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Showing papers on "Vespoidea published in 2015"



Book
12 Aug 2015
TL;DR: It is demonstrated that Ponera {sensu lato) consists of two distinct, non-cognate, and easily distinguished genera, which are confined to the IndoAustralian area, eastern North America and Europe; while the second genus receives most of the former Ponera species, including all of the Neotropical and Ethiopian forms.
Abstract: Most species of Ponera (s. lat.) may be assigned to a newly delimited genus taking the name Hypoponera Santschi (new status, for Ponera subgenus Hypoponera). The 28 living and 1 extinct species remaining in Ponera are monographed, following discussion of the new generic classification. Species described as new are: Ponera alpha, P. angusta (NE New Guinea) ; P. borneensis (Borneo) ; P. chapmani (Negros, Philippines) ; P. manni (Viti Levu, Fiji), P. loi and P. woodwardi (Upolu, Samoa). This is the first of a series of proposed papers dealing with those species assigned to the ant genus Ponera in the classification of Emery (1911) and Wheeler (1922). The EmeryWheeler system has been subject to considerable recent change and will no longer operate successfully in the light of modern knowledge. Recent research has necessitated synonymy of many older genera, as they have merged one into another on critical examination of their status. This paper offers yet another generic change, in this case not a synonymy but a split; for it demonstrates that Ponera {sensu lato) consists of two distinct, non-cognate, and easily distinguished genera. True Ponera contains only 28 living species confined to the IndoAustralian area, eastern North America and Europe; while the second genus receives most of the former Ponera species, including all of the Neotropical and Ethiopian forms. This last assemblage takes the name Hypoponera Santschi (1938) which was originally assigned subgeneric status under Ponera. Santschi's morphological criteria of Hypoponera are taxonomically meaningless, but his type species, Ponera abeillei Andre 1881, belongs in my second genus which must be named accordingly. In addition this study provides a world revision of Ponera, in the newly restricted sense. I have examined many hundreds of specimens of Ponera (sensu lato), including most types. Consequently it can be confidently claimed that all species previously described in Ponera, and congeneric with the type, P. coarctata, are included here. As a sideline to the main study Heer's form-genus Poneropsis has been utilized as a parataxonomic category, containing all but one of the many fossil ants previously assigned to Ponera (Taylor 1964). 1. Based on research completed in partial fulfilment of the requirements for the degree of Doctor of Philosophy at Harvard University. 2. Research supported in part by U. S. National Science Foundation Grant GB-1634. 3. Present address: Entomology Division, CSIRO, Canberra, Australia.

