An annotated checklist of the 128 delphacid planthopper species of Florida, including host data, is presented based on combined specimen and literature records. The list includes 39 genera with 7 new combinations, 6 new synonymies, 3 new species and 16 new state records. The new genus Meristopsis (Delphacini) is here described with 2 new species, M. rhamphis and M. melanosteptos. Muellerianella meadi sp. nov. is also described.
Wilson & McPherson (1980a) provide the only recent compilation of distribution data for delphacids of the United States. Among the conterminous United States, Florida has the most diverse delphacid fauna with over 100 species currently reported. The best surveyed state is Illinois with 72 species (Wilson 1980; Wilson & McPherson 1980a, b). Texas (52 species) and California (45) have fewer species, but are incompletely surveyed; Hawaii has 143 native and 11 introduced delphacids (Asche 1997, 2000). A full understanding of the delphacid fauna of Florida is of particular importance to assist in the recognition of accidentally introduced species, as has already happened in Florida with Harmalia anacharsis Fennah, 1969 (Wooten et al. 1993) and the sugarcane planthopper, Perkinsiella saccharicida Kirkaldy, 1903 (Sosa 1985; Emeljanov 1994; White et al. 1995). The delphacid planthoppers include a number of important agricultural pests not known from the United States such as the brown rice planthopper, Nilaparvata lugens (Stål, 1854), the small brown planthopper, Laodelphax striatellus (Fallen, 1826), and the white-backed planthopper, Sogatella furcifera (Horvath, 1899) (Wilson 2005), the last of which has been erroneously reported from the New World in the past (see Beamer 1952; Asche & Wilson 1990). Both L. striatellus and N. lugens have been intercepted at US ports (unpublished USDA-APHIS-PPQ data). Other delphacid pests from Florida include the native species Liburnia pseudoseminigra (Muir & Giffard, 1924, here transferred to Syndelphax Fennah, 1963a), reported as a pest of St. Augustine grass (Cherry et al. 2006), and the corn planthopper, Peregrinus maidis (Ashmead, 1890).
Here, a checklist of delphacid species from Florida is compiled from the literature and specimens at the Florida State Collection of Arthropods (Gainesville, Florida), with new combinations and synonymies. Three species from Florida are described: a new species of Muellerianella Wagner, 1963, and 2 new species placed in the new genus Meristopsis. This new genus is a member of the Delphacini (Delphacinae), which is most easily defined by the presence of a suspensorium (derived from part of the phallobase and linking abdominal segment 10 to the phallus, see Asche 1985: 56, Fig. 10b; Yang & Chang 2000, e.g., Fig. 339d), the absence of a subanal process on segment 10, and the complete fusion of the phallobase and the aedeagus into a theca (Asche 1985, 1990).
Our objectives are to provide a substantially complete and nomenclaturally accurate checklist of Florida delphacid species and to describe the available new taxa from Florida.
MATERIALS AND METHODS
The checklist of Florida species was updated from Wilson & McPherson (1980a) by compiling more recent literature records and combining them with specimen records compiled from the Florida State collection of Arthropods (FSCA) by Susan Halbert & Kurt Ahlmark (personal communication). Author and year described is reported for all species in Table 1. Host records were compiled from observations and specimen labels by Halbert & Wilson, along with literature records. Scientific names, common names, and authorities of plants are provided based on the USDA PLANTS database (USDA, NRCS 2010). Reported synonymies are made by comparison of primary types, except as otherwise indicated.
For descriptive taxonomy, all available specimens of new taxa were examined. Morphological terminology follows Asche (1985), except that “segment 10” (e.g., DuBose 1960; Gonzon & Bartlett 2008; Bartlett 2010) is used instead of “anal tube”, and “armature” (sensu Muir & Giffard 1924) is used to describe the aedeagal brace on the diaphragm. The heading “genitalia” should be understood to refer to the genitalic and post-genitalic segments of the male. For descriptive purposes, the parameres will be referred to as having a proximal “basal angle” and the pygofer having “ventral angles” (sensu Metcalf 1949), and “aedeagus” is used instead of the more morphologically accurate “theca” (formed when the phallobase forms a tubular fold surrounding the aedeagus and subsequently became fused with the aedeagus, a feature of all Delphacini) to be consistent with other delphacid taxonomic works. Wing venation follows Kukalova-Peck (1978) as interpreted by Dworakowska (1988). Wing venation is illustrated by the right wing shown dorsum up, head left. The generic description of Muellerianella was written following Booij (1981).
Male genitalia were dissected for identification and description as needed using standard taxonomic techniques (e.g., Wilson & McPherson 1980b; Bartlett & Deitz 2000). For dissection, the abdomen was removed and cleared for 12–24 h in 15% potassium hydroxide (KOH), rinsed in water and transferred to glycerol for observation and manipulation. Dissected parts were retained with glycerin in microvials pinned beneath the specimen for storage.
Measurements and photographs were taken using a Nikon SMZ-1500 Digital Imaging Workstation. All photos include a scale bar measuring 0.5 mm unless otherwise noted. Reported measurements are averages in millimeters (mm ± standard deviation), with number measured (n) specified. Total body length was defined as the length from the tip of the vertex to the wing tip; length without wings was also included and was defined as the tip of the vertex to the tip of the abdomen. Width was defined as the width across the mesothorax, including the tegulae. Pronotal and mesonotal length were measured along their respective median carinae. Frontal length was measured along the median carina from the vertex to the frontal clypeal suture; frontal width was measured across the lateral margins, between the antennae. Widths of antennal segments I and II were measured at the widest point. Some measurements are expressed in the descriptions as ratios of length to width (l:w). Length of calcar was measured from the articulation with the tibia to the apex of the calcar.
The distribution of new taxa was inferred from the available specimens. Specimen data are reported as seen on specimen labels. Label data for holotypes are quoted top to bottom with “/” indicating a new line and each label separated by “//”.
Collections from which specimens of described taxa were examined are abbreviated as follows (acronyms following Arnett et al. 1993, except SWWC and VGC):
AMNH—
American Museum of Natural History, Division of Invertebrate Zoology, New York, New York.
FSCA—
Florida State Collection of Arthropods, Division of Plant Industry, Gainesville, Florida.
