基于18S rRNA基因序列的直翅目主要类群系统发育关系研究

基于78种直翅目昆虫的18S rRNA基因全序列构建了直翅目各主要类群间的系统发育关系。本研究的结果支持直翅目的单系性,但不支持蝗亚目和螽亚目各自的单系性;直翅目下除蜢总科和蝗总科外各总科的划分多数与Otte系统相一致;蜢总科的单系性得不到支持;蝗总科的剑角蝗科、斑腿蝗科、斑翅蝗科、网翅蝗科和槌角蝗科5科均不是单系群,各物种间的遗传距离差异不大,应合并为一科,即蝗科;本研究支持将Otte系统中蚱总科和螽蟖总科下各亚科级阶元提升为科级阶元;18S rRNA基因全序列可以作为划分科级阶元的工具,当位于同一分支上互成姐妹群的类群间的遗传距离超过1%时,这几个类群属于不同的科;但由于其在进化上的保守性,18S rRNA基因只能用于纲目等高级阶元间关系的研究,而由其获得的总科以下阶元间的关系并不可靠。     

直翅目昆虫线粒体基因组研究进展

本文总结了本实验室对40余种直翅目昆虫的线粒体基因组序列的研究方法和主要结果.直翅目线粒体基因组研究中最重要的发现包括：（1）在直翅目昆虫线粒体基因组中发现了3种基因排列次序.蝗亚目除蜢总科外都具有DK排列.蜢总科的变色乌蜢为KD 排列,与蝗亚目其他总科不同,而与螽亚目昆虫的排序方式相同.已测出的螽亚目大多数昆虫的KD 排列顺序与典型节肢动物的完全相同,但在黄脸油葫芦Teleogryllus emma发生了tRNA^Glu,tRNA^Ser和tRNA^Asn的倒置;（2）在疑钩额螽Ruspolia dubia中发现了一种到目前为止具有最短控制区（70 bp）的线粒体基因组;（3）采用多种方法分析了昆虫A+T富集区存在的调控序列和二级结构特征,获得了昆虫A+T富集区保守序列的一致结构.采用Z曲线分析蝗虫的A+T富集区,表明也存在与原核生物复制起点类似的信号;（4）构建了30种蝗虫12S rRNA和16S rRNA的二级结构.在昆虫线粒体基因组非编码链中发现了一些类tRNA结构和tRNA异构体;（5）构建了基于线粒体基因组数据的直翅目昆虫主要亚科以上分类单元之间的系统发育关系.     

The phylogeny of Orthoptera inferred from mtDNA and description of Elimaea cheni （Tettigoniidae： Phaneropterinae） mitogenome

The complete 15,831 bp nucleotide sequence of the mitochondrial genome from Elimaea cheni(Phaneropterinae)was determined.The putative initiation codon for cox1 was TTA.The phylogeny of Orthoptera based on different mtDNA datasets were analyzed with maximum likelihood(ML)and Bayesian inference(BI).When all 37 genes(mtDNA)were analyzed simultaneously,the monophyly of Caelifera and Ensifera were recovered in the context of our taxon sampling.The phylogeny of Orthoptera was largely consistent with previous phylogenetie hypotheses.Rhaphidophoridae to be a sister group of Tettigoniidae,and the relationships among four subfamilies of Tettigoniidae were(Phaneropterinae+(Conocephalinae+(Bradyporinae+Tettigoniinae))).Pyrgomorphidae was the most basal group of Caelifera.The relationships among six acridid subfamilies were(Oedipodinae+(Acridinae+(Gomphocerinae+(Oxyinae+(Calliptaminae +Cyrtacanthaeridinae))))).However,we did not recover a monophyletic Grylloidea.Myrmecophilidae clustered into one clade with Gryllotalpidae instead of with Gryllidae.ML and BI analyses of all protein coding genes(using all nucleotide sequence data or excluding the third codon position,and amino acid sequences)revealed a topology identical to that of the entire mtDNA genome dataset.However,22 tRNAs genes excluding the DHU loop and T()C loop(TRNA),and two rRNA genes(RRNA)perform poorly when analyzed as single dataset.Our results suggest that the best phylogenetie inferences were ML and BI methods based on total mtDNA.Excluding tRNA genes,rRNA genes and the third codon position of protein coding genes from dataset and converting nucleotide sequences to amino acid sequences do not positively affect phylogenetic reconstruction.     