56 citations



Book
08 Aug 2015
TL;DR: This monograph is a continuation of the revisionary studies of the Indo-Australian ant fauna and focuses on the studied species of Aenictus, which are apparently specialized predators of other ant species.
Abstract: All of the known Indo-Australian species of Dorylinae, 4 in Dorylus and 34 in Aenictus, are included in this revision. Eight of the Aenictus species are described as new: artipus, chapmani, doryloides, exilis, huonicus, nganduensis, philiporum and schneirlai. Phylogenetic and numerical analyses resulted in the discarding of two extant subgenera of Aenictus (Typhlatta and Paraenictus) and the loose clustering of the species into 5 informal " groups" within the unified genus Aenictus. A consistency test for phylogenetic characters is discussed. The African and Indo-Australian doryline species are compared, and available information in the biology of the Indo-Australian species is summarized. The " true " army ants are defined here as equivalent to the subfamily Dorylinae. Not included are species of Ponerinae which have developed legionary behavior independently (see Wilson, E. O., 1958, Evolution 12: 24-31) or the subfamily Leptanillinae, which is very distinct and may be independent in origin. The Dorylinae are not as well developed in the Indo-Australian area as in Africa and the New World tropics. Dorylus itself, which includes the famous driver ants, is centered in Africa and sends only four species into tropical Asia. Of these, the most widespread reaches only to Java and the Celebes. Aenictus, on the other hand, is at least as strongly developed in tropical Asia and New Guinea as it is in Africa, with 34 species being known from the former regions and only about 15 from Africa. Aenictus is nevertheless notably poor in dispersal ability, as one might expect in army ants. No species is known from east of New Guinea, while only three species have reached eastern and northern Australia. Dorylines are unknown from the rich fossil ant deposits of the Eocene and Miocene of Europe and North America. This fact is consistent with the apparently youthful character of the distribution of the subfamily in the Indo-Australian area. The Asian Dorylus form very large colonies as do the African species, and the one species on which we have any information (Z>. orientalis) appears to be a general predator. The studied species of Aenictus also form large colonies, consisting of tens of even hundreds of thousands of workers. They are apparently specialized predators of other ant species. This monograph is a continuation of my revisionary studies of the Indo-Australian ant fauna. I have been stimulated and encouraged in this work by Dr T. C. Schneirla's field studies of the behavior of Aenictus colonies in Thailand and the Philippines. Both Dr Schneirla and Dr James W. Chapman, before the latter's recent death, contributed gen428 Pacific Insects Vol. 6, no. 3 erously from their collections and field notes to supply a fuller biological background to what otherwise would have been a much more purely taxonomic treatment. The work has been supported by grant no. GB 1634 from the National Science Foundation. GLOSSARY OF SPECIAL TERMS AND MEASUREMENTS The following terms, which are useful in the description of Dorylinae, either are not found in the ordinary entomological glossary or else require special definition with reference to ants. Basal face (of propodeum). The dorsal surface of the propodeum. Basal tooth. The posteriormost tooth of the masticatory border of the mandible. In IndoAustralian dorylines it is usually as well developed as the apical and preapical teeth. CL Cephalic index. (HW X 100)/HL. Declivitous face (of propodeum). The posterior face of the propodeum, extending to the petiolar junction. 15116 level. The set of species that share at least 15 of the 16 binary characters used (q. v.) with the species under consideration. HL. Head length. As conventionally used in myrmecology, the maximum distance, taken along the midline between the points of intersection of the midline with the lines, drawn perpendicular to the midline, that touch the anteriormost and posteriormost parts of the head exclusive of the mandibles (the posteriormost and anteriormost points need not be on or near the midline). HW. Head width. When the head is viewed in full face, the maximum width taken perpendicular to the midline. This measurement is made across the eyes in the & but above or below the eyes (if these break the profile) in the queen and worker. Mesosoma. The alitrunk, or middle tagma, including the thorax and propodeum together. Microreticulum. A very fine reticulum, where the reticular diameters are of the order of 0.01 mm. For most cases in Aenictus, this is one particular form of the microsculpture generically referred to as " shagreening " by many authors. Parafrontal ridges. Thin, low, bilaterally placed ridges running (in some Aenictus) from the posterior margin of the clypeus longitudinally just laterad to the antennal sockets. Propodeal junction. Line of junction of the basal and declivitous faces (q.v.). SL Scape index (SLxl00) /HW. SL. Scape length. The maximum length of this appendage that can be taken. Subopaque. Four arbitrary degrees in the spectrum of " shininess " are recognized: shining, feebly shining, subopaque, opaque. The first and last are self-explanatory, and the middle two are meant to be (subjectively) two equidistant intermediate steps. Thus subopaque means mostly opaque but with a few points of reflection under ordinary reflected light. Typhlatta spot. The two, symmetrically placed patches of yellow located on the occipital corners or upper genae or overlapping both. They usually contrast with a much darker pigment in surrounding areas and characterize certain species of Aenictus. Typical mandible. In Aenictus, the triangular mandible with more than four teeth on the masticatory border, characterizing species such as pachycerus and peguensis (q. v.) ; contrasted with the thin, 3or 4-toothed mandible of brevicornis, ceylonicus, etc. The designation as " typica l" is arbitrary. 1964 Wilson: Indo-Australian true army ants 429 ANALYSIS OF RELATIONSHIPS In the case of Dorylus, the Indo-Australian and African species together are few enough and the characters clear enough to make firm subjective comparisons. In Aenictus, however, there are many more species to be considered: 34 from the Indo-Australian area and at least 12 from Africa. There are moreover about 20 more or less independent characters available to separate these entities. Thus in evaluating the relationships of the Aenictus species, one has to handle over 900 pieces of information. Subjective evaluation becomes exceedingly difficult unless certain characters are chosen in advance as " more important" than others and used exclusively. The latter crude weighting method is in common usage and is justified provided these characters can be assumed to be the ones that do not show convergence in their evolution. However, in Aenictus, I chose initially to use a " numerical " method consisting simply of matching species according to a list of binary characters, i. e., characters that exist in two states. Sixteen such characters were found convenient in the classification of the genus. I used them, together with a smaller number of continuously varying characters, both in the key and routine verbal descriptions. Most involve the simple presence or absence of structures; several involve a 2-state condition of a structure always present; and a single one, ground coloration, is continuous but still allows a sharp partition of the species. The 16 binary characters are as follows: 1. Antenna 9or 10segmented. 2. Mandible thin, with 3 or 4 teeth; vs. mandible broad, subtriangular, with more than 4 teeth. 3. A gap remaining between the mandibles and clypeus when the mandibles are closed; or not. 4. Clypeus entire vs. emarginate. 5. Clypeus armed with teeth; or not. 6. Parafrontal ridge present vs. absent. 7. Occiput tumulose (as in gracilis) ; or not. 8. Occiput bearing a well-developed collar (as in dentatus) ; or not. 9. Head mostly smooth and shining vs. head mostly microreticulate and opaque. 10. Propodeum mostly smooth and shining vs. propodeum mostly microreticulate and opaque. 11. Pronotum armed (as in cornutus) ; or not. 12. Mesonotum and mesopleuron separated by a ridge; or not. 13. Propodeal junction angulate vs. smoothly rounded. 14. Subpetiolar process large and angulate vs. low and rounded or absent. 15. Typhlatta spots present vs. absent. 16. Ground color yellow vs. light reddish brown or darker. The results are shown in Table 1. These data should be very useful for making a rapid assessment of the purely morphological affinities of any given species, and I have used them as a measure of " relationships " in individual taxonomic descriptions. Can the binary-character counts be used to set up an objective subdivision of the genus ? Applying the methods of numerical taxonomy (R. R. Sokal & R. H. A. Sneath, 1963, Principles of numerical taxonomy, Freeman and Co.) it should be possible to set up objective groupings reproducible on the basis of " phenons." For instance, an 80-phenon connotes a group affiliated at no lower than 8 0 ^ of the similarity scale used in the analysis. Den430 Pacific Insects Vol. 6, no. 3 Table I. The number of binary characters, out of a maximum possible total of 16, held in Twelve African species, their names preceded by a star Cit'), are then added. All of the species Two of those from Africa are apparently undescribed and are indicated here by code numbers