NCSU—
North Carolina State University, Department of Entomology, Raleigh, North Carolina.
OSUC—
C.A. Triplehorn Insect Collection, Department of Entomology, Ohio State University, Columbus, Ohio.
SEMC—
University of Kansas Biodiversity Institute, Snow Entomological Museum, Division of Entomology, Lawrence, Kansas.
SWWC—
Collection of S. W. Wilson at the University of Central Missouri, Warrensburg, Missouri.
UDCC—
University of Delaware, Department of Entomology and Wildlife Ecology, Insect Reference Collection, Newark, Delaware.
USNM—
National Museum of Natural History, The Smithsonian Institution, Washington, District of Columbia.
VGC—
Vince Golia Collection, associated with Archbold Biological Station Collection (ABSC), Lake Placid, Florida.
RESULTS
The compiled list of Florida delphacids (Table 1) includes 128 species in 39 genera, including 16 new state records. Some endemics (e.g., Rotundifronta lutea Beamer, 1950) have not been reported as collected since originally described. We found only a single Kelisoidea versa Beamer, 1950 specimen (labeled Monroe Co. Little Torch Ter., 5 May 1975) collected since the species was originally described. A number of new Florida records, including Chionomus balboae (Muir & Giffard, 1924), Delphacodes vaccina Caldwell, 1951, Euides guaduae (Muir, 1926), Tagosodes approximatus (Crawford, 1914), T. cubanus (Crawford, 1914), and T. orizicolus (Muir, 1926) are primarily Neotropical species which have been observed in southern Florida; such species probably are adventive. A few additional widespread Neotropical species might be expected in Florida.
TABLE 1.
DELPHACID SPECIES OBSERVED OR REPORTED FROM FLORIDA AND OBSERVED HOSTS (SCIENTIFIC AND COMMON NAMES OF PLANTS FROM USDA PLANTS DATABASE (USDA, NRCS. 2010). NEW HOST RECORDS FROM LABEL INFORMATION OR BY OBSERVATION INDICATED BY AN ASTERISK (*). HOSTS OF MANY PLANTHOPPERS COMPILED BY WILSON ET AL. (1994). COMMON NAME OF PLANTS REPORTED ONLY FOR FIRST INCIDENCE.
CONTINUED
CONTINUED
CONTINUED
CONTINUED
CONTINUED
CONTINUED
CONTINUED
Taxonomic Changes
Several new combinations are made through transfer of species from Delphacodes Fieber, 1866 or Liburnia Stål, 1866. Both Delphacodes and Liburnia are polyphyletic genera with complex taxonomic histories. Recently, the type species of Liburnia was established to be Embolophora monoceros Stål, 1855 (Bartlett 2008; ICZN 2010), an African species in the Stenocraninae; a decision which unequivocally placed all New World Liburnia into incertae sedis. Delphacodes s.l. is a polyphyletic genus (Urban et al. 2010) with about 164 species worldwide; however Delphacodes s.s. is a western Palearctic genus of 10 species (Asche & Remane 1983). The generic placement of all New World Delphacodes s.l. requires reassessment.
TABLE 2.
NEW COMBINATIONS AND SYNONYMIES.
Of 6 new combinations, 5 species are transferred from Delphacodes or Liburnia into Syndelphax Fennah, 1963a. The features of Syndelphax (type species Delphax matanitu Kirkaldy, 1907, a junior synonym of Delphax disonymos Kirkaldy, 1907) were recently discussed by Gonzon & Bartlett (2008) in contrast to the closely related genera Toya Distant, 1906, and Metadelphax Wagner, 1963 (see Urban et al. 2010). We treat the generic name Syndelphax as masculine following the decision of ICZN (1961) concerning Delphax Fabricius, 1798. Specimens of Syndelphax have conspicuous facial carinae and may be brachypterous (often with dark tegmina contrasting with a yellow or stramineous body) or macropterous (with clear wings and a stramineous body). The male pygofer has a conspicuously expanded dorsocaudal angle of the pygofer, which is not medially inflected (as in Toya and Metadelphax), and the genital diaphragm has armature which is much taller than wide and tends to be narrowly spoon-shaped. Here we transfer 4 Florida species from Delphacodes into new combinations in Syndelphax as follows (Table 2): Syndelphax alexanderi (Metcalf, 1923) new comb., Syndelphax floridae (Muir & Giffard, 1924) new comb. (including Syndelphax floridae puertoricensis (Caldwell, 1951) new comb.), Syndelphax fulvidorsum (Metcalf, 1923) new comb., Syndelphax humilis (Van Duzee, 1907) new comb.; and 1 species from Liburnia: Syndelphax pseudoseminiger (Muir & Giffard, 1924) new comb. We also transfer Delphacodes nigripennis (Crawford, 1914) known from localities in the Caribbean and Central America to Syndelphax nigripennis, new comb. In addition, we synonymize Delphacodes uhleri Muir & Giffard, 1924 with Syndelphax alexanderi. The type specimen of D. uhleri is a macropterous male at the USNM.
Additional new combinations are the transfer of 3 Euides species to Pareuidella Beamer, 1951. The genus Euides Fieber, 1866 (type Delphax basilinea Germar 1821), is comprised of 25 species, of which 17 are in the New World. The name Euides is evidently formed from “Eu-”, a Greek prefix meaning good, plus “eidos” from Greek meaning form or image. Euides has been consistently treated as feminine by Fieber (1866) and subsequent authors. The monophyly of Euides has not been established, either with respect to the Old and New World species, or the New World species alone. Phylogenetic analysis of the Delphacini consistently placed Euides speciosa (Boheman, 1830) near, but not monophyletic with, 4 New World Euides (Urban et al. 2010; Pareuidella was not included in this analysis). Euides basilinea and other European species have in common unbranched parameres, a simple genital diaphragm, and strongly asymmetrical processes on segment 10 (and apparently a medioventral tooth on the opening of the pygofer). Most New World Euides have branched parameres, elaborate strongly caudally projecting genital diaphragms, and processes on segment 10 symmetrical or strongly reduced.
