Lasioglossum (Sphecodogastra) truncatum ( Robertson 1901 )

Lasioglossum (Sphecodogastra) truncatum ( Robertson 1901) View in CoL

( Figs. 5Q View FIGURE 5 , 43H View FIGURE 43 , 44H View FIGURE 44 , 45I View FIGURE 45 , 46I View FIGURE 46 , 71 View FIGURE 71 , 72 View FIGURE 72 , 76F View FIGURE 76 , 79B View FIGURE 79 , 80B View FIGURE 80 , 86B View FIGURE 86 )

Halictus truncatus Robertson 1901, p. 230

Lectotype. ♀ USA, Illinois, Macoupin Co., Carlinville , 15.vi.1887 (C. A. Robertson) [ INHS: 5076] designated by W. E. LaBerge in Webb 1980. Examined by JG 2011

Halictus fulgidus Crawford 1902, p. 235 (syn. Crawford 1907b)

Syntype. ♀ USA, Nebraska, Lancaster Co., Lincoln , iv [ NMNH]

Evylaeus truncatus (in Mitchell 1960 redescription, key ♀, ♂ misdet. of L. oenotherae View in CoL ; Knerer & Atwood 1962 description ♂; Hurd 1979: catalogue; Moure & Hurd 1987: catalogue)

Halictus (Evylaeus) truncatus (in Viereck 1916: catalogue)

Lasioglossum (Evylaeus) truncatum View in CoL (in Michener 1951: catalogue; Krombein 1967: catalogue)

Diagnosis. Female L. truncatum can be recognised by the combination of head wide (L/W ratio = 0.88–0.91) ( Fig. 43H View FIGURE 43 ); metapostnotum coarsely rugose ( Fig. 79B View FIGURE 79 ); and T2 apical impressed area impunctate ( Fig. 80B View FIGURE 80 ). They are most similar to L. cinctipes , but L. truncatum differs in having the ocellocular area polished and distinctly punctate; pronotal dorsolateral angle orthogonal; lateral propodeal carinae subparallel; inner metatibial spur pectinate ( Fig. 5Q View FIGURE 5 ); and T2 apical impressed area impunctate.

Male L. truncatum can be recognised by the combination of clypeus strongly protruding below suborbital tangent ( Fig. 44H View FIGURE 44 ); mesoscutum polished due to lack of microsculpture; T2 apical impressed area sparsely punctate ( Fig. 86B View FIGURE 86 ); metasomal sterna nearly bare, with only very short hairs (<0.5 OD) (as in Fig. 85A View FIGURE 85 ); and retrorse lobe present ( Fig. 46H View FIGURE 46 ). Lasioglossum cinctipes is most similar but differs in head shape, the clypeus barely protruding below suborbital line ( Fig. 44A View FIGURE 44 ); T2 apical impressed area densely punctate ( Fig. 86A View FIGURE 86 ); and retrorse lobe absent ( Fig. 46A View FIGURE 46 ). In the east, the long gonostylus with long plumose setae of the gonostylus ( Fig. 45I View FIGURE 45 ) separates L. truncatum from all others.

Redescription. FEMALE. Length 6.8–9.0 mm. Head length 1.85–2.20 mm. Head width 2.04–2.50 mm. Wing length 5.7–6.8 mm. (n=10)

Colour. Head and mesosoma black. Antenna black, except ventral surface of flagellum brown. Tegula dark reddish brown. Legs dark brown, except medio- and distitarsi reddish brown. Wing membrane hyaline, faintly dusky. Pterostigma testaceous. Metasomal terga black-brown, apical margins pale brown-testaceous.

Structure. Head very wide (L/W ratio = 0.88–0.91). Clypeus 1/2 below suborbital line. Eyes convergent below (UOD:LOD = 1.04–1.14). Gena subequal to eye width. Ocelli normal. Pronotum smoothly rounded. Protibial spur with apical serrations as long as width of malus. Inner metatibial spur pectinate, teeth 3–4, basal teeth longer than width of rachis. Propodeal lateral carinae subparallel, reaching dorsal margin, oblique carina high, separating dorsolateral slope from posterior surface.

Surface sculpture. Supraclypeal area weakly polished, punctures sparse (i=1–2.5d). Gena lineolate, postgena smoother. Mesoscutum polished, weakly imbricate anteromedially; punctures dense laterally (i≤d), well-spaced between parapsidal lines (i=1–2d). Mesepisternum rugose, rugulose ventrally. Metapostnotum coarsely rugose. Propodeum imbricate-tessellate. Metasomal terga polished; punctures dense basally, very sparse apically, T2 apical impressed area broadly impunctate medially.