A preliminary mitochondrial genome phylogeny of Orthoptera (Insecta) and approaches to maximizing phylogenetic signal found within mitochondrial genome data

The phylogenetic utility of mitochondrial genomes (mtgenomes) is examined using the framework of a preliminary phylogeny of Orthoptera. This study presents five newly sequenced genomes from four orthopteran families. While all ensiferan and polyneopteran taxa retain the ancestral gene order, all caeliferan lineages including the newly sequenced caeliferan species contain a tRNA rearrangement from the insect ground plan tRNA(Lys)(K)-tRNA(Asp)(D) swapping to tRNA(Asp) (D)-tRNA(Lys) (K) confirming that this rearrangement is a possible molecular synapomorphy for this suborder. The phylogenetic signal in mtgenomes is rigorously examined under the analytical regimens of parsimony, maximum likelihood and Bayesian inference, along with how gene inclusion/exclusion, data recoding, gap coding, and different partitioning schemes influence the phylogenetic reconstruction. When all available data are analyzed simultaneously, the monophyly of Orthoptera and its two suborders, Caelifera and Ensifera, are consistently recovered in the context of our taxon sampling, regardless of the optimality criteria. When protein-coding genes are analyzed as a single partition, nearly identical topology to the combined analyses is recovered, suggesting that much of the signals of the mtgenome come from the protein-coding genes. Transfer and ribosomal RNAs perform poorly when analyzed individually, but contribute signal when analyzed in combination with the protein-coding genes. Inclusion of third codon position of the protein-coding genes does not negatively affect the phylogenetic reconstruction when all genes are analyzed together, whereas recoding of the protein-coding genes into amino acid sequences introduces artificial resolution. Over-partitioning in a Bayesian framework appears to have a negative effect in achieving convergence. Our findings suggest that the best phylogenetic inferences are made when all available nucleotide data from the mtgenome are analyzed simultaneously, and that the mtgenome data can resolve over a wide time scale from the Permian (approximately 260 MYA) to the Tertiary (approximately 50 MYA).     

直翅目昆虫分子系统学研究新进展

对1994年以来国内外在直翅目昆虫种群遗传变异及进化、种及种下阶元的分类鉴定、种上阶元的系统发育分析及分子进化等分子系统学方面的研究进展进行了综述。近年来,蝗亚目昆虫分子系统学方面的研究成果较为丰富,而有关螽亚目的分子系统学研究较少。线粒体基因和核基因序列联合分析、整个基因组全序列分析以及分子数据与形态学的密切结合将是分子系统学未来发展的主要研究手段。     

The phylogeny of Orthoptera inferred from mtDNA and description of Elimaea cheni(Tettigoniidae:Phaneropterinae)mitogenome

The complete 15,831 bp nucleotide sequence of the mitochondrial genome from Elimaea cheni(Phaneropterinae)was determined.The putative initiation codon for cox1 was TTA.The phylogeny of Orthoptera based on different mtDNA datasets were analyzed with maximum likelihood(ML)and Bayesian inference(BI).When all 37 genes(mtDNA)were analyzed simultaneously,the monophyly of Caelifera and Ensifera were recovered in the context of our taxon sampling.The phylogeny of Orthoptera was largely consistent with previous phyl...     

Cretaceous origin and repeated tertiary diversification of the redefined butterflies

Although the taxonomy of the ca 18 000 species of butterflies and skippers is well known, the family-level relationships are still debated. Here, we present, to our knowledge, the most comprehensive phylogenetic analysis of the superfamilies Papilionoidea, Hesperioidea and Hedyloidea to date based on morphological and molecular data. We reconstructed their phylogenetic relationships using parsimony and Bayesian approaches. We estimated times and rates of diversification along lineages in order to reconstruct their evolutionary history. Our results suggest that the butterflies, as traditionally understood, are paraphyletic, with Papilionidae being the sister-group to Hesperioidea, Hedyloidea and all other butterflies. Hence, the families in the current three superfamilies should be placed in a single superfamily Papilionoidea. In addition, we find that Hedylidae is sister to Hesperiidae, and this novel relationship is supported by two morphological characters. The families diverged in the Early Cretaceous but diversified after the Cretaceous-Palaeogene event. The diversification of butterflies is characterized by a slow speciation rate in the lineage leading to Baronia brevicornis, a period of stasis by the skippers after divergence and a burst of diversification in the lineages leading to Nymphalidae, Riodinidae and Lycaenidae.     