Pareuidella Beamer, 1951 (type Pareuidella spatulata Beamer, 1951), was described to include 2 species from the southeastern USA (including Florida), which resemble Euides but with “crown about one-third longer than basal width, narrowing towards apex and diaphragm with an avicephaliform brace just ventrad of aedeagal shaft” (Beamer 1951: 198). Pareuidella shares with Euides magnistyla (Crawford, 1914), Euides triloba (Metcalf, 1923), and Euides weedi (Van Duzee, 1897) general habitus, branched parameres, avicephaliform genital diaphragm and symmetrical processes on segment 10, and so these species are transferred here to Pareuidella: Pareuidella magnistyla new comb., P. triloba new comb., and P. weedi new comb. (Table 2). In addition Euides vanduzeei (Muir & Giffard, 1924) new syn. is synonymized here with P. triloba.
The remaining Euides reported here from Florida, E. fasciatella (Osborn, 1935) and E. guaduae (Muir, 1926) do not share the avicephaliform genital diaphragm and branched parameres with Pareuidella. These 2 species probably do not belong in Euides s.s., but their generic position would probably be best revealed in the context of a review of allied Neotropical taxa. Delphacodes cornuta Beamer, 1948 new syn. described from Florida, is here considered a synonym of Euides fasciatella. The primary type of Euides fasciatella is a female at OSUC. The primary type of Delphacodes cornuta is a male at SEMC (synonymy based on paratypes of D. cornuta).
Additional synonymies are as follows. Megamelanus rufivittatus Ball, 1905 new syn. is a junior synonym of Saccharosydne saccharivora (Westwood, 1833). The type specimen of Megamelanus rufivittatus is at the USNM. Delphacodes xerosa Caldwell, 1951 new syn. is a junior synonym of D. nigrifacies Muir, 1918. The type of Delphacodes xerosa at the USNM is badly damaged, consisting of the dissected genitalia in a microvial with only the hind legs remaining on the point, and as noted by Bartlett (2007: 57), the body may be glued to the point of the type specimen of Nilaparvata gerhardi (Metcalf, 1923). The type specimen of Delphacodes nigrifacies is a brachypterous male at the AMNH. Liburnia breviceps (Dozier, 1922) is reaffirmed as a junior synonym of Nothodelphax slossonae (Ball, 1903). The synonymy was suggested by Metcalf (1923: 148), and later made by Beamer (1946: 87), but Liburnia breviceps has been treated as valid since that time (e.g., Wilson & McPherson 1980a). The type specimen of Liburnia breviceps is probably at OSUC, but could not be found; our synoymy is based on a paratype male from the type locality from NCSU. The type specimen of Nothodelphax slossonae is at the USNM.
Based on examination of descriptions and detailed illustrations of male genitalia it is apparent that Neomegamelanus dorsalis (Metcalf, 1923) new syn. is a synonym of N. spartini (Osborn, 1905). Neomegamelanus spartini was described by Osborn (1905) (as Megamelanus spartini) from specimens collected on Spartina patens in New York and Maryland. McDermott (1952) stated that the types of N. spartini had been lost. Metcalf (1923) described N. dorsalis from specimens collected in New Jersey and Mississippi. McDermott (1952) apparently examined these specimens and a number of others from Florida, Louisiana, and Maryland and redescribed and illustrated N. dorsalis. Comparison of specimens of all Neomegamelanus species - N. dorsalis, N. elongatus (Ball, 1905), N. lautus (Metcalf, 1923), and N. penilautus McDermott, 1952 - with Osborn's (1905) description resulted in only 1 species, N. dorsalis, corresponding closely to N. spartini. Furthermore, Metcalf (1923) misinterpreted Osborn's description of N. spartini as his illustrations do not correspond to the description. The type specimen of Neomegamelanus dorsalis is at the USNM.
DESCRIPTIVE TAXONOMY
MERISTOPSIS NEW GENUS
Type Species
Meristopsis rhamphis sp. nov.
Description
Uniformly brownish-orange, macropters greater than 3.0 mm long, including wings. Head slightly narrower than pronotum. Frons parallel-sided, median carina forked near fastigium, arms closely approximated onto vertex. Antennal segment I much longer than wide, II longer than I, II bearing rows of sensory pustules. Pronotal lateral carinae just reaching hind margin. Hind tibiae with one spine near femoral joint, a second near midlength, and 5 apical teeth grouped 2 + 3. Basitarsus with 7 apical teeth grouped 2 + 5 and second tarsomere with 4 teeth. Calcar tectiform bearing many fine black-tipped teeth. Male pygofer with ventral angles distinct, diaphragm well-developed, armature thickened, carinate along midline, caudally expanded. Parameres flattened, unbranched, diverging with basal angles developed into elongate projections. Suspensorium conspicuous, ring-like. Aedeagus flattened with 1 or more processes. Segment 10 bearing 2 thick, symmetrical, widely separated processes angled caudally or laterocaudally. Female genitalia with tergite 9 (T9) elongate, with a longitudinal groove on midline. Anal tube with caudal aspect of ventral margin broadly notched. Gonacoxae of segment 8 broadest anteriorly, narrowing posteriorly, ca. 1/4 length of T9 and covering base anteroventrally. Lateral gonapophyses of segment 9 elongate, subacute at apex. In lateral view, lateral gonapophyes of segment 9 (LG9) elongate, broadly spatulate and enclosing the heavily sclerotized, saber-shaped median gonapophyses of segment 9 (MG9) which bear a row of teeth on dorsal margin (Fig. 6F).
Remarks
Meristopsis bears a cursory resemblance to Euides, Pareuidella, and Nilaparvata in general size and color, and all have processes on segment 10 and more than 15 teeth on the calcar. As noted above, both Pareuidella and New World Euides have branched (often multiply branched) parameres and strongly projecting processes of the armature (Old World Euides tend to have unbranched parameres but strongly asymmetrical processes on segment 10). Meristopsis is superficially similar to Nilaparvata, but lacks the teeth on the basitarsus characteristic of Nilaparvata. In Meristopsis the stout, laterocaudally or caudally projecting processes of segment 10 are unique, and in combination with the flattened, unbranched parameres and the simple genital diaphragm serve to separate it from all other North American genera. Superficially, the glossy, uniformly brownish-orange color, with the slight infuscation of the fastigium and wings help distinguish this genus.
Etymology.
