Parsimony,MP)、最大似然法(Maximum Likelihood,ML)和贝叶斯推论法(Bayesian Inference,BI)重建了分子系统树。结果表明:弄蝶科、凤蝶科、粉蝶科、灰蝶科能够单独成一支,其中弄蝶科位于系统树的基部,分化较早,是较原始的类群,与传统的形态分类结果是相一致的;粉蝶科与凤蝶科的亲缘关系较近;蚬蝶科倾向与灰蝶科有较近的亲缘关系,且蚬蝶科种群始终聚为一支,显示了该科是一个单系群,从单系性方面来看,本文支持将蚬蝶科作为一个独立的科;此外,本文结果表明,中国分布的蛱蝶总科是一单系群,并且它与灰蝶科和蚬蝶科聚成的一支是姐妹群关系。  相似文献   

8.
袁向群  高可  袁锋  张雅林 《昆虫学报》2015,58(4):400-407
【目的】探讨中国弄蝶亚科各族之间的系统发育关系。【方法】对22属32种弄蝶亚科蝶类的Cytb和ND1基因部分序列进行了联合分析,分别采用最大似然法(maximum likelihood,ML)和贝叶斯法(Bayesian inference,BI)构建了系统发育树。【结果】测得的Cytb和ND1基因联合后,获得的序列总长为836 bp,包含保守位点450个,变异位点386个,简约信息位点304个;A+T的平均含量为76.9%,明显高于C+G的平均含量(23.1%)。基于Cytb和ND1基因联合序列的系统发育分析显示,钩弄蝶族(Ancistroidini)、刺胫弄蝶族(Baorini)、弄蝶族(Hesperiini)为单系群,且亲缘关系较近,其亲缘关系为:(弄蝶族Hesperiini+(刺胫弄蝶族Baorini+钩弄蝶族Ancistroidini));而锷弄蝶族Aeromachini(=酣弄蝶族Halpini)是一个复系群。【结论】本文支持钩弄蝶族(Ancistroidini)、刺胫弄蝶族(Baorini)、弄蝶族(Hesperiini)的族级地位,锷弄蝶族(Aeromachini)与Warren等研究结果矛盾,其他族有待补充样本后做进一步研究。  相似文献   

9.
通过整理鉴定四川大学自然博物馆馆藏的100多年间采自四川省的1万余号蝶类标本,最早的四川蝶类标本(宽带凤蝶西部亚种Papilio nephelus chaon)采于1910年,结合文献和专著资料,参考《中国蝶类志》的分类系统,得到四川省蝶类644种,隶属于12科240属。其中,蛱蝶科Nymphalidae 162种、弄蝶科Hesperiidae 125种、眼蝶科Satyridae 114种、灰蝶科Lycaenidae 100种、粉蝶科Pieridae 59种、凤蝶科Papilionidae 45种、蚬蝶科Riodinidae 14种、绢蝶科Parnassiidae 11种、斑蝶科Danaidae 8种、环蝶科Amathusiidae 4种、喙蝶科Libytheidae 1种、珍蝶科Acraeidae 1种。四川省蝶类物种组成丰富,其中,蛱蝶科、弄蝶科、眼蝶科和灰蝶科物种数均超过或达到100种。建议在全省范围内选择不同生境建立长期监测点,持续监测蝶类物种多样性分布及变化情况,这对于保护全省生态环境和维持生物多样性都是至关重要的。建议尽快开展相关研究,包括四川省蝶类的经典分类学、系统发育及区系、生物地理学、生态学、行为学和进化生态学等研究。  相似文献   

