First molecular phylogeny of the major clades of Pseudoscorpiones (Arthropoda: Chelicerata)

The phylogenetic relationships of the major lineages of the arachnid order Pseudoscorpiones are investigated for the first time using molecular sequence data from two nuclear ribosomal genes and one mitochondrial protein-encoding gene. The data were analyzed using a dynamic homology approach with the new program POY v.4 under parsimony as the optimality criterion. The data show monophyly of Pseudoscorpiones as well as many of its superfamilies (Feaelloidea, Chthonioidea, Cheiridioidea and Sternophoroidea), but not for Neobisiodea or Garypoidea. Cheliferoidea was not monophyletic either due to the position of Neochelanops, which grouped with some garypoids. In all the analyses, Feaelloidea constituted the sister group to all other pseudoscorpions; Chthonioidea is the sister group to the remaining families, which constitute the group Iocheirata sensu Harvey--a clade including pseudoscorpions with venom glands within the pedipalpal fingers. This phylogenetic pattern suggests that venom glands evolved just once within this order of arachnids.     

The chelifores of sea spiders (Arthropoda,Pycnogonida) are the appendages of the deutocerebral segment

SUMMARY Within the last decade, gene expression patterns and neuro‐anatomical data have led to a new consensus concerning the long‐debated association between anterior limbs and neuromeres in the arthropod head. According to this new view, the first appendage in all extant euarthropods is innervated by the second neuromere, the deutocerebrum, whereas the anterior‐most head region bearing the protocerebrum lacks an appendage. This stands in contrast to the clearly protocerebrally targeted “antennae” of Onychophora and to some evidence for protocerebral limbs in fossil euarthropod representatives. Yet, the latter “frontal appendages” or “primary antennae” have most likely been reduced or lost in the lineage, leading to extant taxa. Surprisingly, a recent neuro‐anatomical study on a pycnogonid challenged this evolutionary scenario, reporting a protocerebral innervation of the first appendages, the chelifores. However, this interpretation was soon after questioned by Hox gene expression data. To re‐evaluate the unresolved controversy, we analyzed neuro‐anatomy and neurogenesis in four pycnogonid species using immunohistochemical techniques. We clearly show the postprotocerebral innervation of the chelifores, which is resolved as the plesiomorphic condition in pycnogonids when evaluated against a recently published comprehensive phylogeny. By providing direct morphological support for the deutocerebral status of the cheliforal ganglia, we reconcile morphological and gene expression data and argue for a corresponding position between the anterior‐most appendages in all extant euarthropods. Consequently, other structures have to be scrutinized to illuminate the fate of a presumptive protocerebral appendage in recent euarthropods. The labrum and the “frontal filaments” of some crustaceans are possible candidates for this approach.     

A diverse chasmataspidid (Arthropoda: Chelicerata) fauna from the Early Devonian (Lochkovian) of Siberia

Examination of material held at the Palaeontological Institute, Moscow, enables the identification of two novel chasmataspidid species: Nahlyostaspis bergstroemi gen. et sp. nov. and Skrytyaspis andersoni gen. et sp. nov. ‘Eurypterus’ stoermeri and ‘Tylopterella’ menneri are both redescribed as chasmataspidids, having previously been assigned to Eurypterida. ‘T’. menneri is transferred to the new genus Dvulikiaspis gen. nov. An identical prosomal structure is identified in ‘Eurypterus’ stoermeri and Heteroaspis novojilovi from the Devonian of Germany and the two species are synonymized, with ‘E’ stoermeri having priority. The previous synonymy of H. novojilovi with Diploaspis casteri is rejected. The presence of ophthalmic ridges is confirmed within Diploaspididae, and new structural characteristics of their bucklers are identified.     