The genus name is formed from the Greek adjective meristo meaning “divided” and the noun -opsis meaning “face”, and refers to the conspicuous frontal carinae. The name is feminine in gender.
KEY TO SPECIES OF MERISTOPSIS
1. Smaller species (male approximately 3.2, female 3.8 mm); parameres (Fig. 6E) widest subapically with sharp, laterally projecting apices, basal angles developed into elongate projections; aedeagus (Fig. 6C–D) with prominent dorsal projection in basal third; opening above genital diaphragm triangular (Fig. 2D); apices of segment 10 processes projected caudally (Fig. 2E); Florida and Central America Meristopsis melanosteptos
1′. Larger species (male approximately 4.2, female 4.5 mm); parameres (Fig. 5F) widest in basal third with dorsally directed apices, basal angles developed into short, flattened processes; aedeagus (Figs 5C–E) parallel sided with a subapical flange on right and an elongate apical process curved left; opening above genital diaphragm roughly quadrate (Fig. 1D); apices of segment 10 processes curved laterad (Fig. 5B); Florida Meristopsis rhamphis
MERISTOPSIS RHAMPHIS SP. NOV. (Figs. 1 and 5)
Type Locality
USA; Florida, Palm Beach County, Lake Worth.
Diagnosis
Uniformly light brown, over 4 mm. Parameres widest in basal third with dorsally directed apices, basal angles developed into short, flattened processes. Aedeagus parallel sided bearing a subapical flange on right side and an elongate apical process curved left. Genital diaphragm thickened, with median ridge, caudally projected dorsally; opening above genital diaphragm roughly quadrate. Processes of segment 10 curved laterad apically.
Description
Color. General body color light brown (Figs. 1A–B), paler ventrally, glossy. Vertex infuscate at fastigium; paler posterior to submedian carinae. Carinae of head lightly infuscate. Frons paler ventrad; rostrum apex infuscate. Antennae light brown, darker at junction of segments I and II. Pronotum brown, mesonotum darker, carinae concolorous. Intercarinal regions of mesonotum infuscate. Tegulae concolorous with body. Pleural regions brown. Forewings clear, faintly and uniformly infuscate, veins brown. Legs yellow, infuscate at articulation of femur and tibiae. Pygofer light brown.
Structure. Body length (n = 12 unless otherwise indicated; 4♂ and 8♀) ♂ macropter: 4.2 (4.02–4.31), ♀: 4.5 (4.13–4.59). Body length without wings ♂ macropter: 2.9 (2.85–2.93; n = 3); ♀ : 3.3 (2.46–3.66); body width 1.0. Brachypter: none observed. Head slightly narrower than pronotum. Frons (Fig. 1C) roughly twice as long as wide (l:w 1.93:1). Carinae on frons conspicuous. Median carina of postclypeus conspicuous. Ocelli near ventral anterior margin of compound eye. Antennal segment I about twice as long as wide (l:w 2.23:1) and ½ length II (I:II 0.57:1), second segment with 5 irregular rows sensory pustules (with 1, 2, 4, 3, and 2 pustules, although irregular organization makes row assignment difficult). Pronotal lateral carinae diverging, curved caudally to just reach posterior margins. Mesonotal length roughly equal to length of pronotum plus head (0.99:1). Mesonotal lateral carinae originating halfway between mesonotal median carina and anterior lateral margins of mesonotum; slightly diverging and posteriorly curved laterad. Mesonotal median carina becoming obsolete on scutellum. Forewings rounded apically; extended for about ½ length (0.30) beyond abdomen. Forewing with R 3-branched (RA, RP1+2, RP3+4; sometimes with RP3+4 apically branched), MP unbranched and CuA appearing 2 or 3 branched (CuA1a, CuA1b, CuA2 or CuA1 and CuA2); inner and outer subapical cells similar in size. Calcar approximately 2/3 length of basitarsus (0.69:1, n = 11), flattened, tectiform, and narrowing distally to acuminate apex, bearing a continuous row of 18 or more black-tipped teeth on outer lateral margin (range 18–23; n = 11; 20 on holotype).
Genitalia. Male pygofer (Figs. 1E and 5A) rather quadrangular in lateral view, anal angles weakly developed; in caudal view (Fig. 1D) opening wider than tall, margins of opening carinate, ventral margin projecting, concave between. Genital diaphragm roughly twice as wide as tall; armature thickened, weakly carinate along midline, caudally projecting into acute point. Opening between diaphragm and segment 10 in caudal view approximately quadrangular. Parameres (Fig. 5F) narrow, flattened, unbranched, setose; approximate basally, diverging to acutely pointed apices; basal angles expanded into short flattened caudodorsally directed projections; large dorsomedially directed tooth above basal angles and several indistinct subapical teeth on inner and outer margin. Suspensorium distinct, ring-shaped, loosely encircling aedeagus. Aedeagus (Figs. 5C–E) flattened and rather parallel-sided, appearing subapically hooked in right-lateral view; in caudal view bearing 2 processes, an elongate apical process curved left, and a rounded flange in the apical ¾ directed right. Aedeagus armed ventrally with row of approximately 5 fine subapical serrulations. Segment 10 (Figs. 5A and 5B) in lateral view broad, longer than tall, rather quadrate, ventrally concave; ventrocaudally bearing a pair of stout, strongly developed, widely separated processes, broadest basally and narrowing to rounded apex; caudally curved in lateral view and laterally curved in caudal view. Segment 11 about 2/3 length of segment 10 in lateral view.
Remarks
All available specimens are macropterous. All specimens with collection data (9 of 12) were collected at lights. Meristopsis rhamphis can most easily be distinguished from M. melanosteptos by the shape of the parameres and aedeagus. In M. rhamphis, the parameres are widest in basal third with dorsally directed apices, and the basal angles developed into short, flattened processes; as opposed to M. melanosteptos where the parameres are widest subapically, with sharp, laterally projecting apices, and the basal angles developed into elongate projections. The aedeagi of the 2 species are quite different with M. rhamphis bearing an apical process and subapical flange instead of the prominent dorsal process in the basal third. The large size, features of the aedeagus, and the stout, laterocaudally projecting processes of segment 10 serve to distinguish this taxon from any similar species.
Reported Hosts
None.
Distribution
USA: Florida.
