Brueelia, Bush, 2017
publication ID |
https://doi.org/ 10.11646/zootaxa.4313.1.1 |
publication LSID |
lsid:zoobank.org:pub:A5Fdfba5-F992-44A8-84C2-1756C943C19B |
DOI |
https://doi.org/10.5281/zenodo.5296863 |
persistent identifier |
https://treatment.plazi.org/id/832187E9-FF92-FFE1-FF74-640EFA44FCFF |
treatment provided by |
Plazi |
scientific name |
Brueelia |
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The Brueelia -complex
Ansari (1956a) stated that Brueelia Kéler, 1936a , was a group unified primarily by abdominal characters. He considered the morphological characters of the head, male genitalia, and abdominal chaetotaxy to be “ minor ” or “insignificant” for dividing the genus into smaller groups. However, the phylogeny of Bush et al. (2016) shows that many characters previously treated as “ minor ” or “superficial” actually contain phylogenetic signal. Indeed, genital and preantennal characters, as well as the chaetotaxy of the abdomen, head, and legs appear to be shared derived characters that accurately delimit monophyletic clades of lice presently placed in the genus Brueelia . For Brueelia s. str., the most comprehensive morphological characterization is that of Mey & Barker (2014), who listed 22 different morphological and ecological characters. Their concept of Brueelia s. str. also includes species that here we place either in Olivinirmus Złotorzycka, 1964 or in Guimaraesiella Eichler, 1949. Thus, their characters are most appropriate for delimiting the core genera within the Brueelia -complex.
Part of the difficulty in clearly and unambiguously circumscribing either the Brueelia -complex or Brueelia s.
str. lies in the large number of species in these groups, and in the great morphological variation between and within some groups. Clay & Tandan (1967) made the first attempt to characterise the Brueelia -complex as a whole. They used seven characters that are found in all known members of this complex, and they listed additional characters that are found in most of the genera they included in the Brueelia -complex. Here we outline the unique characters that keep the Brueelia -complex together, as well as some of the large variation in morphology within this complex.
Diagnosis. The Brueelia -complex can be identified by the combined presence of the following 17 morphological characters: 1) ventral carina interrupted medially and continuing anteriorly towards the frons forming a clypeo-labral suture; 2) avs3 situated near bend of ventral carinae, more or less median to avs2, and not more anteriorly near vsms2; 3) trabecula absent; 4) s5–7 absent; 5) pronotum with 1 seta on each side; 6) prosternal plate absent; 7) metepisternum fully sclerotized laterally; 8) pleurites, if present, fused to tergites; 9) first apparent tergopleural plate (II) without setae on anterior margin; 10) no sts on anterior end of abdominal segment II; 11) no sts on male subgenital plate (abdominal segments VII–XI) (but sternal plate VII has setae if male subgenital plate is divided into sternal plate VII + subgenital plate as in e.g. Turdinirmoides n. gen., Fig. 128 View FIGURES 124 – 129 ); 11) no sts on female abdominal segments VII–XI, except when sternal plate VII is not modified into subgenital plate (as in Mirandofures kamena n. sp., Fig. 97 View FIGURES 92 – 97 ); 12) male tergopleurite IX+X separated from XI by definite suture; 13) male anogenital opening and anal setae dorsal; 14) subvulval plates absent; 15) female subgenital plate present at least as sternal plate VII; 16) endomeres, hypomere, and telomeres fused entirely into mesosomal complex; 17) parameres separate from basal apodeme, but may be fused to mesosome (as in Couala n. gen., Figs 512 View FIGURES 512 – 513 , 522 View FIGURES 520 – 523 ).
The following characters are found in most genera within the Brueelia -complex: 18) if dorsal preantennal suture is present, ads is located in or posterior to suture (except in Meropoecus Eichler, 1940 : Figs 494 View FIGURES 494 – 496 , 499 View FIGURES 499 – 501 ); 19) mts 3 only temporal macroseta [except in Titanomessor n. gen., Fig. 212 View FIGURES 212 – 216 ; Harpactrox n. gen., Fig. 248 View FIGURES 248 – 252 ; Rostrinirmus ruficeps (Nitzsch [in Giebel], 1866), Fig. 439 View FIGURES 439 – 440 ; Motmotnirmus Mey & Barker, 2014 , Fig. 504 View FIGURES 504 – 508 ]; 20) medianly divided tergopleural plates II–IX+X in male and II–VIII in females (except some Hecatrishula n. gen.); 21) abdominal sternites III–VI in form of central plates (but may be absent in at least some segments as in some Sturnidoecus Eichler, 1944 , Figs 377–378 View FIGURES 377 – 378 ; Manucodicola n. gen., Figs 451–452 View FIGURES 451 – 452 , 457–458; Motmotnirmus , Figs 502–503 View FIGURES 502 – 503 ); 22) female subgenital plate reaches to vulval margin (except in e.g. Osculonirmus , Fig. 129 View FIGURES 124 – 129 ; some Mirandofures n. gen., Fig. 97 View FIGURES 92 – 97 ; Turdinirmoides , Fig. 181 View FIGURES 177 – 181 ); 23) lateral setae posterior to vulval margin on raised area of sternal plate (except in Buerelius Clay & Tandan, 1967 , Fig. 510 View FIGURES 509 – 511 ); 24) vss thorn-like (except in Buerelius , Fig. 511 View FIGURES 509 – 511 ).
The phylogeny of Bush et al. (2016) showed that the closest relatives of the Brueelia -complex are a grade of genera primarily occurring on parrots and South American passerines. This group includes Neopsittaconirmus , Formicaphagus , Formicaricola , Paragoniocotes , Psittaconirmus , Theresiella , Forficuloecus , Psittoecus and Nyctibicola . These genera share the following characters with the Brueelia -complex: ventral carina interrupted medially and continuing anteriorly towards the frons forming a clypeo-labral suture; pronotum with 1 seta on each side; meso- and metanotum fused to form pterothorax; male anogenital opening and anal setae dorsal; trabecula absent; if dorsal preantennal suture is present, ads is located in or posterior to suture; prosternal plate absent; endomeres, hypomere, and telomeres fused entirely into mesosomal complex; parameres separate from basal apodeme; avs3 not situated near vsms2; pleurites, if present, fused to tergites; mts 2 only macroseta. However, members of all these genera can be separated from members of the Brueelia -complex by the presence of setae on the anterior margin of tergopleurite II; these setae are absent in the Brueelia -complex. The sclerotization of the metepisternum is always continuous from the lateral margin of the pterothorax to near the metasternum in the Brueelia -complex, but the extent of sclerotization varies among genera in this sister grade. In all these genera except Nyctibicola and Forficuloecus the tergopleurites are complete medianly, whereas in all Brueelia -complex lice except some Hecatrishula n. gen. tergopleurites II–IX+X in males and II–VIII in females are interrupted medianly. Sensilla s5–7 are absent in all Brueelia -complex genera, but present in some of these closely related genera. For these reasons, we do not presently consider any of these closely related louse genera to be members of the Brueelia -complex. However, future studies of this grade may suggest that a more natural circumscription of the Brueelia -complex must contain these taxa.