Nucleotide Composition of CO1 Sequences in Chelicerata (Arthropoda): Detecting New Mitogenomic Rearrangements

Here we study the evolution of nucleotide composition in third codon-positions of CO1 sequences of Chelicerata, using a phylogenetic framework, based on 180 taxa and three markers (CO1, 18S, and 28S rRNA; 5,218?nt). The analyses of nucleotide composition were also extended to all CO1 sequences of Chelicerata found in GenBank (1,701 taxa). The results show that most species of Chelicerata have a positive strand bias in CO1, i.e., in favor of C nucleotides, including all Amblypygi, Palpigradi, Ricinulei, Solifugae, Uropygi, and Xiphosura. However, several taxa show a negative strand bias, i.e., in favor of G nucleotides: all Scorpiones, Opisthothelae spiders and several taxa within Acari, Opiliones, Pseudoscorpiones, and Pycnogonida. Several reversals of strand-specific bias can be attributed to either a rearrangement of the control region or an inversion of a fragment containing the CO1 gene. Key taxa for which sequencing of complete mitochondrial genomes will be necessary to determine the origin and nature of mtDNA rearrangements involved in the reversals are identified. Acari, Opiliones, Pseudoscorpiones, and Pycnogonida were found to show a strong variability in nucleotide composition. In addition, both mitochondrial and nuclear genomes have been affected by higher substitution rates in Acari and Pseudoscorpiones. The results therefore indicate that these two orders are more liable to fix mutations of all types, including base substitutions, indels, and genomic rearrangements.     

An exquisitely preserved harvestman (Arthropoda,Arachnida, Opiliones) from the Middle Jurassic of China

Sclerosomatids constitute the largest family of the arachnid order Opiliones, and one of the two families commonly found in the temperate regions of the northern Hemisphere. Harvestmen have a sparse fossil record in the Mesozoic, with only two species known from the Jurassic, one of them poorly preserved and none with precise phylogenetic placement. Here we report a new fossil, Mesobunus dunlopi sp. nov., from the Middle Jurassic (approx. 165 Mya) of Daohugou, Inner Mongolia, China. The new species is related to another genus of the same formation, but the preservation quality and details of the penis and pedipalps allow us to place them in the extant sclerosomatid subfamilies Gagrellinae or Leiobuninae. The first recognisable fossil in this subfamily highlights morphological stasis over ca. 165 Mya and the finding of this species along with lacustrine insects suggests a life mode similar to that of some modern sclerosomatids, and a possible connection between morphological and ecological stasis.     

Telltale eyes: the lateral visual systems of Rhenish Lower Devonian eurypterids (Arthropoda,Chelicerata) and their palaeobiological implications

The compound eyes of three taxa of Rhenish Lower Devonian eurypterids are examined and compared with those known from other eurypterids and the extant horseshoe crab Limulus polyphemus. The lateral eyes of the small species Rhenopterus diensti, a phylogenetically basal representative of the stylonurine clade, are characterized by a comparatively low number of lenses and high interommatidial angle Δφ (2.8°). The comparatively limited visual capacities of R. diensti are more similar to L. polyphemus than to its closer relatives of the eurypterine clade and perhaps this reflects a progression of lateral eye structure in the evolution of eurypterids as a whole. The number of eye facets in Adelophthalmus sievertsi is higher than that in the supposed ambush predator Acutiramus cummingsi, but lower than that in other ‘swimming’ eurypterids (Eurypterina). Due to poor preservation, no other eye parameters could be analysed in this species, but further morphological attributes and geographical distribution designate the mid‐sized A. sievertsi as an able swimmer. A low interommatidial angle Δφ of less than 1° confirms that the visual capacities of Jaekelopterus rhenaniae are in line with an interpretation of this giant species as an active high‐level predator. The inferred lifestyles of adult individuals of these three, co‐occurring Rhenish eurypterids indicate niche differentiation avoiding to some degree the competition for food in their marginal marine to delta plain transitional habitats.     