基于线粒体COI基因全序列的直翅目部分类群系统发育关系分析

该研究基于直翅目56种昆虫的COI基因全序列构建了该目部分类群间的系统发育关系,同时也分析了COI基因编码的氨基酸序列构建直翅目系统发育关系的可靠性。将COI序列按照密码子一、二、三位点划分,分别计算PBS(partioned Bremer support)值,评估蛋白质编码基因密码子不同位点的系统发生信号强度。分析结果支持螽亚目和蝗亚目的单系性;剑角蝗科、斑腿蝗科、斑翅蝗科、网翅蝗科和槌角蝗科5科均不是单系群,科间的遗传距离在0.107~0.153之间变化,与其他科相比遗传距离较小,符合将这5科合并为一科(即蝗科)的分类系统,瘤锥蝗科和锥头蝗科归为锥头蝗总科,癞蝗科单独成为一科,这也与Otte(1997)系统的划分一致。根据PBS值的大小推断密码子第三、第一位点对系统树分支的贡献比第二位点大,并且较长的序列含有较多的信息位点。研究也证实将各物种COI基因之间的遗传距离作为直翅目划分科级阶元的工具是可行的。     

Molecular phylogenetics and historical biogeography among salamandrids of the "true" salamander clade: rapid branching of numerous highly divergent lineages in Mertensiella luschani associated with the rise of Anatolia

Phylogenetic relationships among salamandrids of the "true" salamander clade are investigated using 2019 aligned base positions (713 parsimony informative) of 20 mitochondrial DNA sequences from the genes encoding ND1 (subunit one of NADH dehydrogenase), tRNA(Ile), tRNA(Gln), tRNA(Met), ND2, tRNA(Trp), tRNA(Ala), tRNA(Asn), tRNA(Cys), tRNA(Tyr), and COI (subunit I of cytochrome c oxidase), plus the origin for light-strand replication (O(L)) between the tRNA(Asn) and the tRNA(Cys) genes. Parsimony analysis produces a robust phylogenetic estimate for the relationships of the major groups of "true" salamanders. Strong support is provided for the sister taxon relationship of Chioglossa and Mertensiella caucasica and for the placement of Salamandra and Mertensiella luschani as sister taxa. These relationships suggest two vicariant events between Europe and Anatolia caused by the formation of seaways in the Mediterranean Basin. Molecular divergence indicates an Early Miocene separation of Chioglossa and M. caucasica and a Late Miocene separation of Salamandra and M. luschani. The traditional phylogenetic hypothesis of a monophyletic Mertensiella is statistically rejected, indicating that southwestern and northeastern Anatolian populations have separate historical biogeographic origins. Therefore, we recommend placement of M. luschani in the genus Salamandra. Within M. luschani, six highly divergent lineages showing 7.6 to 10.1% pairwise sequence divergence are identified. Tests using four-taxon subsamples suggest that these lineages diverged nearly simultaneously in the Late Miocene, approximately 6 to 8 million years ago, when extensive uplifting of Anatolia occurred in response to the Arabian collision.     

利用线粒体16S rRNA基因全序列分析直翅目主要类群的系统发生关系

为了构建稳健的直翅目主要类群间的系统发生关系并探讨16S rRNA基因序列在构建直翅目昆虫不同分类阶元系统发生关系时的可行性、功效以及性能,文章测定了直翅目4总科9科18种昆虫的16S rRNA基因全序列,联合已知该基因全序列的其他40种昆虫,构建了直翅目主要类群之间的系统发生关系,并分析了16SrRNA基因全序列的系统发生性能和功效。结果表明,直翅目昆虫的16S rRNA基因全长平均为1 310 bp;除生活方式特化的蚤蝼总科和蝼蛄总科的地位无法确定外,直翅目其他主要类群系统发生关系比较稳定;蝗总科下除了斑翅蝗科和槌角蝗科外,剑角蝗科、斑腿蝗科、网翅蝗科都不是单系群,且用不同的方法构建的系统发生树中聚类情况完全一致,各科间遗传距离差异不大,建议将其合为一科;锥头蝗科、瘤锥蝗科和癞蝗科间的遗传距离差异也不大;在构建系统发生树时,16S rRNA基因环区的信息量要比茎区的大;16S rRNA基因可以构建可靠的直翅目属与种水平和目与亚目高级阶元的系统发生关系,但对科和总科阶元缺乏足够的分辨力。     