Members of the Brueelia -complex share some characters with members of the Philopterus -complex, which often occur on the same hosts. Like the Philopterus -complex ( Mey 2004; Philopterinae, sensu Eichler 1963 ), the genera of the Brueelia -complex have a medianly interrupted ventral carina that extends anteriorly, and medianly divided tergopleurites II–IX+X in male and II–VIII in females (except some Hecatrishula ). However, the two complexes can be separated by the following characters: trabecula are present in the Philopterus -complex but are absent in the Brueelia -complex; metepisterna do not extend medianly in the Philopterus -complex, but do extend medianly to near the metasternum in the Brueelia -complex; prosternal plate is present in the Philopterus -complex but absent in the Brueelia -complex; subvulval plates present in Philopterus -complex but absent in Brueelia - complex; parameres fused to basal apodeme in Philopterus -complex, but separate from basal apodeme in Brueelia - complex.
The following characters also separate most of the species in the two complexes: os macrosetae in Philopterus - complex (except Cincloecus Eichler, 1951a ), but microseta in the Brueelia -complex (except Rostrinirmus ruficeps , Fig. 450 View FIGURES 441 – 450 ); pos macro- or mesoseta in several Philopterus -complex genera, but microsetae or absent in Brueelia - complex; ads is located on dorsal anterior plate in Philopterus -complex, but in or posterior to dorsal anterior suture (if present) in Brueelia -complex (except Meropoecus ); mts 1 macroseta and mts 2 often macroseta in Philopterus - complex, but both are microsetae in Brueelia -complex (except Motmotnirmus , Fig. 504 View FIGURES 504 – 508 ).
Mey & Barker (2014) included the Penenirmus -complex ( Penenirmus Clay & Meinertzhagen, 1938 , and Picophilopterus Ansari, 1947 ) within the Brueelia -complex. These two complexes are similar in that both lack trabecula and both have a medianly interrupted, anteriorly bent ventral carina. In addition, the metepisternum extends medianly to near the metasternum in both complexes. However, there are distinct differences. In the Penenirmus -complex, the parameres are fused to the basal apodeme and the anogenital opening is ventral/terminal; in the Brueelia -complex the parameres are articulated with the basal apodeme (but may be fused to the mesosome as in Couala ), and the anogenital opening is dorsal. Males have setae on the subgenital plate and both sexes have setae on the anterior margin of tergopleurite II in the Penenirmus -complex, but not in the Brueelia -complex.
Other characters, with few exceptions, delimit the members of the Penenirmus - and Brueelia -complexes: tergopleurites II–VII are fused medianly in the Penenirmus -complex (except Pe. zeylanicus Dalgleish 1967), but not in the Brueelia -complex [except Hecatrishula docilis n. comb. ( Ansari 1956b)]. Setae mts 1 and sometimes os are macrosetae in the Penenirmus -complex, but these are microsetae in the Brueelia -complex [except in Ro. ruficeps (Nitzsch [in Giebel], 1866), Fig. 439 View FIGURES 439 – 440 ].
Description. Apart from the characters listed above, no other morphological characteristics have been identified that are shared among all lice in this complex. The genera of the Brueelia -complex even vary enormously in gross morphology. For example, all four feather louse “ecomorphs” ( Johnson et al. 2012) known to occur on birds are found within the Brueelia -complex: “head lice”, “wing lice”, “body lice”, and “generalists”. Each of these ecomorphs vary in morphological traits that are associated with the different microhabitats of the body where they are most commonly found. Head lice have large, triangular heads, round bodies, and usually a widely interrupted marginal carina and derivate preantennal area (e.g. Schizosairhynchus n. gen., Figs 463–464 View FIGURES 463 – 464 ; Sturnidoecus Eichler, 1944 , Figs 377–378 View FIGURES 377 – 378 ). Wing lice have long, slender bodies and smaller, triangular or trapezoidal, heads (e.g. Acronirmus Eichler, 1953, Figs 83–84 View FIGURES 83 – 84 ; Aratricerca n. gen., Figs 168–169 View FIGURES 168 – 169 ). Body lice have broadly rounded heads and rounded bodies (e.g. Saepocephalum n. gen., Figs 238–239 View FIGURES 238 – 239 ; Couala n. gen., Figs 512– 513 View FIGURES 512 – 513 ). Generalists have intermediate body forms and are commonly found roaming all over the body of the host (e.g. Mirandofures n. gen., Figs 90–91 View FIGURES 90 – 91 ). These ecomorphs are convergent forms that have evolved repeatedly within the Brueelia -complex (Bush et al. 2016).
Coloration. Coloration within the Brueelia -complex varies from very light and almost translucent to heavily sclerotized and very dark. Extreme colour variation even occurs within some genera (e.g. Brueelia Kéler, 1936a ). Not all lice in the complex are uniformly pigmented, and in some species pigmentation is restricted to parts of the head, thoracic, and abdominal plates, which gives the lice a striated or otherwise distinct appearance (e.g. Corvonirmus Eichler, 1944 , Hecatrishula n. gen., some Brueelia s. str.). Louse colour is not necessarily phylogenetically informative. Bush et al. (2010) showed that colour variation among congeneric lice was associated with the colour of the host. Lice that are similar in colour to the hosts’ feathers are cryptic, and are less likely to be removed when the bird preens, which is a bird’s principal defense against ectoparasitic lice ( Bush et al. 2010). The potential for repeated evolution of cryptic evolution among congeneric lice suggests that the use of pigmentation patterns for generic delimitation (as in Złotorzycka 1964a) may be misleading and should be used cautiously. colour may be informative at the species level, but if pigmentation patterns are used, this should be done cautiously and in combination with other characters, until more is known about colour variation within and between species of lice.
Head. Head shape variable among genera within the complex ( Figs 1–9 View FIGURES 1 – 9 ), as well as within some genera (e.g. Brueelia s. str. and Guimaraesiella Eichler, 1949).