43 citations



Book
25 Aug 2015
TL;DR: The Florida Pheidole fauna is increased to eighteen species and Pheidoles is now the largest ant genus in the state.
Abstract: Until recently only twelve species of Pheidole were reported from Florida, 19 anastasii Emery, l? bicarinata vinelandica Forel, I! dentigula M. R Smith, l? flavens Roger, l? megacephala (Fabricius), l? moerens Wheeler, l? morrisi Forel, I? pilifera (Roger), l? dentata Mayr, l? floridana Emery, l? metallescens Emery andl? sitarches littoralis Cole. The last four have Florida as the type locality. l? pilifera (Roger) is believed to have been erroneously reported from Florida and has been excluded from the Florida fauna l? flavens (Gregg, 1958, nec Roger) is considered a misidentification and to be an undescribed species, l? greggin sp. In addition to l? greggi n sp., 2 additional new species of Pheidole are described from Florida: l? adrianoi n sp., l? carrolli n. sp. An exotic species, l? fallax obscurithorax (= l? fallax arenicola var. obscurithorax Santschi) probably introduced from South America, is also added to the North American ant fauna Pheidole crassicomis Emery and l? diversipilosa Wheeler are recorded for the first time in Florida The latter species is resurrected from synomymy and is elevated to full species. Two additional taxa are elevated to full species: l? vinelandica (= l? bicarinata vinelandica Forel) andl? littoralis (= l? sitarches littoralis Cole). The two new species, l? adrianoi n sp., l? carrolli n sp., plus the introduced species l? fallax obscurithorax Santschi and the recognized species I? diversipilosa Wheeler increase the total Pheidole fauna of North America north of Mexico to seventy-five. The Florida Pheidole fauna is increased to eighteen species and Pheidole is now the largest ant genus in the state. Keys for the identification of both majors and workers are provided Scanning electron micrographs are also provided as identification aides. The ecological behavior and biology of each species is discussed

22 citations


Journal ArticleDOI
TL;DR: Fourteen genera and 33 species of wasps belonging to the family Vespidae are reported from the Indian state of Chhattisgarh, of which seven generA and 23 species are new records for Chhatt isgarh.
Abstract: Fourteen genera and 33 species of wasps belonging to the family Vespidae are reported from the Indian state of Chhattisgarh, of which seven genera and 23 species are new records for Chhattisgarh.

11 citations





Journal ArticleDOI
31 Aug 2015-ZooKeys
TL;DR: 32 species are reported as new for Peru based mainly on the collection of the Natural History Museum, London, with the loss of the endemic status of two species.
Abstract: The first checklist of the Peruvian Hymenoptera listed 1169 species and subspecies of aculeate wasps, including 173 species of Pompilidae, seven of Scoliidae, 39 of Sphecidae and 403 of Vespidae. Herein are reported 32 species as new for Peru based mainly on the collection of the Natural History Museum, London. The loss of the endemic status of two species is also reported: Entypus peruvianus (Rohwer) (Pompilidae: Pepsinae) and Omicron ruficolle schunkei Giordani Soika (Vespidae: Eumeninae).