10.
【目的】了解扬眉线蛱蝶Limenitis helmanni线粒体基因组结构及其分子系统发育。【方法】采用PCR步移法对扬眉线蛱蝶线粒体基因组全序列进行测定和分析。基于线粒体基因组13个蛋白质编码基因和2个rRNA基因的核苷酸序列构建了66种鳞翅目昆虫的系统发育树。【结果】扬眉线蛱蝶线粒体基因组全长15 178 bp(Gen Bank登录号:KY290566),包括13个蛋白质编码基因、22个tRNA基因、2个rRNA基因和一段长度为346 bp的A+T富含区,基因排列顺序与其他已知近缘种昆虫相同。扬眉线蛱蝶线粒体基因组中存在很高的A+T含量(81.1%)。13个蛋白质编码基因中,COI以CGA作为起始密码子,ND5以GTT作为起始密码子,其余均以昆虫典型的ATN为起始密码子。COII和ND4基因使用了不完全终止密码子T,其余基因均以典型的TAA为终止密码子。在所测得的22个tRNA基因中,除tRNASer(AGN)缺少DHU臂外,其余tRNA均能形成典型的三叶草结构。与其他多数鳞翅目昆虫一样,扬眉线蛱蝶的A+T富含区中有一段由ATAGA引导的保守的多聚T结构,长度为20 bp,并散布着一些长短不一的串联重复单元。系统发育树结果显示,蛱蝶科亚科级别的系统发育关系为:(绢蛱蝶亚科+眼蝶亚科)+((蛱蝶亚科+闪蛱蝶亚科)+(釉蛱蝶亚科+线蛱蝶亚科))。【结论】线蛱蝶族与翠蛱蝶族的亲缘关系较近,丽蛱蝶族是该亚科较早分化出来的一支。基于线粒体基因组构建的线蛱蝶亚科物种系统发育关系与传统形态分类学研究结论不一致。  相似文献   

11.
The molecular phylogenetic relationships among true butterfly families (superfamily Papilionoidea) have been a matter of substantial controversy; this debate has led to several competing hypotheses. Two of the most compelling of those hypotheses involve the relationships of (Nymphalidae + Lycaenidae) + (Pieridae + Papilionidae) and (((Nymphalidae + Lycaenidae) + Pieridae) + Papilionidae). In this study, approximately 3,500 nucleotide sequences from cytochrome oxidase subunit I (COI), 16S ribosomal RNA (16S rRNA), and elongation factor-1 alpha (EF-1α) were sequenced from 83 species belonging to four true butterfly families, along with those of three outgroup species belonging to three lepidopteran superfamilies. These sequences were subjected to phylogenetic reconstruction via Bayesian Inference (BI), Maximum Likelihood (ML), and Maximum Parsimony (MP) algorithms. The monophyletic Pieridae and monophyletic Papilionidae evidenced good recovery in all analyses, but in some analyses, the monophylies of the Lycaenidae and Nymphalidae were hampered by the inclusion of single species of the lycaenid subfamily Miletinae and the nymphalid subfamily Danainae. Excluding those singletons, all phylogenetic analyses among the four true butterfly families clearly identified the Nymphalidae as the sister to the Lycaenidae and identified this group as a sister to the Pieridae, with the Papilionidae identified as the most basal linage to the true butterfly, thus supporting the hypothesis: (Papilionidae + (Pieridae + (Nymphalidae + Lycaenidae))).  相似文献   

12.
Qin F  Jiang GF  Zhou SY 《Mitochondrial DNA》2012,23(2):123-125
In this study, we sequenced the complete mitochondrial genome of Teinopalpus aureus guangxiensis (Lepidoptera: Papilionidae), which is considered as an endemic species in China. It is listed as a vulnerable species by International Union for Conservation of Nature and Natural Resources Red List and also a first class endangered species in China. The complete mtDNA from T. aureus guangxiensis was 15,235 base pairs in length and contained 13 protein-coding genes (PCGs), 2 rRNA genes, 22 tRNA genes, and a control region. The T. aureus guangxiensis genes were in the same order and orientation as the completely sequenced mitogenomes of other lepidopteran species. All PCGs of T. aureus guangxiensis mitogenome start with a typical ATN codon and terminate in the common stop codon TAA, except that ND1 gene uses TTA, ND3 gene uses ATT, and ND4 and ND4L gene use TAA. The phylogenetic relationships were reconstructed with the concatenated sequences of the 13 PCGs of the mitochondrial genome, and phylogenetic results confirmed that Nymphalidae, Lycaenidae, Papilionidae, Pieridae are monophyletic clades.  相似文献   