Marginal carina —variable ( Figs 10–18 View FIGURES 10 – 18 ). Marginal carina may be uninterrupted ( Figs 10–11 View FIGURES 10 – 18 ), interrupted submedianly ( Figs 12–13 View FIGURES 10 – 18 ), laterally ( Figs 14– 15 View FIGURES 10 – 18 ), or both ( Fig. 16 View FIGURES 10 – 18 ). Laterally interrupted marginal carinae may be divided into pre- and postmarginal carinae ( sensu Clay 1951 , Fig. 85 View FIGURES 85 – 89 ), or premarginal carina may be absent ( Figs 17–18 View FIGURES 10 – 18 ). The section of the marginal carina between the submedian interruptions may be present ( Fig. 13 View FIGURES 10 – 18 ) or absent ( Fig. 16 View FIGURES 10 – 18 ). Median section of the marginal carina often displaced posteriorly and dorsally at osculum, in which case frons is hyaline ( Figs 11, 15 View FIGURES 10 – 18 ). In some genera marginal carina is not displaced, and there is no hyaline margin ( Fig. 10 View FIGURES 10 – 18 ). Displaced section of marginal carina may be present only as a discrete lateral thickening of the dorsal anterior plate (e.g. Aratricerca , Fig. 170 View FIGURES 170 – 174 ) or as a medianly continuous sinuous thickening of the dorsal anterior plate (e.g. Resartor n. gen., Fig. 163 View FIGURES 163 – 167 ). Displaced section of marginal carina may extend posteriorly into a distinct marginal carinal plate (e.g. Mirandofures kamena n. sp., MCP in Fig. 92 View FIGURES 92 – 97 ).
Hyaline margin —Hyaline margin generally confined to median section ( Fig. 11 View FIGURES 10 – 18 ), but may extend along lateral sides of head ( Fig. 18 View FIGURES 10 – 18 ). In Schizosairhynchus hyaline margin forms fleshy lobes on antero-lateral ends of head ( Figs 465 View FIGURES 465 – 469 , 472 View FIGURES 472 – 476 ).
Dorsal preantennal sutures —may arise from either submedian or lateral interruptions of marginal carina, or both. Extent of dorsal preantennal sutures variable, even within genera (e.g. Guimaraesiella, Figs 361–364 View FIGURES 361 – 364 ). Sutures range from minute dots near base of dsms (some Priceiella n. gen., Fig. 287 View FIGURES 287 – 291 ) to transversally and longitudinally continuous bands delimiting dorsal anterior plate (e.g. Sturnidoecus , Fig. 379 View FIGURES 379 – 383 ). In Priceiella (Thescelovora) n. gen et n. subgen. ( Fig. 302 View FIGURES 302 – 306 ) sutures are longitudinal and may reach both dsms and ads, but sutures do not connect medianly and do not reach margins of head. In Titanomessor n. gen. ( Fig. 212 View FIGURES 212 – 216 ) and Harpactrox n. gen. ( Figs 248 View FIGURES 248 – 252 , 255, 260) dorsal preantennal suture is transversal but does not reach the margins of the head. In Mirandofures ( Fig. 92 View FIGURES 92 – 97 ) dorsal preantennal suture is transversally continuous but does not connect to the hyaline margin. Several genera (e.g. Corvonirmus , Fig. 321 View FIGURES 321 – 326 ) lack dorsal preantennal sutures entirely.
Dorsal anterior plate —present or absent, variable between and within genera. Plate, when present, may be completely separated from main head plate as in Sturnidoecus ( Fig. 379 View FIGURES 379 – 383 ), but is often continuous with main head plate at least posteriorly as in many Guimaraesiella ( Fig. 356 View FIGURES 356 – 360 ). In Priceiella (Thescelovora) ( Fig. 302 View FIGURES 302 – 306 ) doral anterior plate is continuous with main head plate both antero-laterally and posteriorly. In some genera ( Titanomessor , Fig. 212 View FIGURES 212 – 216 ; Harpactrox , Fig. 248 View FIGURES 248 – 252 ) dorsal anterior plate is separated posteriorly but continuous anterolaterally. Posterior margin of dorsal anterior plate may be extended into spur overlapping with main head plate as in Schizosairhynchus n. gen. ( Fig. 465 View FIGURES 465 – 469 ).
Ventral carina and clypeo-labral suture —ventral carina interrupted medianly, bending anteriorly towards frons, thereby forming clypeo-labral suture medianly ( Fig. 20 View FIGURES 19 – 20 ). Clypeo-labral suture reaches anterior margin of head in all genera except Anarchonirmus n. gen. ( Fig. 116 View FIGURES 116 – 121 ), Harpactrox ( Fig. 248 View FIGURES 248 – 252 ), and Saepocephalum ( Fig. 240 View FIGURES 240 – 245 ). Ventral carinae displaced medianly at avs3 ( Fig. 20 View FIGURES 19 – 20 ); may have median finger-like extension on each side near anterior end of pulvinus (e.g. Brueelia pseudognatha n. sp., Fig. 65 View FIGURES 65 – 69 ; Resartor , Fig. 163 View FIGURES 163 – 167 ). In Harpactrox loeiensis n. sp. ( Fig. 248 View FIGURES 248 – 252 ) lateral margins of clypeo-labral suture are not clearly delimited anterior to pulvinus.
Ventral anterior plate —present or absent. When present generally crescent- or square-shaped. In groups where clypeo-labral suture does not reach anterior margin of head, ventral anterior plate not laterally separated from main head plate (e.g. Harpactrox , Fig. 255).
Coni —small ( Figs 10–11 View FIGURES 10 – 18 ) to large ( Fig. 18 View FIGURES 10 – 18 ).
Preantennal nodi —variable between species and genera. Preantennal nodi typically rounded, not extending median to the antennal socket, with defined lateral margin (e.g. Manucodicola n. gen., Fig. 453 View FIGURES 453 – 456 ). In many Brueelia s. str. (e.g. Br. pseudognatha , Fig. 65 View FIGURES 65 – 69 ) lateral margin diffuse or absent. Preantennal nodi prominent in some genera (e.g. Traihoriella Ansari, 1947 , Fig. 265 View FIGURES 265 – 269 ), and extend almost to base of mandibles in some species of Couala ( Fig. 520 View FIGURES 520 – 523 ). Small accessory nodi median to preantennal nodi present in Harpactrox ( Fig. 248 View FIGURES 248 – 252 ).
Pre- and postocular nodi —variable between and within genera. Preocular nodi slightly to considerably larger than postocular nodi. Ocular nodi almost entirely enclose the eye in Nemuus n. gen. ( Fig. 340 View FIGURES 340 – 345 ); nodi almost entirely absent in Acronirmus ( Fig. 85 View FIGURES 85 – 89 ).
Dorsal postantennal suture —present only in Meropoecus Eichler, 1940 ( Figs 494 View FIGURES 494 – 496 , 499 View FIGURES 499 – 501 ), where it is medianly continuous but often diffuse.