Pubescence. Head and mesosoma with sparse plumose hairs. Metafemoral scopa with dense plumose hairs. Metasomal terga with relatively sparse, medially-interrupted apical fimbriae. T1 with sparse, erect plumose hairs. T2–T4 with dense basal bands of tomentum, sometimes medially (or entirely on T4) obscured by preceding segment.

MALE. Length 5.9–8.8 mm. Head length 1.55–2.11 mm. Head width 1.63–2.16 mm. Wing length 4.8–6.4 mm. (n=3).

Structure. Head round (L/W ratio = 0.95–1.01). Mandible short, reaching opposing clypeal angle. Flagellomeres, except F1 elongate, F2 longer than F1 and pedicel combined. Eyes strongly convergent below (UOD:LOD = 1.38–1.52). Gena narrower than eye. Pronotum smoothly rounded. Propodeal lateral carina reaching dorsolateral slope, contiguous with strong oblique carina.

Colour. Head and mesosoma black. Clypeus yellow apical half. Mandible brown. Labrum yellow. Antenna black, except ventral surface of flagellum brown. Legs dark brown, except tarsi, bases and apices of tibiae yellow, anterior surface of protibia yellow-testaceous. Wing membrane hyaline. Pterostigma orange-brown. Metasomal terga dark brown, pale brown apically.

Surface sculpture. Supraclypeal area imbricate, punctures dense (i≤d). Gena lineolate. Mesoscutum polished, reticulate anterolaterally; punctures dense laterally (i≤d), well-separated between parapsidal lines (i=1–2d). Mesepisternum rugose. Metapostnotum carinate-rugose. Propodeum rugose. Metasomal terga polished; punctures deep, close basally. T1–T4 apical impressed areas with sparse punctures, T5–T6 impunctate apically.

Pubescence. Head and mesosoma with sparse plumose hairs. Face below eye emargination with dense tomentum, clypeus bare on distal half. Propodeum largely bare, with scattered plumose hairs. Metasomal terga nearly bare, without apical fimbriae. T2–T4 with thick, basolateral patch of tomentum. Metasomal sterna nearly bare, with sparse, short, simple and plumose hairs (≤1 OD).

Terminalia . As shown in Figs. 45I View FIGURE 45 , 46I View FIGURE 46 . Gonostylus long, with elongate, plumose setae. Retrorse lobe long, broad, attenuated apically.

Taxonomic notes. Mitchell (1960) incorrectly associated the male of L. truncatum with L. cinctipes . Knerer discovered the true male of L. truncatum ( Mitchell 1962; Knerer & Atwood 1964). Although L. truncatum is superficially similar to L. cinctipes , the structure of the male genital capsule suggests and molecular phylogenetic study, suggest they are not closely related. Western North American species, such as L. cooleyi ( Crawford 1906c) and L. pullilabre ( Vachal 1904) , belong to the same species group as L. truncatum , sharing an elongate gonostylus with long setae.

Biology. Lasioglossum truncatum is polylectic ( Moure & Hurd 1987). There are no published records of its nesting biology or social level, but it is believed to be a eusocial ground-nester. Examination of specimen records of L. truncatum in the northeastern USA suggests that this species may have become less common in recent decades ( Bartomeus et al. 2013). Nevertheless, the species is still found regularly in recent collections (e. g. Gibbs 2009b; Donovall et al. 2010; Park et al. 2010).

DNA barcodes. Two individuals were sampled (maximum intraspecific p-distance: 0%). The minimum interspecific p-distance separating L. truncatum from other species herein is 9.5%. Seven fixed nucleotide substitutions distinguish L. truncatum from other species included herein: positions 87(T), 127(C), 144(C). 352(G), 399(T), 453(C), and 510(G) (see Table 2).

Range. Fig. 73 View FIGURE 73 .

Material examined. 525 (424 females, 101 males). Deposited in AMNH, ANSP, BBSL, CMNH, CNC, EMEC, MCPM, MCZ, MSUC, PMAE , ROMent, UCMC, and UCRC.

CANADA. ONTARIO: Georgian Bay; Hastings Co.: Marmora; Huron Co.: Kinburn; Lanark Co.: Franktown; Perth; Rideau Ferry; Smith Falls; Leeds-Grenville United Co.; Athens; Chaffeys Lock; Opinicon; Spencerville, Limerick For.; Muskoka Dist.: Dorset; Muskoka; Six Mile Lake, Port Severn, 6 mi. N; National Capital Reg.: Constance Bay; Ottawa; Northumberland Co.: Brighton; QUEBEC: Montérégie Reg.: Knowlton; Mt. St. Hilaire; Outaouais Reg.: Beech Grove; Gatineau Pk., Harrington Lk.; Kirk`s Ferry; Tenaga.