13.
1. Available evidence on butterfly family-level relationships is re-examined according to the principles of phylogenetic (cladistic) systematics. 2. The assumption of a sister-group relationship between the Hesperioidea and Papilionoidea seems a reasonably substantiated working hypothesis. 3. The Papilionoid families Papilionidae, Pieridae and Lycaenidae sensu Ehrlich (1958) are definable as monophyletic entities; of Ehrlich 's two remaining families, Nymphalidae and Libytheidae, the former is paraphyletic in terms of the latter. 4. The interrelationships between the Papilionoid families may be presented as Papilionidae + (Pieridae + [Lycanidae + Nymphalidae]). 5. In a phylogenetic system any given arrangement of taxa is either correct or not: Contrary to the pheneticists' view (Ehrlich and Ehrlich 1967) phylogenetic systematists cannot accept the existence of a multitude of valid classifications.  相似文献   

14.
Phylogenetic relationships among the Japanese papilionid butterflies were analyzed by comparing 783 nucleotide sequences of the mitochondrial gene encoding NADH dehydrogenase subunit 5 (ND5). Phylogenetic trees of the representative species from each family in the superfamily Papilionoidea revealed that the species of the family Papilionidae and those of all other families formed distinct clusters, with a few species of the family Hesperiidae (Hesperioidea) as an outgroup. In the phylogenetic trees of most Japanese species of the family Papilionidae with Nymphalis xanthomelas (Nymphalidae) as an outgroup, the tribe Parnassiini (Parnassiinae) formed a cluster, and the rest formed the other cluster in which the tribe Zerynthiini (Parnassiinae) and the subfamily Papilioninae formed different subclusters. In the Papilioninae cluster, the tribes Troidini and Graphiini formed a subcluster, and the tribe Papilionini formed the other subcluster. These results generally agree with the traditional classification of the papilionid butterflies based on their morphological characteristics and support the proposed evolutionary genealogy of the butterflies based on their morphology, behavior, and larval host plants, except that the tribes Parnasiini and Zerynthiini (both Parnassiinae) are not in the same cluster. Received: 16 March 1998 / Accepted: 28 April 1998  相似文献   

15.
The complete mitochondrial genome of Ampittia dioscorides (Lepidoptera: Hesperiidae) was determined. The sequenced genome is a circular molecule of 15313 bp, containing 13 protein-coding genes (PCGs), 22 tRNA genes, two rRNA genes, and an A + T-rich region. The gene arrangements and transcribing directions are identical to those in most of the reported lepidopteran mitogenomes. The base composition of the whole genome and genes or regions are also similar to those in other lepidopteran species. All the PCGs are initiated by typical ATN codons; the exception being COI, which begins with a CGA codon. Eight genes (ND2, ATPase8, ATPase6, COIII, ND5, ND4L, ND6, and Cytb) end with a TAA stop codon, and two genes (ND1 and ND3) end with TAG. The remaining three genes (COI and COII, which end with TA-, and ND4, which ends with T-) have incomplete stop codons. All tRNAs have the typical clover-leaf structure of mitochondrial tRNAs, with the exception of tRNASer(AGY). On the basis of the concatenated nucleotide and amino acid sequences of the 13 PCGs and wingless gene of 22 butterfly species, maximum parsimony (MP) and Bayesian inference (BI) trees were constructed, respectively. Both MP and BI trees had the same topological structure: ((((Nymphalidae + Danaidae) + Lycaenidae) + Pieridae) + Papilionidae) + Hesperiidae). The results provide support for Hesperiidae as a superfamily-level taxon.  相似文献   