Antennae— monomorphic in most genera. Sexually dimorphic antennae do, however, occur sporadically throughout the Brueelia -complex, and may differ even within genera. Among species with dimorphic antennae the male scapes and sometimes the male pedicels larger than those of females (e.g. Anarchonirmus , Figs 116–117 View FIGURES 116 – 121 ; Ceratocista n. gen., Figs 155–156 View FIGURES 155 – 160 ). Flagellomeres generally constant in length and width between sexes even in genera where scapes and pedicel are dimorphic. In Melibrueelia Valim & Palma, 2015 , and Ceratocista ( Fig. 155 View FIGURES 155 – 160 ) flagellomeres of male are wider than those of females. Male flagellomeres are large and bulbous in Anarchonirmus ( Fig. 116 View FIGURES 116 – 121 ) and flagellomere II is extended distally along posterior margin in male Osculonirmus Mey, 1982a ( Fig. 124 View FIGURES 124 – 129 ).
Head chaetotaxy. Setae of the head generally as in Fig. 19 View FIGURES 19 – 20 . In many genera, all setae named by Clay (1951) are present, but presence or absence of specific head setae are important in genus delimitations.
Position of dsms and ads more or less constant throughout Brueelia -complex. In species with dorsal preantennal suture, dsms may be situated in (e.g. Guimaraesiella, Fig. 356 View FIGURES 356 – 360 ), anterior to (e.g. Titanomessor , Fig. 212 View FIGURES 212 – 216 ), or lateral to (e.g. Turdinirmoides australissimus n. sp., Fig. 191 View FIGURES 191 – 195 ) suture, but never median to suture; ads is situated in (e.g. Osculonirmus , Fig. 124 View FIGURES 124 – 129 ) or posterior to suture (e.g. Brueelia phasmasoma n. sp., Fig, 58), but never anterior to suture or on anterior margin or suture. Position of pas more or less constant throughout complex, as in Fig. 19 View FIGURES 19 – 20 . Presence or absence and length of pns, pts and s1–4 diagnostic for some genera; s5–7 absent in all genera of the Brueelia -complex. In most genera pns, pts, and s1–4 are present, but pns is absent in e.g. Ceratocista ( Fig. 155 View FIGURES 155 – 160 ) and both pns and s4 are absent in Brueelia s. str. ( Fig. 44 View FIGURES 44 – 48 ). In Ro. ruficeps (Nitzsch [in Giebel], 1866) os is macroseta ( Fig. 439 View FIGURES 439 – 440 ), but this is not the case in other species of this genus [e.g. Ro. buresi ( Balát, 1958) , Fig. 444 View FIGURES 441 – 450 ], and not the case for any other genus treated here. Position of pos variable, either on eye or posterior to eye. In the genera Acronirmus ( Fig. 85 View FIGURES 85 – 89 ), Ceratocista ( Fig. 155 View FIGURES 155 – 160 ), Resartor ( Fig. 163 View FIGURES 163 – 167 ), Aratricerca ( Fig. 170 View FIGURES 170 – 174 ), and Turdinirmoides n. gen. ( Fig. 177 View FIGURES 177 – 181 ) pos absent. All five mts are present in all genera of the Brueelia -complex except Acronirmus ( Fig. 85 View FIGURES 85 – 89 ), in which mts 1 is absent. The only temporal macrosetae for most genera in complex is mts 3. In Couala ( Fig. 514 View FIGURES 514 – 517 ) mts 2 is ventral, thick, and may be curved ( Fig. 520 View FIGURES 520 – 523 ). In Motmotnirmus Mey & Barker, 2014 ( Fig. 514 View FIGURES 514 – 517 ) mts 2 is macroseta. In Harpactrox ( Fig. 249 View FIGURES 248 – 252 ) all mts are microsetae. In Titanomessor ( Fig. 212 View FIGURES 212 – 216 ) mts 3–5 are of roughly equal length in males, and mts 3–4 are of roughly equal length in females. If present, as1–3 marginal or submarginal. In many genera (e.g. Brueelia s. str., Fig. 19 View FIGURES 19 – 20 ) as3 absent; as2–3 absent in Acronirmus ( Fig. 85 View FIGURES 85 – 89 ). In species with laterally interrupted marginal carina, as3 is situated either anterior to suture (e.g. Mirandofures , Fig. 92 View FIGURES 92 – 97 ) or posterior to suture (e.g. Sturnidoecus , Fig. 379 View FIGURES 379 – 383 ). Location of vsms2 variable, typically on lateral margins of clypeo-labral suture ( Fig. 19 View FIGURES 19 – 20 ), but may be inside clypeo-labral suture [e.g. Br. brachythorax ( Giebel, 1874) , Fig. 44 View FIGURES 44 – 48 ]; vsms1 typically lateral or slightly posterior to vsms2. In all Brueelia -complex genera, avs3 is situated near median interruption of ventral carina, clearly separated from vsms2; avs1–2 typically close together, near anterior margin of preantennal nodi. In most genera avs1 is submarginal ( Fig. 20 View FIGURES 19 – 20 ), but may be marginal ( Fig. 19 View FIGURES 19 – 20 ). Position of pcs and mds more or less constant throughout complex, as in Fig. 19 View FIGURES 19 – 20 .
Thorax. Thoracic segments largely similar throughout subfamily.
Prothorax —usually rectangular, broader than long. Proepisternum slender to broad; pleural ridges prominent in some genera (e.g. Resartor , Figs 161–162 View FIGURES 161 – 162 ). Prosternal plate absent. Proepimera generally slender, oblique. Median section of proepimera generally widened anteriorly and posteriorly; posterior extension may be long and curl around coxa II (e.g. Anarchonirmus , Fig. 114 View FIGURES 114 – 115 ). One pronotal post-spiracular seta (ppss) present on each side on postero-lateral corner of pronotum ( Fig. 26 View FIGURE 26 ) or rarely on posterior margin of pronotum ( Schizosairhynchus , Figs 463–464 View FIGURES 463 – 464 ); absent in Meropsiella Conci, 1941b ( Figs 479–480 View FIGURES 479 – 480 ).