Baboon phylogeny as inferred from complete mitochondrial genomes

Baboons (genus Papio) are an interesting phylogeographical primate model for the evolution of savanna species during the Pleistocene. Earlier studies, based on partial mitochondrial sequence information, revealed seven major haplogroups indicating multiple para‐ and polyphylies among the six baboon species. The most basal splits among baboon lineages remained unresolved and the credibility intervals for divergence time estimates were rather large. Assuming that genetic variation within the two studied mitochondrial loci so far was insufficient to infer the apparently rapid early radiation of baboons we used complete mitochondrial sequence information of ten specimens, representing all major baboon lineages, to reconstruct a baboon phylogeny and to re‐estimate divergence times. Our data confirmed the earlier tree topology including the para‐ and polyphyletic relationships of most baboon species; divergence time estimates are slightly younger and credibility intervals narrowed substantially, thus making the estimates more precise. However, the most basal relationships could not be resolved and it remains open whether (1) the most southern population of baboons diverged first or (2) a major split occurred between southern and northern clades. Our study shows that complete mitochondrial genome sequences are more effective to reconstruct robust phylogenies and to narrow down estimated divergence time intervals than only short portions of the mitochondrial genome, although there are also limitations in resolving phylogenetic relationships. Am J Phys Anthropol, 2013. © 2012 Wiley Periodicals, Inc.     

Pleistocene diversification of living squirrel monkeys (Saimiri spp.) inferred from complete mitochondrial genome sequences

In order to enhance our understanding of the evolutionary history of squirrel monkeys (Saimiri spp.), we newly sequenced and analyzed data from seven complete mitochondrial genomes representing six squirrel monkey taxa. While previous studies have lent insights into the taxonomy and phylogeny of the genus, phylogenetic relationships and divergence date estimates among major squirrel monkey clades remain unclear. Using maximum likelihood and Bayesian procedures, we inferred a highly resolved phylogenetic tree with strong support for a sister relationship between Saimiri boliviensis and all other Saimiri, for monophyly of Saimiri oerstedii and Saimiri sciureus sciureus, and for Saimiri sciureus macrodon as the sister lineage to the S. oerstedii/S. s. sciureus clade. We inferred that crown lineages for extant squirrel monkeys diverged around 1.5 million years ago (MYA) in the Pleistocene Epoch, with other major clades diverging between 0.9 and 1.1 MYA. Our results suggest a relatively recent timeline of squirrel monkey evolution and challenge previous conceptions about the diversification of the genus and its expansion into Central America.     

基于线粒体ND2基因的直翅目部分种类分子系统发育分析

测定了39种直翅目昆虫线粒体ND2基因全长序列,联合GenBank中41种直翅目昆虫的ND2基因序列,探讨ND2基因在解决直翅目系统发育分析上的功效,为建立直翅目的主要类群之间稳定的系统发育关系提供更多的数据。研究结果表明,直翅目昆虫的ND2基因序列全长为996～1 029 bp,平均长度为1 020 bp,A+T含量平均为73%。用贝叶斯法(Bayesian,BI)、最简约法(maximum parsimony,MP)和最大似然法(maximum likelihood,ML)构建系统树,SH检验显示,RAxML法构建的ML树似然值最大,与PAUP*的ML法构建的ML树差异显著,而与贝叶斯树和简约树没有明显差异。所有系统树都显示直翅目为单系群;而蝗亚目的剑角蝗科、网翅蝗科、槌角蝗科和斑腿蝗科均不是单系群,锥头蝗科与瘤锥蝗科亲缘关系较近,这与Otte分类系统一致。螽亚目基本由两大分支构成,一支是蝼蛄总科和蟋蟀总科聚集而成,且具有很高的置信度;另一大分支由螽斯总科独自构成。     

A mitochondrial phylogeny of the rainforest skink genus Saproscincus, Wells and Wellington (1984)