Etymology
The species name rhamphis is formed from the Greek word rhamph meaning “hook”, a reference to the hooklike appearance of the apex of the aedeagus in lateral view. The species name is to be regarded as feminine.
Material Examined
Holotype (here designated; FSCA, macropterous male) “Florida, Palm Beach / Co. Lake Worth / Geneva Lakes Court / 8-IV-2004 / Vince Golia / Black Light”. Paratypes. FLORIDA: Palm Beach Co., Lake Worth Geneva Lakes Court, 8-IV-2004, Vince Golia, Black light (3 ♂, VGC), same, 15-V-2003 (1♂, 1♀, VGC), same, 24-V-2003 (15, VGC). Miami-Dade Co., Miami Airport, Fumigation site, 22-IV-2008, Light trap, T. Dobbs (2 ♀, UDCC). Paradise Key, 2-III-1919, H. Barber (1♀, USNM), same, 4-III-1919, (1 ♀, USNM), same, 3-III-1919, Schwarz & Barber (1 ♀, USNM). Highlands Co., Lake Placid, 8 miles S. Archbold Biological Station, 2 September 1982, M. Deyrup, at UV light (1 ♀, VGC).
MERISTOPSIS MELANOSTEPTOS SP. NOV. (Figs. 2, 6 and 9)
Type Locality
Belize, Toledo District
Diagnosis
Uniformly light brown, less than 4 mm. Parameres widest in apical third with laterally hooked apices, basal angles projected into elongate processes. Aedeagus flattened, in lateral view broadening distally to large dorsally projecting curved process; abruptly narrowed to ventrally curved acuminate apex. Genital diaphragm somewhat thickened medially, caudally projected dorsally; opening above genital diaphragm triangular. Processes of segment 10 directed caudad.
Description
Color. General body color uniformly light brown, glossy (Figs. 2A and B). Vertex usually infuscate near fastigium; paler posterior to submedian carinae; carinae concolorous. Frons paler ventrad. Antennae light brown, slightly darker at junction of segments I and II and at antennal sulcus. Pronotum brown, mesonotum darker, carinae concolorous. Tegulae concolorous with body. Forewings clear, faintly and uniformly infuscate, veins brown. Legs uniformly light brown, infuscate at pretarsus. Pygofer light brown, parameres darker.
Structure. Body length (n = 12 unless otherwise indicated; 8♂ and 4♀) ♂ macropter: 3.22 (2.95–3.38), ♀: 3.79 (3.65–3.92). Body length without wings ♂ macropter: 2.29 (2.00–2.48); ♀: 2.71 (2.62–2.88); body width: 0.86. Brachypter: none ob- served. Head narrower than pronotum. Frons (Fig. 2C) more than twice as long as wide (l:w 2.16:1). Carinae on frons and median carina of postclypeus conspicuous. Ocelli near ventral anterior margin of compound eye. Antennal segment I about twice as long as wide (l:w 1.83:1) and ½ length II (I:II 0.53:1), second segment with 5 irregular rows sensory pustules (1, 2, 3–4, 3–4, and 2–3 pustules, holotype with 1, 2, 3, 3, 2, although irregular organization makes row assignment difficult). Pronotal lateral carinae diverging, curved caudally to just reach posterior margin. Mesonotal length roughly equal to length of pronotum plus head (1.10:1). Mesonotal lateral carinae originating near midlength between midline and apices of pronotal lateral carinae; slightly diverging and posteriorly curved laterad. Mesonotal median carina becoming obsolete on scutellum. Forewings rounded apically; extended for about ⅓ length (0.30) beyond abdomen. Forewing (Fig. 9) with R 3-branched (RA, RP1+2, RP3+4), MP unbranched, and CuA appearing 2 or 3 branched (CuA1a, CuA1b, CuA2 or CuA1 and CuA2); inner and outer subapical cells similar in size. Calcar approximately 2/3 length of basitarsus (0.71:1), flattened, tectiform, and narrowing distally to acuminate apex, bearing a continuous row of more than 15 black-tipped teeth on outer lateral margin (range 16–25; 18 on holotype).
Genitalia. Male pygofer (Figs. 2D–E) elongatequadrangular in lateral view, longer ventrally than dorsally; anal angle caudally projected into tooth, and slightly projected at level of base of parameres. In caudal view, opening taller than wide, margins of opening rounded (not carinate). Genital diaphragm strongly concave medially; armature thickened along midline, caudally projecting, weakly carinate along midline between parameres. Opening between diaphragm and segment 10 in caudal view approximately triangular (Fig. 2D). Parameres narrow, flattened, unbranched, setose; approximate basally, diverging to sharply pointed laterally projected apices, widest subapically. Suspensorium distinct, ring-shaped, loosely encircling aedeagus. Aedeagus flattened, in lateral view concave ventrally, broadening from base to large, curved dorsal process located at about 2/3 length; abruptly narrowed in apical ¼ to ventrally curved, acuminate apex; distal third with ventral margin weakly serrulate. Segment 10 in lateral view quadrate, roughly as long as tall, ventrocaudally bearing a pair of strongly developed, widely separated processes, broadest basally, caudally curved, and narrowing to sharp apex. Length of segment 11 subequal to segment 10.
Remarks
All available specimens are macropterous. Available specimens from southern Belize or Northern Guatemala were collected in the 1930s, evidently from light traps, and probably with the specimens collected into alcohol. These specimens were generally not in good condition, but we were unable to find more suitable specimens in more recent collections from a similar geographic area. Specimens labeled “Rio Temas” probably refer to the Temash River in the Toledo District in southern Belize. A single specimen from Florida was observed (also collected at a light), which unfortunately also was poorly preserved.
Features separating the species of Meristopsis are provided in the remarks to M. rhamphis. This species is generally smaller (3.22 vs. 4.19 mm for males) and less robust than M. rhamphis. The form of the aedeagus of Meristopsis melanosteptos, with the large dorsal projection, is unique.
Reported Hosts
None.
Distribution
USA: Florida (Palm Beach County); Belize, Guatemala.
Etymology
The species name melanosteptos is formed from the Greek combining form “melano”- meaning “dark” and steptos (Greek, adjective) meaning “crowned”, in reference to the infuscation of the vertex near the fastigium, which is more conspicuous in this species than in M. rhamphis. The species name is to be regarded as feminine in gender.