Pterothorax— typically short and wide, roughly pentagonal in shape (see e.g. Brueelia s. str., Figs 42–43 View FIGURES 42 – 43 ); hexagonal in Aratricerca ( Figs 168–169 View FIGURES 168 – 169 ). Meso- and metasternal plates may or may not be fused. Pteronotum not medianly divided, except partially in posterior end in Schizosairhynchus ( Figs 463–464 View FIGURES 463 – 464 ). Metepisternum continuous from metasternum to lateral margin of pterothorax. Metepimeron much thickened in some genera (e.g. Indoceoplanetes n. gen., Figs 217–218 View FIGURES 217 – 218 ). Postero-lateral corner of pterothorax with 1 thorn-like (here pths) and 1 trichoid seta (here ptrs), typically on ventral side; ptrs absent in Osculonirmus ( Figs 122–123 View FIGURES 122 – 123 ). Marginal mesometanotal setae (mms) variable, typically forming sparse rows along outer third of pterothorax on each side (e.g. Titanomessor , Figs 210–211 View FIGURES 210 – 211 ). In some genera mms clustered near poster-lateral corners (e.g. Aratricerca , Figs 168–169 View FIGURES 168 – 169 ), in other genera mms form continuous row along posterior margin (e.g. Sturnidoecus , Figs 377–378 View FIGURES 377 – 378 ). Numbers of setae on pteronotum vary among genera and species.
Leg chaetotaxy —illustrated for coxae, trochanters, and femora in Fig. 25 View FIGURES 25 ; cI-d1, cI-a1–4, cI-v3, tI-v2, fI-p2–3, cII-d1, tII-a1, tII-d1, cIII-d1, tIII-a1, tIII-d1 are typically very small and inconspicuous, especially if specimens are small, darkly pigmented, or poorly mounted. Leg setae are generally constant throughout a given genus, and are often informative for delimitations of genera and higher levels. However, some groups show slight differences in leg chaetotaxy between species groups.
Abdomen. Abdominal shape varies from slender (e.g. Acronirmus, Figs 83–84 View FIGURES 83 – 84 ) to rotund (e.g. Schizosairhynchus , Figs 463–464 View FIGURES 463 – 464 ). Typically, males shorter and broader than females.
Tergopleurites— tergites and pleurites are fused into tergopleurites. Male tergopleurites II–IX+X divided medianly ( Fig. 26 View FIGURE 26 a) except for male segment IX+X in some Hecatrishula ; in other Hecatrishula all tergopleurites connected medianly by narrow bridge (not illustrated). Female tergopleurites II–VIII divided medianly, tergopleurite IX+X transversally continuous ( Fig. 26 View FIGURE 26 b), except in Aratricerca ( Fig. 169 View FIGURES 168 – 169 ). Rarely, female tergopleurite IX+X fused with tergopleurite XI [e.g. Resartor , Fig. 162 View FIGURES 161 – 162 ; Indoceoplanetes (Capnodella) n. gen. & n. subgen., Fig. 225 View FIGURES 224 – 225 ; Melibrueelia ]. Some genera (e.g. Priceiella , Figs 285–286 View FIGURES 285 – 286 ) with conspicuous ridges anterior to spiracle openings (here pre-spiracular ridges, PSR in Fig. 285 View FIGURES 285 – 286 ). In some genera tergopleurites do not reach lateral margins of abdomen (e.g. Anarchonirmus , Figs 114–115 View FIGURES 114 – 115 ). Typically tergopleurites extend to ventral side of abdomen, but this is not the case in e.g. some Corvonirmus ( Figs 319–320 View FIGURES 319 – 320 ). Pleural incrassations generally present at least in anterior segments, but often absent on segments VII–IX+X. Pleural incrassations absent in some genera (e.g. most Corvonirmus , Figs 319–320 View FIGURES 319 – 320 ). Pleurites II with median anterior extensions in some genera (e.g. Meropsiella , Figs 479–480 View FIGURES 479 – 480 ). Re-entrant heads of pleurites present or absent.
Sternal plates —if present medianly continuous, typically rectangular, and not approaching ventral section of tergopleurites. Sternal plates absent in anterior segments of Manucodicola ( Figs 451–452 View FIGURES 451 – 452 ) and all segments of some Sturnidoecus ( Figs 377–378 View FIGURES 377 – 378 ) and Motmotnirmus ( Figs 502–503 View FIGURES 502 – 503 ). Females with no sternal plates posterior to vulval margin. Lateral margins may be concave ( Anarchonirmus , Figs 114–115 View FIGURES 114 – 115 ). In some genera sternal plates are crescent-shaped (e.g. some Sturnidoecus , Figs 420–421 View FIGURES 420 – 421 ). Sternal plate II of Schizosairhynchus ( Figs 463–464 View FIGURES 463 – 464 ) modified into transversal band. Accessory sternal plates may be present lateral to medial sternal plates or subgenital plate and pleurites in males [e.g. Brueelia audax ( Kellogg, 1896) , Fig. 71 View FIGURES 70 – 74 ], females ( Meropoecus , Fig. 493 View FIGURES 492 – 493 ), or both sexes ( Schizosairhynchus , Figs 463–464 View FIGURES 463 – 464 ). In some Priceiella ( Fig. 277 View FIGURES 277 – 278 ), accessory sternal plates are present lateral to male subgenital plate. In Aratricerca ( Figs 168–169 View FIGURES 168 – 169 ) at least sternal plate II with thickened lateral and anterior margins.
Male subgenital plate —typically from segment VII to posterior margin of abdomen; does not reach posterior margin in, e.g. Meropoecus ( Fig. 492 View FIGURES 492 – 493 ); divided into sternal plate VII and vaguely delimited subgenital plate in Aratricerca ( Fig. 168 View FIGURES 168 – 169 ) and Turdinirmoides ( Fig. 175 View FIGURES 175 – 176 ). Male subgenital plate may continue around terminal end of the abdomen, forming small dorsal plate (e.g. Hecatrishula , Fig. 138 View FIGURES 138 – 139 ). Male genital opening is dorsal, on segment IX+X, usually with three anal setae on each side.