The phylogenetic relationships and historical biogeography of 10 currently described rainforest skinks in the genus Saproscincus were investigated using mitochondrial protein-coding ND4 and ribosomal RNA 16S genes. A robust phylogeny is inferred using both maximum likelihood and Bayesian analysis, with all inter-specific nodes strongly supported when datasets are combined. The phylogeny supports the recognition of two major lineages (northern and southern), each of which comprises two divergent clades. Both northern and southern lineages have comparably divergent representatives in mid-east Queensland (MEQ), providing further molecular evidence for the importance of two major biogeographic breaks, the St. Lawrence gap and Burdekin gap separating MEQ from southern and northern counterparts respectively. Vicariance associated with the fragmentation and contraction of temperate rainforest during the mid-late Miocene epoch underpins the deep divergence between morphologically conservative lineages in at least three instances. In contrast, one species, Saproscincus oriarus, shows very low sequence divergence but distinct morphological and ecological differentiation from its allopatric sister clade within Saproscincus mustelinus. These results suggest that while vicariance has played a prominent role in diversification and historical biogeography of Saproscincus, divergent selection may also be important.     

Comparative phylogeography of pitvipers suggests a consensus of ancient Middle American highland biogeography

Aim  We used inferences of phylogenetic relationships and divergence times for three lineages of highland pitvipers to identify broad-scale historical events that have shaped the evolutionary history of Middle American highland taxa, and to test previous hypotheses of Neotropical speciation.
Location  Middle America (Central America and Mexico).
Methods  We used 2306 base pairs of mitochondrial gene sequences from 178 individuals to estimate the phylogeny and divergence times of New World pitviper lineages, focusing on three genera ( Atropoides , Bothriechis and Cerrophidion ) that are broadly co-distributed across Middle American highlands.
Results  We found strong correspondence across three highland lineages for temporally and geographically coincident divergences in the Miocene and Pliocene, and further identified widespread within-species divergences across multiple lineages that occurred in the early–middle Pleistocene.
Main conclusions  Available data suggest that there were at least three major historical events in Middle America that had broad impacts on species divergence and lineage diversification among highland taxa. In addition, we find widespread within-species genetic structure that may be attributable to the climatic changes that affected gene flow among highland taxa during the middle–late Pleistocene.     

Mitochondrial genes from 18 angiosperms fill sampling gaps for phylogenomic inferences of the early diversification of flowering plants

The early diversification of angiosperms is thought to have been a rapid process, which may complicate phylogenetic analyses of early angiosperm relationships. Plastid and nuclear phylogenomic studies have raised several conflicting hypotheses regarding overall angiosperm phylogeny, but mitochondrial genomes have been largely ignored as a relevant source of information. Here we sequenced mitochondrial genomes from 18 angiosperms to fill taxon-sampling gaps in Austrobaileyales, magnoliids, Chloranthales, Ceratophyllales, and major lineages of eudicots and monocots. We assembled a data matrix of 38 mitochondrial genes from 107 taxa to assess how well mitochondrial genomic data address current uncertainties in angiosperm relationships. Although we recovered conflicting phylogenies based on different data sets and analytical methods, we also observed congruence regarding deep relationships of several major angiosperm lineages: Chloranthales were always inferred to be the sister group of Ceratophyllales, Austrobaileyales to mesangiosperms, and the unplaced Dilleniales was consistently resolved as the sister to superasterids. Substitutional saturation, GC compositional heterogeneity, and codon-usage bias are possible reasons for the noise/conflict that may impact phylogenetic reconstruction; and angiosperm mitochondrial genes may not be substantially affected by these factors. The third codon positions of the mitochondrial genes appear to contain more parsimony-informative sites than the first and second codon positions, and therefore produced better resolved phylogenetic relationships with generally strong support. The relationships among these major lineages remain incompletely resolved, perhaps as a result of the rapidity of early radiations. Nevertheless, data from mitochondrial genomes provide additional evidence and alternative hypotheses for exploring the early evolution and diversification of the angiosperms.     

Using regional comparative phylogeographic data from snake lineages to infer historical processes in Middle America