The Morphology and Some Data on the Anatomy of Pycnogonids of the Family Colossendeidae (Arthropoda: Chelicerata)

Russian Journal of Marine Biology - Pycnogonids are a small group of archaic primarily marine chelicerates. They exhibit an unusual bauplan and some features that distinguish them from the rest of...     

A comparison of the mitochondrial genomes from two families of Solifugae (Arthropoda: Chelicerata): Eremobatidae and Ammotrechidae

Arachnids are an ancient and diverse group of arthropods, yet few representative mitochondrial genomes have been published for most of the 11 orders. Here, we present and compare sequence and genomic data from two complete mitochondrial genomes from the arachnid order Solifugae (the camel spiders or wind scorpions), representing two families, Ammotrechidae and Eremobatidae. We also make genome-level and sequence comparisons between these taxa and the horseshoe crab, a chelicerate from the sister group to arachnids. In their organization, the two solifuge mitochondrial genomes are similar to that of the horseshoe crab, although both of the solifuges possess a region of repeated sequence. All 13 protein-coding genes and the two ribosomal RNA genes are of similar sizes to those found in the horseshoe crab. The ammotrechid and the eremobatid each have one tRNA gene that differs in location from those of other chelicerates, suggesting that these translocations occurred after the divergence of Solifugae from other arachnid lineages. All 22 tRNA genes in both solifuges are inferred to form secondary structures that are typical of those found in other metazoan mt genomes. However, in the eremobatid, the tRNA(Ser(UCN)) gene in the repeat region appears to have undergone partial duplication and loss of function, and a new tRNA(Ser(UCN)) gene has been created de novo. Our divergence data, in conjunction with the fossil record, indicate that these two solifuge families diverged more than 230 million years ago. Thus, despite several gene rearrangements and duplications, these data indicate a remarkable degree of evolutionary stasis.     

The mitochondrial genome of the predatory mite Metaseiulus occidentalis (Arthropoda: Chelicerata: Acari: Phytoseiidae) is unexpectedly large and contains several novel features

The complete mitochondrial genome of the phytoseiid Metaseiulus occidentalis (Arthropoda: Chelicerata: Acari: Phytoseiidae) has been sequenced. It is 24,961 bp in length and contains a 14,695-bp unique region, a 345-bp triplicated region, and a 9921-bp duplicated region, in that order. The A+T content of the unique region is 76.9% and contains 11 protein coding (COI-III; ATP6-8; CytB; ND1, 2, 4, 5 and 4L), two ribosomal RNA (srRNA and lrRNA), 22 transfer RNA (tRNA) genes, and two copies of D-loop control sequence. Two genes (ND3 and 6) appear to be missing, but there is a large intergenic spacer (390 bp) present, which could contain ND3 if a different codon usage is employed. The gene order is completely different from the pattern in all other known chelicerates, including the horseshoe crab Limulus polyphemus [Lavrov et al., Mol. Biol. Evol., 2000; 17:813-824]. All the inferred tRNA genes are missing the TPsiC arm, but this arm has fused with the variable arm to generate a TV replacement loop. The duplicated region (9921 bp) contains 18 genes in the same order as in the unique region from CytB to tRNA-His, plus one copy of D-loop control sequence (311 bp) and a partial tRNA-Leu2 sequence (34 bp). The small triplicated region (345 bp) contains a D-loop control sequence (311 bp) and a partial tRNA-Leu2 sequence (34 bp). Because of these anomalies, amplifying sequences posed technical difficulties, but were accomplished by using a primer-walking strategy and increasing the AT content to 75% in the high-fidelity PCR dNTP mix. This is the first phytoseiid mitochondrial genome to be completely sequenced and the largest (25 kb) detected from the Chelicerata.     