Material Examined
Holotype (here designated; macropterous male, NCSU): “Br. Hondora / Rio Temas May 1937 /A. J. White.” Paratypes. USA: FLORIDA: Palm Beach Co., 4 mi SE Canal Point, 16.vii.1973, C. W. O'Brien, Blacklight trap (1 ♂, UDCC). BELIZE (as British Honduras): [Toledo District:] Punta Gorda, May 1930, J. J. White (1 ♂, NCSU); Rio Grande, June 1932, J. J. White (1 ♂, NCSU); Rio Temas [Temash River], May 1937, A. J. White (1 ♂, 6 ♀, NCSU), same, July 1937 (5 ♂, 14 ♀, NCSU, UDCC), same, Aug. 1937 (2 ♂, 12 ♀, NCSU), same, Sept. 1937 (3 ♂, 7 ♀, NCSU). GUATEMALA: [Izabal Department] Morales, Oct. 1930, J. J. White (2 ♂, 1 ♀, NCSU).
MUELLERIANELLA, WAGNER 1963
Type Species
Delphax fairmairei Perris, 1857
Diagnosis
Moderately large and robust delphacids (brachypters body length mostly 2.3–2.5 mm, macrop-
MUELLERIANELLA MEADI SP. NOV. (Figs. 3 and 7)
Type Locality
USA; Florida, Alachua Co., Paynes Prairie.
Diagnosis
Apex of aedeagus with large dorsal apical subtriangular process; aedeagus at midlength with 2 dorsal processes: 1 sinuate anteroventrally-directed spine on left side and 1 caudoventrally-directed spine on right side.
Description
Color. Body (Figs. 3A–B) pale, yellowish to light brown, frons dark brown with mottled pattern. Median and lateral carinae of pronotum and mesonotum pale yellow. Intercarinal regions of pronotum and mesonotum yellow, suggestive of median vitta; outer regions dark brown. Antennae light brown, paler yellow at articulation of antennal segments I and II. Frontal clypeal suture and median carina of frons yellow, lateral margins of frons dark brown. Dark brown mottled coloration on frons, gena. Black spot on mesopleuron. Forewings translucent pale brown, veins slightly infuscate. Slight infuscation at top and bottom edge of wing in lateral view. Legs pale yellow with dark brown coxae and longitudinal dark stripes on tibiae. Pygofer pale.
Structure. Body length (n = 10 unless otherwise indicated; 5♂ and 5♀) ♂ macropter: 3.8 (3.63–3.98), ♀: 4.5 (4.28–4.68). Body length without wings ♂ macropter: 2.3 (2.14–2.43); ♀: 2.8 (2.70–3.01). Brachypter: none observed. Body width 1.1. Head slightly narrower than pronotum. Frons (Fig. 3C) narrow, approximately twice as long as wide (l:w 2.15:1); median and lateral carinae conspicuous. Clypeus with pale, weak median longitudinal carina. Pronotum with lateral carinae curving posterolaterally, paralleling curvature of compound eyes; with prominent median longitudinal carina. Mesonotal lateral carinae originating near midlength between midline and apices of pronotal lateral carinae. Median carina of mesonotum becoming obsolete on scutellum. Length of antennal segment I about 1½ × width (l:w 1.55:1) and about ½ length II (I:II 0.48:1). Mesonotal length roughly ¼ greater than length of pronotum plus head (1.26:1). Forewings rounded apically; extended for about ⅓ length beyond abdomen. Hind tibiae with spine near tarsal joint and a second, less-developed spine near femoral joint, and 5 apical teeth, grouped 2 + 3. Basitarsus with 7 apical teeth (grouped 2 + 5), and second tarsomere with 4 teeth. Calcar slightly shorter in length than basitarsus (0.9:1), calcar flattened, tectiform, and narrowing distally to acuminate apex, bearing a continuous row of more than 15 very small black-tipped teeth on posterolateral margin (15–18) becoming reduced near apex.
Genitalia. Parameres (Fig. 7D) stout, appearing flattened and unbranched, diverging laterally to pointed apices, closely approximated basally, with large dorsomedially directed tooth above basal angles. Diaphragm armature narrow, not strongly developed. Aedeagus (Figs. 7B and C) tubular, broadest basally, strongly arched dorsally, with dorsal transparent membranous subtriangular apex sometimes appearing bifurcate; midlength with 2 strong, subequal posteriorly directed dorsal processes. Segment 10 appearing quadrate, without processes; segment 11 elongate.
Female Genitalia. Tergite 9 (T9) elongate, with a longitudinal groove on midline. Anal tube subcylindrical, dorsoventrally flattened; caudal aspects of dorsal and ventral margins concave; anal style narrowing caudally, subequal in length to anal tube. Gonacoxae of segment 8 subtriangular, ca. ¼ length of T9 and covering it anteroventrally. Lateral gonapophyses of segment 9 elongate, ca. 3/4 length of T9, narrowing and rounded apically. In lateral view, median gonapophyses of segment 9 (MG9) saber-shaped, heavily sclerotized, broad at base, narrowing toward acute apex; row of ca. 25 prominent teeth on dorsal margin in distal 1/2. Gonapophyses of segment 8 enclosing MG9, slightly shorter and narrower than MG9.
Remarks
Muellerianella meadi differs from M. laminalis most conspicuously in having 2 dorsal processes on the aedeagus near midlength and 1 dorsal apical projection, compared with 1 at midlength and 2 apical in M. laminalis. Muellerianella meadi also tends to have a paler frons than M. laminalis. Brachypterous forms are known for M. laminalis but have not yet been observed in M. meadi, as all available specimens from Florida were collected from light traps. As all other Muellerianella species have brachypterous forms, it is probable that there are brachypters of M. meadi. Muellerianella meadi is most similar in male genitalic features to the European M. brevipennis, which has 2 subequal aedeagal spines but has an additional short anteriorly-directed spine on the right side (see Booij 1981, Holzinger et al. 2003). The specimen of M. laminalis reported from Cuba by Rodriguez-León and colleagues (1994) is likely to be M. meadi because M. laminalis appears to be more northern in distribution.
Reported Hosts
None.
Distribution
USA: Florida and possibly Cuba.