Female subgenital plate —variable, typically covering segments VII–VIII. Figures 27–41 View FIGURES 27 – 30 View FIGURES 31 – 34 View FIGURES 35 – 38 View FIGURES 39 – 41 introduces the terminology used for the shape of the female subgenital plate within the Brueelia -complex. If at least the median section of the distal margin of the subgenital plate is continuous with the vulval margin, the subgenital plate is said to reach the vulval margin ( Figs 29 View FIGURES 27 – 30 , 35–38 View FIGURES 35 – 38 ). If no section of the distal margin of the subgenital plate is continuous with the vulval margin, but at least the median section is close to the vulval margin (typically reaching to near the vss, e.g. Guimaraesiella, Fig. 360 View FIGURES 356 – 360 ), the submarginal plate is said to approach the vulval margin ( Figs 30 View FIGURES 27 – 30 , 33 View FIGURES 31 – 34 ). In some genera (e.g. Osculonirmus , Fig. 89 View FIGURES 85 – 89 ) the subgenital plate does not approach the vss ( Figs 27, 29 View FIGURES 27 – 30 , 31 View FIGURES 31 – 34 , 40 View FIGURES 39 – 41 ). The distal end of the subgenital plate may be unmodified ( Figs 27–30 View FIGURES 27 – 30 ), but in many genera the distal end is widened laterally and follows the vulval margin. Ansari (1956a) referred to this structure as a “cross-piece”. The term “cross-piece” is here limited to those cases where the widened section of the distal subgenital plate is continuous with the vulval margin ( Figs 35–40 View FIGURES 35 – 38 View FIGURES 39 – 41 ). The cross-piece may be partial ( Fig. 35 View FIGURES 35 – 38 ) in which case it does not reach the lateral ends of the vulval margin, but in most species with a cross-piece, this structure reaches the lateral ends of the vulval margin, in which case it is said to be complete. The cross-piece may be narrow ( Fig. 36 View FIGURES 35 – 38 ) or broad (37). In Anarchonirmus ( Fig. 83 View FIGURES 83 – 84 ) the cross-piece is medianly displaced ( Fig. 38 View FIGURES 35 – 38 ), as the median section of the cross-piece is not continuous with the vulval margin. If the lateral widenings of the subgenital plate are not marginal, these are referred to as lateral submarginal extensions ( Figs 32–34 View FIGURES 31 – 34 ). Lateral extensions may be present as small bulges ( Fig. 32 View FIGURES 31 – 34 ) that are limited to the median section, or reach the lateral margins of the vulval margin ( Figs 33–34 View FIGURES 31 – 34 ), and may be narrow ( Fig. 33 View FIGURES 31 – 34 ) or broad ( Fig. 34 View FIGURES 31 – 34 ). In Saepocephalum ( Fig. 181 View FIGURES 177 – 181 ) the sclerotized sections of the vulval margin are separated from the subgenital plate submedianly, and are referred to as lateral marginal plates ( Fig. 39 View FIGURES 39 – 41 ). In Turdinirmoides ( Fig. 181 View FIGURES 177 – 181 ) and Sychraella ( Fig. 113 View FIGURES 108 – 113 ) the vulval margin is scleritozed but the subgenital plate does not reach the sclerotized section, which is referred to as a detached cross-piece ( Fig. 40 View FIGURES 39 – 41 ). In Sychraella ( Fig. 41 View FIGURES 39 – 41 ) the subgenital plate is detached from the sclerotized median section of the vulval margin, which is connected to lateral extensions that reach the lateral ends of the vulval margins; this structure is here termed a laterally submarginal cross-piece.
Abdominal chaetotaxy —variable among genera ( Table 2) and within some genera ( Tables 3–12). Some setal characters are more or less constant throughout complex. No setae in anterior end of tergopleurite II. Typically no setae on subgenital plates of either sex, except oblique set of short setae in females ( Fig. 26 View FIGURE 26 b). Trichoid seta of tergopleurite VIII often located submarginally in grove on tergopleurite. Presence or absence of groups of setae are very useful characters for delimiting genera as discussed below (see also Tables 3–12). The post-spiracular sensillus ( Clay 1954; here pss) is often visible only in segments IV–V, but can be seen in more anterior segments in some genera (e.g. Anarchonirmus , Figs 114–115 View FIGURES 114 – 115 ; Osculonirmus , Figs 122–123 View FIGURES 122 – 123 ) where it is associated with psps in these segments. In Brueelia s. str. ( Figs 42–43 View FIGURES 42 – 43 ), Acronirmus ( Figs 83–84 View FIGURES 83 – 84 ), and some other genera, pss is present also on segments VI–VII, but this is generally not the case in the Brueelia -complex. The pss is lateral to and typically contiguous with the aperture of the psps, but this is not the case in e.g. Anarchonirmus ( Figs 114–115 View FIGURES 114 – 115 ) or Corvonirmus ( Figs 319–320 View FIGURES 319 – 320 ) where the pss does not touch the aperture of the psps. The pss may not differentiate genera within the Brueelia -complex, but may be useful in differentiating higher taxonomic levels.
Genus Sex ps aps psps tps ss sts
Brueelia * M III–VIII V–VII VI–VIII – V–VIII II–VI F IV–VIII – VI–VII – – II–VI Teinomordeus M III–VIII III–VII V–VIII V–VIII III–VIII II–VI F II–VIII – V–VII – VIII II–VI Acronirmus M III–VIII VI–VIII VII–VIII VII–VIII V–VIII II–VI F III–VIII – VII–VIII – VII–VIII II–VI Mirandofures * M IV–VIII – – IV–VIII V–VIII II–VI F III–VIII – – – – II–VI Sychraella M III–VIII IV–V VI–VIII IV–VIII IV–VIII II–VI F III–VIII – – – – II–VI Anarchonirmus M IV–VIII II–V II–VI II–VIII II–VIII II–VI F IV–VIII – II–VI – II–VIII II–VI Osculonirmus M III–VIII – II–VIII – II–VIII II–VI F III–VIII – II–VIII – II–VIII II–VI Hecatrishula M III–VIII – III–VII II–VIII II–VIII II–VI F III–VIII – III–VII II–VIII II–VIII II–VI Psammonirmus . M IV–VIII – IV–VIII V–VIII II–VIII II–VI F IV–VIII – V–VIII V–VIII – II–VI Ceratocista M IV–VIII – V–VII VI–VIII VII–VIII II–VI F II–VIII – V–VIII – – II–VI Resartor * M IV–VIII – IV–VII VI–VIII II–VIII II–VI F IV–VIII – IV–VII – – II–VI ......continued on the next page Genus Sex ps aps psps tps ss sts Buphagoecus M IV–VIII IV–VII III–VIII VIII II–VIII II–VI F IV–VIII – IV–VIII – II–VIII II–VI Rostrinirmus * M IV–VIII II–VII II–VIII VII–VIII II–VIII II–VI F IV–VIII II–VII II–VIII – II–VIII II–VI Manucodicola M IV–VIII VI–VIII IV–VIII VI–VIII II–VIII II–VI F IV–VIII – IV–VIII – II–VIII II–VI Schizosairhynchus M IV–VIII IV–VIII IV–VIII II–VIII II–VIII II–VI F IV–VIII – IV–VIII II–VIII II–VIII II–VI Bizarrifrons M IV–VIII V–VII IV–VIII VI–VIII II–VIII II–VI F IV–VIII – IV–VII – II–VIII II–VI Meropsiella M IV–VIII – IV–VII VI–VIII II–VIII II–VI F IV–VIII – IV–VII – II–VIII II–VI Meropoecus M IV–VIII – II–VIII II–VIII II–VIII II–VI F IV–VIII – II–VIII II–VIII II–VIII II–VI Motmotnirmus M 3 IV–VIII – III–VIII VII–VIII II–VIII II–VI F 4 IV–VIII – III–VIII VIII II–VIII II–VI Buerelius M IV–VIII – IV–VII – II–VIII II–VI F IV–VIII – IV–VII – II–VIII II–VI Couala M III–VIII – VI–VII VII–VIII II–VIII II–VI F III–VIII – VI–VII – II–VIII II–VI Aporisticeras M IV–VIII – IV–VII VI–VIII II–VIII II–VI F IV–VIII – IV–VII – II–VIII II–VI
1 Males of some undescribed species of Thescelovora have aps on tergites VI–VII. 2 Nemuus hoedhri n. sp. has tps also on tergites II–V.