Humoral Recognition Factors in the Arthropoda. The Specificity of Chelicerata Serum Lectins

Arthropods have the capacity of recognizing self from non-selfin various defense phenomena including hemolymph clotting, phagocytosis,encapsulation, melanization and clearance of the foreign matterwhich must be initiated by a first step of molecular recognition."Natural" and experimentally induced humoral factors have beendescribed which act as hemagglutinins, bacterial agglutinins,precipitins, bactericidal factors, bacteriolysins, hemolysins,opsonins, clotting factors, and lysozymes. Their exact rolein recognition functions has not been fully explored and theirfunction remains unclear. Among these factors, the carbohydrate-bindingmolecules (lectins) are the best characterized in their specificity,physicochemical properties and molecular structure. Arthropodlectins are multimeric, high molecular weight protein (glycoprotein)molecules with a certain degree of heterogeneity in their specificityand structure. In particular, serum lectins from chelicerates(horseshoe crabs, scorpions and spiders) share a common property:the specificity for sialic acids. Arachnids and merostomes divergedin the earliest Cambrian. Since they occupy markedly differenthabitats, the sialic acid specific lectins most probably area relict rather than an adaptative character. In addition tothis common feature of specificity, lectins from cheliceratesand other arthropods represent heterogeneous populations whichcan bind a wide variety of carbohydrates, many of them presenton bacteria as D-galactose, 2-keto-3-deoxyoctonate, glucuronicacid, N-acetylmuramic acid, and colominic acid. Multiplicityin specificity suggests that serum lectins might contributeas a carbohydrate-based recognition system for the non-self.The requirement for avoiding self recognition would be thatcarbohydrate structures potentially recognized by the systemwould be absent, masked or out of reach of this humoral factoror cell associated recognition factors.     

Evolution of hyperflexible joints in sticky prey capture appendages of harvestmen (Arachnida,Opiliones)

The rigid leg segments of arthropods are flexibly connected by joints, which usually consist of two ball-and-bowl hinges, permitting a uniaxial pivoting up to 140°. Here, we report the occurrence of hyperflexible joints (range of movements?=?160–200°) in the pedipalps (second pair of appendages) of some harvestmen (Sabaconidae and Nemastomatidae), representing some of the most flexible leg joints among arthropods. Hyperflexion is achieved by a reduction of hinges and a strong constriction of the joint region. We demonstrate that hyperflexion occurs during prey capture and is used to clamp appendages of the prey, in addition to attachment by glue secreted by specialized setae. By means of high-speed video recordings, we found that in the Sabaconidae the tibiotarsal joint of the pedipalp can flex extremely rapidly (<5 ms), limiting prey escape. This is the fastest reported predatory strike in arachnids and caused both by leverage and a click mechanism. By comparative analysis of different related taxa, we retraced joint evolution and found that hyperflexion has independently evolved in Sabaconidae and Nemastomatidae, with totally different joint kinematics. We hypothesize that (rapid) hyperflexion evolved to enhance the efficiency of the pedipalp as a means of prey capture, because in springtails detachable scales limit the action of the sticky secretion of pedipalpal setae.     

Morphology of the mandibles in the millipedes (Diplopoda, Arthropoda)

The mouthparts of seven species from five families of Diplopoda have been investigated with scanning electron microscopy. The distal segment of the mandible, the gnathal lobe, is the most complex structure. Although the biting and crushing parts among the examined genera arc always based on the same general scheme, typical modifications of these structures exist which are regarded to be taxon-specific. The density of the teeth on the pectinate lamellae appears to determine the size of the ingested food particles. A well-developed anterior fringe does not seem to be necessary for the ingestion of food.     