Etymology
The species name is named in honor of Dr. Frank Mead, retired from FSCA, who contributed significantly to our knowledge of planthoppers. Dr. Mead originally collected Muellerianella meadi and recognized it as an undescribed species.
Material Examined
Holotype (here designated; FSCA, macropterous male). “Florida, Alachua Co. / Edgecliff Subdivision / S. side Paynes Prairie / 23-VII-1991 / D. H. Habeck / at blacklight”. Paratypes. FLORIDA: Alachua Co., same (5 ♂, 5 ♀, FSCA). Other material examined. Alachua Co., Edgecliff Subdivision, S. side Paynes Prairie 23-VII-1991, D. H. Habeck at blacklight (41 ♂, 143 ♀, FSCA). Gainesville, Doyle Conner Bldg., 21-23-IX-1979, F. W. Mead, Blacklight trap (1♂, FSCA); same, 20-VIII-1979 (1 ♂, 5 ♀, FSCA); same, 7-VII-1978 (1♂, FSCA).
MUELLERIANELLA LAMINALIS (VAN DUZEE)
(Figs. 4 and 8)
= Liburnia laminalis Van Duzee 1897: 251.
= Megamelus laminalis (Van Duzee), new combination by Crawford 1914: 607.
= Liburnia laminalis Van Duzee, restored combination from Megamelus laminalis by Van Duzee 1917: 774
= Delphacodes lateralis (Van Duzee 1897:191) [nec. Fieber, 1879], new combination by Muir & Giffard 1924: 38.
= Delphacodes laterana Metcalf 1943, new name for Delphacodes lateralis (Van Duzee, 1897) [nec. Fieber, 1879] by Metcalf, 1943: 458; synonymy with D. laminalis by Oman, 1947: 212–213.
= Muellerianella laminalis (Van Duzee), new combination by Maw et al. 2000: 85.
Diagnosis
Body length ♂ brachypter = 2.3 mm, ♂ macropter = 4.0; ♀ brachypter = 2.5, ♀ macropter = 4.3. Male genitalia (Figs. 4D and E) with pygofer yellow, most of lateral aspects fuscous; sub-quadrate with caudal margin in dorsal ⅓ extending caudally as a subtriangular extension (Figs. 4E and 8A). Parameres fuscous; in caudal view, spatulate with apices slightly rounded. Aedeagus arched dorsally, with large subtriangular transparent membranous apex; with 1 subapical sinuate anteroventrally-directed spine on left side, and 1 caudoventrally-directed spine originating near middle on dorsal aspect on right side. Female genitalia with tergite 9, in ventral view, elongate, each side broad with length approximately 3x width, apex rounded. Segment 10 subcylindrical. Lateral gonapophyses of segment 9 elongate, spatulate posteriorly. In lateral view, median gonapophyses of segment 9 curved, narrowing toward apex, with about 20 small teeth on dorsal margin in distal one-half.
Distribution
Canada: Ontario, Quebec; USA: California (error?), Connecticut, District of Columbia, Florida, Illinois, Indiana, Kentucky, Louisiana, Maryland, Maine, Massachusetts, Missouri, Mississippi, New Hampshire, New York, North Carolina, Ohio, Pennsylvania, and Tennessee (Metcalf 1943, DuBose 1960, Coley 1970, Wilson & McPherson 1980a, Giri et al. 1985, Maw et al. 2000, Gonzon et al. 2007); also observed Delaware, Nebraska, North Dakota, Texas, Vermont.
Etymology
The species name laminalis is evidently derived from the Latin lamina, meaning “thin plate” or “blade.”
Remarks
Transfer of this species to Muellerianella was made without comment by Maw and colleagues (2000). The similarity of this species to its European congeners was previously noted by Muir & Giffard (1924: 25) who commented that this “… species is closely related to D. fairmairei (Perr.) of Europe”. Descriptions and illustrations of the male genitalia were provided by Muir & Giffard (1924), DuBose (1960), Coley (1970), and Wilson & McPherson (1980b). A few specimens of this species appeared smaller and paler than average (including those noted as a potential new species by Gonzon et al. 2007), but careful review of these specimens confirm that they were M. laminalis.
Material Examined
DELAWARE: Kent Co., Norman G. Wilder WMA, Petersburg Tract, 8-VI-2005 A. Gonzon (13♂, 2 ♀, UDCC); Route 1 & 113 near Milford I. G. Burton Auto Dealer, 21-VIII-2005 A. Gonzon (1♂, UDCC); New Castle Co., Middletown, Brick Mill Farm, 22-VIII-2003 A. Gonzon (14♂, 22♀, UDCC); same, 6-VII-2003; C & D Canal N., Retriever Training Area, 20-VII-2006 A. Gonzon (1♀, UDCC); Glasgow, Frenchtown Woods NA, 19-VI-1999 A. Short (1♀, UDCC); same, 2-VII-2002 C. Bartlett (1♀, UDCC); near Vandyke, Blackbird State Forest, Vandyke Tract, 9-VI-2004 C. Bartlett (25, UDCC); Vandyke, Peter's Tract Blackbird State Forest, 9-VI-2004 N. Nazdrowicz (1♀, UDCC); Brandywine Creek State Park, 18-X-2007 A. Gonzon (7♂, 5♀, UDCC); south of Taylor's Bridge Road near Cedar Swamp WMA, 29-VIII-2003 A. Gonzon (1♀, UDCC); Newark, IX-1988 C. Bartlett (1♂, UDCC); Sussex Co.: Georgetown, 6-X-1999 R. Snyder (2♀, UDCC); circa 2 miles northwest of Georgetown, Wilson Hill Road, 22-VII-2004 A. Gonzon (1♀, UDCC); MAINE: York Co., near Berwick, 15-IX-1999 C. Bartlett (1♂, UDCC); Kittery, 5-IX-1999 C. Bartlett (1♀, UDCC); MARYLAND: Allegeny Co., Little Orleans, 1-VI-2001 C. Bartlett (2♀, UDCC); same, 2-4-VI-2006 (1♀, UDCC); same, 2-VI-2006 R. Rakitov (1♀, UDCC); Cecil Co., Elkton, 6-VIII-2010 L. Barringer (1♀, UDCC); Fair Hill, Fair Hill Natural Resources Area, 17-IX-2010 C. Bartlett (1♂, UDCC); same, 18-IX-2009 (1♀, UDCC); MISSOURI: Johnson Co., Warrensburg, 7-IX-2000, S. Wilson, 23-X-2001 (3♂, SWWC); Taney Co., Ozark Underground Laboratory, 3 mi. N. Protem, 16-IX-2000 (3♂, 3♀, SWWC); NEBRASKA: Jefferson Co., Fairbury, southwest of town, Flathead WMA, 12-VIII-2010 L. Barringer (1♂, UDCC); NEW YORK: Chautauqua