3 An undescribed species from Eumomota superciliosa australis Bangs, 1906 , has 1–3 tps on tergite VI. 4 Motmotnirmus humphreyi lacks tps on tergite VII.
Male genitalia. Male genitalia are variable among genera ( Figs 21–24 View FIGURES 21 – 24 ), and within some genera, where they form the basis of delimited species-groups (e.g. Olivinirmus Złotorzycka, 1964a , Figs 334–337 View FIGURES 334 – 337 ; Sturnidoecus , Figs 384–398 View FIGURES 384 – 389 View FIGURES 390 – 395 View FIGURES 396 – 398 ). In other genera ( Brueelia s. str., Fig. 45 View FIGURES 44 – 48 ; Acronirmus, Fig. 86 View FIGURES 85 – 89 ) male genitalia are more or less identical in structure throughout genus, and only the shape of the genitalic elements differ between species. Most genera within the Brueelia -complex have similar genitalic structures that are described here and illustrated in Figs 21–24 View FIGURES 21 – 24 . The structures of two genera with aberrant genitalia ( Meropoecus , Fig. 495 View FIGURES 494 – 496 ; Aporisticeras n. gen., Fig. 527–530 View FIGURES 526 – 531 ) are not treated here, instead see relevant genus and species descriptions. All other genera treated here follow a general pattern.
Basal apodeme —present, usually large. Lateral margins may be folded medianly in distal end. Lower endomere absent; however several genera have a ventral sclerite which may be remnant of lower endomere (e.g. Hecatrishula , Fig. 135 View FIGURES 132 – 137 ; Corvinirmus, Fig. 324 View FIGURES 321 – 326 ; Schizosairhynchus , Fig. 467 View FIGURES 465 – 469 ). Male genitalia of Aporisticeras (Fig. 538) contain structures that may correspond to the lower endomere. In many genera extrusor muscles well defined as convergent ventral ridges (VR in Figs 22, 24 View FIGURES 21 – 24 ).
Mesosome— the endomeres, hypomere, and telomeres are fused entirely into mesosomal complex; distinct parts cannot be discerned clearly in any genus. To avoid any positive statements of homology we use terms that divide the mesosome into three clearly visible parts: proximal mesosome, mesosomal lobes, and gonopore (see Figs 21–24 View FIGURES 21 – 24 ).
Proximal mesosome —this term refers to the proximal end of the mesosome, which often overlaps with the posterior end of the basal apodeme and/or the parameres. Proximal mesosome may be homologous to antero-dorsal endomere ( sensu Ewing 1932 ) but is completely fused to other parts of mesosomal complex and this cannot be established with certainty. Shape typically variable between species in same genus. Ventral ridges distinctly convergent and wing-shaped (e.g. Rostrinirmus Złotorzycka, 1964a , Figs 442, 446, 449 View FIGURES 441 – 450 ) or band-shaped (e.g. Guimaraesiella, Fig. 357 View FIGURES 356 – 360 ). When present, ventral ridges usually reach or are continuous with gonopore distally and extrusor muscles proximally. Anterior margin of proximal mesosome may be thickened (e.g. Schizosairhynchus , Figs 467 View FIGURES 465 – 469 , 474 View FIGURES 472 – 476 ). In Couala ( Figs 515 View FIGURES 514 – 517 , 521 View FIGURES 520 – 523 ) proximal mesosome is fused to basal apodeme.
Gonopore— present in most genera, but highly modified in some Sturnidoecus ( Figs 384–398 View FIGURES 384 – 389 View FIGURES 390 – 395 View FIGURES 396 – 398 ). Gonopore may be entirely ventral ( Figs 22, 24 View FIGURES 21 – 24 ), or may be located on terminal margin of mesosome ( Figs 21, 23 View FIGURES 21 – 24 ). Gonopore typically visible as a circle or semicircle, and is typically open distally (e.g. Brueelia s. str., Fig. 46 View FIGURES 44 – 48 ), but may be open proximally as well, present as convergent median ridges (e.g. Turdinirmoides , Fig. 178 View FIGURES 177 – 181 ). However, gonopore is usually a ventral dome, in which the ridges or circle are just the outline. Gonopore may be expanded laterally (e.g. Sychraella n. gen., Fig. 111 View FIGURES 108 – 113 ). Distally gonopore may extend posterior to mesosomal lobes (e.g. Hecatrishula atherae , Fig. 135 View FIGURES 132 – 137 ).
Mesosomal lobes —lateral structures of distal mesosome, variable between and within genera. Lobes may be homologous to endomeres, but fused to rest of mesosomal complex. In many groups the shape of lobes, as well as the shapes of structures (carinae, nodi, ridges) on lobes and the position of setae are one of the best ways to recognise closely related species. In some genera lobes form prominent lateral “wings” that overlap considerably with parameres (e.g. Hecatrishula , Fig. 135 View FIGURES 132 – 137 ). Conversely, mesosomal lobes are almost entirely absent in genera like Guimaraesiella s. str. ( Fig. 358 View FIGURES 356 – 360 ) and Traihoriella ( Fig. 274 View FIGURES 272 – 276 ). Lateral and posterior margins usually with carina, distal margin may be fringed, scaly, brush-like, or rugose (e.g. Brueelia s. str., Fig. 46 View FIGURES 44 – 48 ; Psammonirmus n. gen., Fig. 150 View FIGURES 148 – 152 ; Ceratocista , Fig. 158 View FIGURES 155 – 160 ). Postero-lateral corner in many genera with distinct rugose nodi (e.g. Nemuus , Fig. 351 View FIGURES 348 – 353 ). In Couala ( Figs 516 View FIGURES 514 – 517 , 522 View FIGURES 520 – 523 ) mesosomal lobes are partially fused to parameral heads.