Evolution of the secondary structure of the rRNA internal transcribed spacer 2 (ITS2) in hard ticks (Ixodidae, Arthropoda)

ITS2 sequences are used extensively in molecular taxonomy and population genetics of arthropods and other animals yet little is known about the molecular evolution of ITS2. We studied the secondary structure of ITS2 in species from each of the six main lineages of hard ticks (family Ixodidae). The ITS2 of these ticks varied in length from 679 bp in Ixodes scapularis to 1547 bp in Aponomma concolor. Nucleotide content varied also: the ITS2 of ticks from the Prostriata lineage (Ixodes spp.) had 46-49% GC whereas ITS2 sequences of ticks from the Metastriata lineage (all other hard ticks) had 61-62% GC. Despite variation in nucleotide sequence, the secondary structure of the ITS2 of all of these ticks apparently has five domains. Stems 1, 3, 4 and 5 of this secondary structure were obvious in all of the species studied. However, stem 2 was not always obvious despite the fact that it is flanked by highly conserved sequence motifs in the adjacent stems, stems 1 and 3. The ITS2 of hard ticks has apparently evolved mostly by increases and decreases in length of the nucleotide sequences, which caused increases, and decreases in the length of stems of the secondary structure. This is most obvious when stems of the secondary structures of the Prostriata (Ixodes spp.) are compared to those of the Metastriata (all other hard ticks). Increases in the size of the ITS2 may have been caused by replication slippage which generated large repeats, like those seen in Haemaphysalis humerosa and species from the Rhipicepalinae lineage, and the small repeats found in species from the other lineages of ticks.     

Fissiphalliidae, a new family of South American laniatorean harvestmen (Arachnida: Opiliones)

Fissiphalliidae, a new family of the Opiliones suborder Laniatores, is described in the superfamily Gonyleptoidea, based on a new genus (Fissiphallius n. gen.) und 3 new species (F. sturmi n. sp., F. spinulatus n. sp., F. sympatricus n. sp.) from Colombia. Most emphasized are the male genitalic characters, unique in Opiliones: A honzontally split truncus which results in a long movable (glans) and an immovable finger (distal part of the truncus). Both hide the extremely long stylus with the seminal opening at its end. In an expanded state, the movable finger is bent dorsally by an erectile vesicle. It is shown that male genitalic characters in Opiliones display clear functional and constructional traits on the family level. Those characters, if used appropriately, will demonstrate that several families in gonyleptoid Laniatores are polyphyletic and should be divided into several taxa of the family level.     

Phylogeny of the arachnid order Opiliones (Arthropoda) inferred from a combined approach of complete 18S and partial 28S ribosomal DNA sequences and morphology

The phylogenetic relationships among the main evolutionary lines of the arachnid order Opiliones were investigated by means of molecular (complete 18S rDNA and the D3 region of the 28S rDNA genes) and morphological data sets. Equally and differentially weighted parsimony analyses of independent and combined data sets provide evidence for the monophyly of the Opiliones. In all the analyses, the internal relationships of the group coincide in the monophyly of the following main groups: Cyphophthalmi, Eupnoi Palpatores, Dyspnoi Palpatores, and Laniatores. The Cyphophthalmi are monophyletic and sister to a clade that includes all the remaining opilionid taxa (=Phalangida). Within the Phalangida the most supported hypothesis suggests that Palpatores are paraphyletic, as follows: (Eupnoi (Dyspnoi + Laniatores)), but the alternative hypothesis (Laniatores (Eupnoi + Dyspnoi)) is more parsimonious in some molecular data analyses. Relationships within the four main clades are also addressed. Evolution of some morphological characters is discussed, and plesiomorphic states of these characters are evaluated using molecular data outgroup polarization. Finally, Martens' hypothesis of opilionid evolution is assessed in relation to our results.     

Biogeographical variation in the harvestman Mitopus morio (Opiliones, Arachnida)

The taxonomic status of three forms of the harvestman Mitopus morio in Britain have been examined. These have been identified by previous workers as a small, upland M, morio cinerascens , a larger, lowland M. morio morio , and a northern M. morio borealis. In this paper, the delimitation of trinomials has been found to be inappropriate for M. morio. since all three forms have been shown to lie at different points on a continuum of phenotypic variation within the species M. morio. It is suggested that this phenotypic variation is mediated by the variation in temperature regimes between different localities.