Co., Fredonia, 21-VII-1946 (1♂, 1♀, SWWC); NORTH CAROLINA: Haywood Co., Great Smoky Mountains National Park, the Purchase, weather station, 5-12-IX-2003 GJ Steck & BD Sutton (1♀, UDCC); Great Smoky Mountain National Park, circa 0.8 miles southeast Purchase Knob ATBI House along gravel drive, 22-VI-2006, C. Bartlett and A. Gonzon (1♂, UDCC); Mecklenburg Co., Charlotte 4-6-VIII-1969 J. Cornell (1♂, UDCC); Swain Co., Great Smoky Mountains National Park, Clingman's Dome Road circa 2 miles from US 441, 20-VI-2006 C. Bartlett & A. Gonzon (1♂, 2♀, UDCC); same, 10-VI-2005 L. Donovall (1♀, UDCC); NORTH DAKOTA: Richland Co., 11.5 miles south Wahpeton, 15-VIII-1973 G. Hevel (2♂, 1♀, UDCC); Wake Co., Raleigh, Centennial Campus, 17-VI-1994, C. Bartlett (1♀, UDCC); Raleigh, Schenck Forest, 16-VII-1993 C. Bartlett (1♂, UDCC); OHIO: Wayne Co., Izaak Walton For., c. 10 mi. W. Wooster, 17-VIII-1990 (2♂, 5♀, SWWC); PENNSYLVANIA: Chester Co., Avondale, Stroud Water Research Center, 9-IX-2005 L. Donovall (1♀, UDCC); Oxford, Locust Street, 3-X-1999 R. Synder (1♀, UDCC); TENNESSEE: Blount Co., near Townsend, Great Smoky Mountains National park, Cades Cove, Wet Bottom Trail, 8-VII-2002 C. Bartlett et al. (1♀, UDCC); Sevier Co., Great Smoky Mountains National Park, Twin Creeks ATBI Plot, 27-IX-8-X-2001 I. Stocks (1♀, UDCC); same, 26-IX-12-X-2000 Parker, Stocks, Petersen (1♀, UDCC); TEXAS: Dallas Co., Dallas, 5-XII-1945, coll. R. H. Beamer (1♂, SWWC). Victoria Co., Coleto Creek Park campground lots, 30-VII-2003 A. Short (1♀, UDCC); VERMONT: Chittenden Co., Jehrico, Sunnyview Drive, 22-25-VIII-1997 C. Bartlett (1♂, UDCC); same, 26-27-IV-2001 (1♀, UDCC); same, 26-27-V-2001 (3♀, UDCC).
DISCUSSION
The compiled species list suggests that Florida has the highest diversity of delphacids in the conterminous United States with 128 species recorded so far, including the 3 new species described here. In comparison, compiled state delphacid records from Wilson & McPherson (1980a) and more recent sources provide the highest number of state records from North Carolina (77), Illinois (75), New York (66), Mississippi (59), Connecticut (55), Georgia (53), Texas (52), Kansas (49), Colorado (46) and California (45); but this reveals more about the distribution of entomologists studying Auchenorrhyncha than it does about the distribution of planthoppers. Given that planthoppers (Fulgoroidea) generally are more diverse in lower latitudes, and about 2/3 of the 935 planthopper species north of Mexico are western (unpublished data), Texas and California might be expected to have the highest delphacid totals because of their relative size and their location in the West. The lower numbers reported suggest inadequate survey for delphacids. Four states have fewer than 10 delphacid species records (North Dakota, Rhode Island, Vermont, and West Virginia). States in the southwestern US (especially Arizona and New Mexico) certainly must have a much richer delphacid fauna than is currently reported, although possibly not as diverse as Florida.
Several of the new records are Neotropical species that have been recorded in southern Florida (e.g., Chionomus balboae, C. havanae, Delphacodes vaccina, Euides guaduae, Tagosodes approximatus, T. cubanus, and T. orizicolus). It is not clear whether such species are vagrants or established, but members of the genera Chionomus, Euides, and Tagosodes are common in light trap samples from the Neotropics, and these taxa potentially are long-distance migrants that may be expected as a regular feature of the fauna of Florida. More northern records of some taxa, particularly members of the genera Tagosodes, Sogatella, and Nilaparvata (see Bartlett 2007) probably are migrants rather than established populations.
The new species Muellerianella meadi described here doubles the number of known Muellerianella species in the New World, and expands known Muellerianella habitat to reflect a more widespread tropical distribution.
Meristopsis appears to be a tropical genus based on our current specimen records from southern Florida, Belize, and Guatemala. The observed specimens were nearly all collected at lights, providing no information regarding their host or habitat preferences. The new species appear to be relatively rare in collections. This underrepresentation may be due to small size, cryptic habits, and appearance that may be unremarkable to non-specialists. Additional species are very likely to be found, particularly in Central America, whose delphacid fauna remains poorly investigated.
ACKNOWLEDGMENTS
We are indebted to Kimberley Shropshire (University of Delaware) for assistance with photography. We are indebted to Dr. Susan Halbert and Kurt Ahlmark (Florida Collection of Arthropods, Florida Department of Plant Industry, Gainesville) for compiling Florida specimen and host records. We thank Susan Halbert, Mark Rothschild (Maryland Department of Agriculture, retired) and 3 anonymous reviewers for helpful comments on the manuscript. This research was supported by the USDA Agriculture and Food Research Initiative Competitive Grants Program Grant No. 2009-5560505006 from the National Institute of Food and Agriculture and Hatch Project W-2185 Biological Control in Pest Management Systems of Plants, with additional support from the University of Delaware Department of Entomology and Wildlife Ecology.