16.
【背景】米尔顿姬小蜂是一种入侵我国台湾地区的植食性小蜂,能够严重影响水果的产量和食用价值。目前在我国大陆没有分布,由于其个体微小,与近似种区别较小,通过传统的形态学分类方法难以鉴定,因此有必要研究其基因片段序列,探讨分子鉴定方法。【方法】利用PCR方法扩增并测定了米尔顿姬小蜂线粒体16SrRNA和COⅠ基因的部分序列,并对各序列的碱基组成进行了分析。然后根据COⅠ基因部分序列,利用DNAMAN的Maximum Likelihood方法构建了米尔顿姬小蜂与膜翅目其他科的系统发育树。【结果】16SrRNA基因的PCR扩增产物为426bp,COⅠ基因的PCR扩增产物为488bp。通过测序获得米尔顿姬小蜂16SrRNA和COⅠ基因部分序列,序列分析表明,16SrRNA和COⅠ基因的A+T含量均较高,存在较强的A+T偏向性。系统发育树显示,米尔顿姬小蜂与蚜小蜂科的Encarsia berlesei亲缘关系最近,与姬小蜂科的Chrysocharis nautius、C.eurynota亲缘关系较远。【结论与意义】本研究为米尔顿姬小蜂的分子鉴定提供了依据。  相似文献   

17.
锯凤蝶类与凤蝶科其他类群的系统发生关系及其分类学地位一直存在争议。本研究采用PCR和long PCR技术测定了属于锯凤蝶类的丝带凤蝶Sericinus montelus线粒体基因组全序列; 结合已有的其他凤蝶科物种的相应序列数据, 基于13个蛋白质编码基因重建了凤蝶科主要类群的系统发生树, 探讨了它们之间的系统发生关系。基因组分析结果表明: 丝带凤蝶线粒体基因组全长15 242 bp, 包括13个编码蛋白基因(ATP6, ATP8, COⅠ-Ⅲ, ND1-6, ND4L和Cytb)、 22个tRNA基因、 16S和12S rRNA基因以及非编码的控制区; 基因组A, T, G和C含量分别为40.1%, 40.8%, 7.4%和11.7%, 表现出明显的AT偏倚。所有的蛋白质编码基因都使用标准的起始密码子(ATN); 除ND4 和 ND4L基因使用单个的T作为终止密码子外, 其余蛋白编码基因都使用了标准的终止密码子(TAA)。除丝氨酸 tRNA的二氢尿苷突环缺失外, 所有tRNA基因都形成典型的三叶草型结构。基因组中共存在12个大小介于2~65 bp之间的基因间隔区以及15个大小介于1~8 bp之间的基因重叠区, 其中, 存在于COⅡ和tRNALys之间的24 bp的间隔区在其他鳞翅目昆虫中未曾见到。以邻接法和最大简约法并基于13个蛋白质编码基因序列对凤蝶科进行了系统发生分析。结果显示, 丝带凤蝶和中华虎凤蝶Luehdorfia chinensis先构成一个支系, 再和冰清绢蝶Parnassius bremeri构成姊妹群; 表明锯凤蝶类应作为族级分类单元归于凤蝶科下的绢蝶亚科。  相似文献   

18.
Operational taxonomic units (OTUs) are conventionally defined at a phylogenetic distance (0.03—species, 0.05—genus, 0.10—family) based on full-length 16S rRNA gene sequences. However, partial sequences (700 bp or shorter) have been used in most studies. This discord may affect analysis of diversity and species richness because sequence divergence is not distributed evenly along the 16S rRNA gene. In this study, we compared a set each of bacterial and archaeal 16S rRNA gene sequences of nearly full length with multiple sets of different partial 16S rRNA gene sequences derived therefrom (approximately 440-700 bp), at conventional and alternative distance levels. Our objective was to identify partial sequence region(s) and distance level(s) that allow more accurate phylogenetic analysis of partial 16S rRNA genes. Our results showed that no partial sequence region could estimate OTU richness or define OTUs as reliably as nearly full-length genes. However, the V1-V4 regions can provide more accurate estimates than others. For analysis of archaea, we recommend the V1-V3 and the V4-V7 regions and clustering of species-level OTUs at 0.03 and 0.02 distances, respectively. For analysis of bacteria, the V1-V3 and the V1-V4 regions should be targeted, with species-level OTUs being clustered at 0.04 distance in both cases.  相似文献   

设为首页 | 免责声明 | 关于勤云 | 加入收藏

Copyright©北京勤云科技发展有限公司  京ICP备09084417号