Genital chaetotaxy —Up to 6 setae present on each side of mesosome, here tentatively divided into two sets. Anterior mesosomal setae (ames) are located ventrally, anterior to gonopore. Posterior mesosomal setae (pmes) are located lateral or posterior to gonopore, and may be on lateral margin of mesosome. In some genera (e.g. Priceiella , Fig. 289 View FIGURES 287 – 291 ) both ames and pmes are anterior to gonopore; in these cases, we interpret the lateral set, which is typically associated with a marginal thickening of the mesosomal lobes, as ames, and the more median set, typically associated with the gonopore, as pmes. In Buphagoecus husaini ( Ansari, 1968) n. comb. both ames and pmes are located distal to gonopore ( Fig. 432 View FIGURES 431 – 436 ) Other configurations also exist, e.g. Sturnidoecus ( Figs 384–398 View FIGURES 384 – 389 View FIGURES 390 – 395 View FIGURES 396 – 398 ). Sensilliform pmes and ames are typically very hard to see, especially on mesosomes that are partially papillate, rugose, or with multiple ventral folds or thickenings. Lateral pmes and ames are often easy to overlook in noneverted gentalia. Distal part of paramere with 0–2 setae, here called parameral setae 1–2 (pst1–2, Fig. 21 View FIGURES 21 – 24 ); pst1 typically sensillus located centrally on paramers; pst2 sensillus or microseta, located either centrally, laterally, or distally on paramere. Meropoecus ( Fig. 495 View FIGURES 494 – 496 ) and Aporisticeras ( Fig. 529 View FIGURES 526 – 531 ) unique within the Brueelia -complex in having more then two parameral setae.
Parameral heads —shapes differ among genera. In some genera (e.g. some Brueelia , Fig. 61 View FIGURES 58 – 62 ) heads are bluntly rounded with no modifications. In some genera (e.g. Osculonirmus , Fig. 128 View FIGURES 124 – 129 ; Turdinirmus , Fig. 187 View FIGURES 184 – 188 ) heads are bifid. In Hecatrishula ( Figs 136 View FIGURES 132 – 137 , 144 View FIGURES 140 – 145 ) the heads are divided into several anterior points. In Maculinirmus ( Figs 201 View FIGURES 198 – 202 , 208) heads are folded laterally into narrow semi-circle. In many genera (e.g. Corvonirmus , Fig. 325 View FIGURES 321 – 326 ; Guimaraesiella, Fig. 359 View FIGURES 356 – 360 ; Bizarrifrons Eichler, 1938 , Fig. 478 View FIGURES 477 – 478 ) heads extend medianly, and often overlap with the proximal mesosome; these median extensions are often rectangular (e.g. Bizarrifrons , Fig. 478 View FIGURES 477 – 478 ), triangular (e.g. Nemuus , Fig. 344 View FIGURES 340 – 345 ), or oblique finger-like (e.g. some Sturnidoecus , Figs 382 View FIGURES 379 – 383 , 385 View FIGURES 384 – 389 ), but other shapes occur.
Parameral blades —variable among genera. Four basic shapes common: roughly triangular with lateral margin variable, often elongated distally (e.g. Brueelia s. str., Fig. 47 View FIGURES 44 – 48 ); irregularly oval, widening distally (e.g. Maculinirmus , Fig. 201 View FIGURES 198 – 202 ); slenderly rounded-rectangular, tapering only in distal end (e.g. many Sturnidoecus , Fig. 382 View FIGURES 379 – 383 ); elongatedly triangular (e.g. Nemuus , Fig. 344 View FIGURES 340 – 345 ). In some genera, parameral blades are connected to parameral heads by slender parameral neck (e.g. Corvonirmus , Fig. 325 View FIGURES 321 – 326 ). Parameral blades may be curled around mesosome (e.g. Schizosairhynchus , Fig. 466 View FIGURES 465 – 469 ), highly convergent ( Titanomessor , Fig. 215 View FIGURES 212 – 216 ), or highly divergent [ Priceiella (Camurnirmus) n. gen et n. subgen., Fig. 298 View FIGURES 294 – 299 ). Some genera have distinct “heel” on median margin just distal to mesosome (e.g. some Mirandofures , Fig. 104 View FIGURES 100 – 105 ; Anarchonirmus , Fig. 120 View FIGURES 116 – 121 ). Parameral blades of Meropsiella bullockoda ( Williams, 1981) have rugose bands ( Fig. 488 View FIGURES 483 – 491 ).
Female genitalia. Female genitalia more or less constant throughout complex. Vulval margin typically gently rounded, but highly convex in some genera (e.g. Osculonirmus , Fig. 129 View FIGURES 124 – 129 ).
Vulval chaetotaxy is identified in Fig. 26 View FIGURE 26 b. Vulval chaetotaxy typically consisting of one marginal set of slender setae (vms), one submarginal set of thorn-like setae (vss), and one oblique set of slender setae (vos) following lateral margins of subgenital plate. Number, size, and position of setae vary among genera.
In most groups, vss are situated clearly anterior to the vms, but in some groups [e.g. many Priceiella (Thescelovora) , Fig. 306 View FIGURES 302 – 306 ] both vms and vss form a combined row of setae. In these groups, the number of setae in the two different set can still be counted separately as the vms and vss differ in shape and size.
Distally convergent rows of vos typically situated lateral to submarginal plate, but some or all vos may be situated on plate (e.g. Schizosairhynchus , Fig. 469 View FIGURES 465 – 469 ). If cross-piece is present, most vos are typically located anterior to cross-piece. However, 1–3 distal vos typically located near distal margin of subgenital plate. These distal vos are typically located median to the vss (e.g. Nemuus imperator n. sp., Fig. 345 View FIGURES 340 – 345 ). In many genera, there is a gap in the row of vos on each side, so that the distal 1–3 vos are separated from the more proximal ones (e.g. Resartor , Fig. 167 View FIGURES 163 – 167 ). Typically, the vos distal to the gap are longer than the vms, but the same length as the more proximal vos. In addition, in most cases these distal vos are not situated on the vulval margin, but more proximally, often proximal to the vss. If the subgenital plate reaches the vulval margin, the distal vos are often situated on the surface of the subgenital plate (e.g. Brueelia , Fig. 48 View FIGURES 44 – 48 ). If the subgenital plate does not reach the vulval margin, the distal vos are typically situated on the distal margin of the subgenital plate (e.g. Resartor , Fig. 167 View FIGURES 163 – 167 ). Due to the difference in length between these setae and the vms, the more proximal placement of these setae, and the fact that in many groups there is no gap in the row of vos (e.g. Nemuus , Fig. 345 View FIGURES 340 – 345 ) we treat all vos as one set, separate from the vms.
No known copyright restrictions apply. See Agosti, D., Egloff, W., 2009. Taxonomic information exchange and copyright: the Plazi approach. BMC Research Notes 2009, 2:53 for further explanation.
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