Understanding how historical processes have either similarly, or differentially, shaped the evolution of lineages or biotic assemblages is important for a broad spectrum of fields. Gaining such understanding can be particularly challenging, however, especially for regions that have a complex geologic and biological history. In this study we apply a broad comparative approach to distill such regional biogeographic perspectives, by characterizing sets of divergence times for major biogeographic boundaries estimated from multiple codistributed lineages of snakes. We use a large combined (mitochondrial gene sequence) phylogeographic/phylogenetic dataset containing several clades of snakes that range across Middle America – the tropical region between Mexico and northwestern South America. This region is known for its complex tectonic history, and poorly understood historical biogeography. Based on our results, we highlight how phylogeographic transition zones between Middle and South America and the Nicaragua Depression appear to have undergone multiple episodes of diversification in different lineages. This is in contrast to other examples we find where apparently a single vicariant period is shared across multiple lineages. We specifically evaluate the distributions of divergence time estimates across multiple lineages and estimate the number of temporal periods of lineage diversification per biogeographic break. Overall, our results highlight a great deal of shared temporal divergence, and provide important hypotheses for yet unstudied lineages. These multi‐lineage comparisons across multiple spatial and temporal scales provide excellent predictive power for identifying the roles of geology, climate, ecology and natural history in shaping regional biodiversity.     

Rampant Nuclear Insertion of mtDNA across Diverse Lineages within Orthoptera (Insecta)

Nuclear mitochondrial pseudogenes (numts) are non-functional fragments of mtDNA inserted into the nuclear genome. Numts are prevalent across eukaryotes and a positive correlation is known to exist between the number of numts and the genome size. Most numt surveys have relied on model organisms with fully sequenced nuclear genomes, but such analyses have limited utilities for making a generalization about the patterns of numt accumulation for any given clade. Among insects, the order Orthoptera is known to have the largest nuclear genome and it is also reported to include several species with a large number of numts. In this study, we use Orthoptera as a case study to document the diversity and abundance of numts by generating numts of three mitochondrial loci across 28 orthopteran families, representing the phylogenetic diversity of the order. We discover that numts are rampant in all lineages, but there is no discernable and consistent pattern of numt accumulation among different lineages. Likewise, we do not find any evidence that a certain mitochondrial gene is more prone to nuclear insertion than others. We also find that numt insertion must have occurred continuously and frequently throughout the diversification of Orthoptera. Although most numts are the result of recent nuclear insertion, we find evidence of very ancient numt insertion shared by highly divergent families dating back to the Jurassic period. Finally, we discuss several factors contributing to the extreme prevalence of numts in Orthoptera and highlight the importance of exploring the utility of numts in evolutionary studies.     

Use of mitochondrial DNA sequences to test the Ceratomorpha (Perissodactyla:Mammalia) hypothesis

Wood (J. Mamm. 18, 106–118; 1937) united the superfamilies Tapiroidea sensu stricto and Rhinocerotoidea in the suborder Ceratomorpha and aligned the Ceratomorpha with the suborder Hippomorpha within the order Perissodactyla. Although the monophyly of the Ceratomorpha appears now well-supported in paleontological and morphological analyses, the molecular relationship among the three extant superfamilies Tapiroidea, Rhinocerotoidea, and Equoidea has not yet been examined due to the limited amount of molecular information on tapirs. In the present study, we examined the phylogenetic position of Tapiroidea, represented by the complete mitochondrial cytochrome b gene (1140 bp) of a lowland tapir ( Tapirus terrestris ), and a Indian tapir ( Tapirus indicus ), relative to modern horses, zebras, donkeys, and rhinoceroses. The phylogenetic analyses using standard parsimony, neighbour-joining and maximum likelihood algorithms revealed monophyly of the Perissodactyla and three clearly distinct lineages: the modern horses, tapirs, and rhinoceroses. However, the sister-taxon relationship of the tapirs to either the rhinoceroses or the horses was not resolved conclusively in the bootstrap analysis. Spectral analysis, in which phylogenetic information is displayed independently of any selected tree, revealed that the DNA sequences available do not contain enough phylogenetic signal for any of the alternative hypotheses on the basal diversification of perissodactyls. The short branch lengths among the three perissodactyl lineages suggest that they diverged within a relatively short period, a finding consistent with molecular divergence datings and the fossil evidence that indicates a major radiation of the early perissodactyls approximately 54–50 million years ago.     

Ovčar–Kablar Gorge (SW Serbia) – a new hotspot of Orthoptera diversity

We present a list of Orthoptera from the Ov?ar–Kablar Gorge, situated in western Serbia. During 2015 and 2016 we collected 86 Orthoptera species (50 Ensifera, 36 Caelifera). The majority of the species were registered for the first time for the locality and the presence of Pachytrachis frater (Tettigoniidae) in Serbia is confirmed. This study is intended to provide data for future conservation planning, to expand knowledge about rare species and to point to the high natural value of the Gorge.