USA. CONNECTICUT: Fairfield Co.: Stamford; Litchfield Co.: Colebrook; Westbury; New Haven Co.: New Haven; ILLINOIS: Cook Co.: Edgebrook; Macoupin Co.: Carlinville; Perry Co.: Pyatts; Winnebago Co.: Rockford; KANSAS: Douglas Co.: Lawrence; Pleasant Grove, 3 mi. SW; MAINE: Piscataquis Co: Greenville; MASSACHUSETTS: Hampden Co.: Chester; Middlesex Co.: Auburndale; Framingham; Holliston; West Newton; Norfolk Co.: Blue Hills; Milton; Needham; Sharon; Suffolk Co.: Forest Hills; Worcester Co.: Petersham; MICHIGAN: Lake Co.; MINNESOTA: Fillmore Co.: Fountain, 3 mi. N; Pine Co.: Lower Tamarack R.; Wabasha Co.: Wabasha, 3 mi. W; MISSOURI: Greene Co.: Willard; Howell Co.: Willow Springs; St. Louis Co.: Tyson Res. Sta., nr. Eureka; NEBRASKA: Cass Co.: South Bend; Lancaster Co.: Lincoln; Malcolm; NEW HAMPSHIRE: Belknap Co.: Meredith; Meredith Ctr.; Cheshire Co.: Nelson; Coos Co.: Gorham; Lancaster; NEW YORK: Albany Co.: Rensselaerville, Huyck Preserve; Broome Co.; Cattaraugus Co.: Cattaraugus; Cayuga Co. : Spring Lake; Madison Co.; Orange Co.; Otsego Co.; Putnam Co.: Garrison; Seneca Co. : Aurora , 2 mi. N; Suffolk Co.: Cold Spring Harbor; Tompkins Co.: Enfield, Teeter Rd.; Freeville; Ithaca; Ithaca, Cornell U.; Ithaca, Van Natta’s Dam; Westchester Co.; NORTH CAROLINA: Alleghany Co.: Scenic Hwy.; Avery Co.: Grandfather Mt.; Burke Co.: Linville; Haywood Co.: Cruso; Hyde Co.; Johnston Co.; Macon Co.: Highlands; Wayah Bald; McDowell Co.: Blue Ridge Pkwy.; Marion; Moore Co.: Southern Pines; Swain Co.: Bryson City; Wake Co.: Raleigh; Washington Co.: Pettigrew S.P.; Wilkes Co.: Moravian Falls; NORTH DAKOTA: Richland Co.: Walcott, 14 mi. SW; OHIO: Athens Co.: New Marshfield; PENNSYLVANIA: Allegheny Co.: Pittsburgh; Beaver Co.: New Galilee; Lehigh Co.: Lehigh Gap; Montgomery Co.: Edge Hill; Somerset Co.; Tioga Co. : Mansfield; Westmoreland Co.; Jeanette; Pleasant Grove, 2 mi. S; Powdermill N.R.; SOUTH CAROLINA: Oconee Co.: Mountain Rest; SOUTH DAKOTA: Lawrence Co.: Fs Rd. 131.1; VERMONT: Caledonia Co. : Burke Mt. S.P.; Bennington Co.; Windham Co.: Westminster; Windsor Co.; VIRGINIA: Shenadoah N.P.; Carroll Co.: Laurel Fork; Fairfax Co.: Dunn Loring; WEST VIRGINIA: Greenbrier Co.: Alvon; Hardy Co.: Lost River S.P.; Pendleton Co.: Spruce Knob; WISCONSIN: Burnett Co.: Fish Trap; Randal; Yellow River; Grant Co.: Boscobel; Wyalusing; Pierce Co.: Prescott; St. Croix Co.: North Hudson; Vernon Co.: Genoa.

DISCUSSION

The new classification proposed herein for the weak-veined Lasioglossum (or Hemihalictus series) is novel and unlikely to be accepted by some authors, including experts on halictid taxonomy who explicitly reject phylogenetic (cladistic) classifications (e. g. Ebmer 2002). The large number of subgeneric changes, including many taxa of importance for research in the fields of sociobiology and social evolution (e. g. L. (Sphecodogastra) albipes ( Fabricius 1781)) , is bound to cause consternation among many biologists working with bees. Nevertheless, we consider the logic and consistency of applying a cladistic classification far superior to other modes of classification (Hennig 1965, 1975) and arguments in favour of naming paraphyletic groups to be largely fallacious (reviewed in Schmidt-Lebuhn 2012). If the arguments for a cladistic classification are accepted, then the subgeneric limits of many Lasioglossum subgenera proposed by previous authors should be rejected on the grounds of demonstrated paraphyly and polyphyly ( Danforth et al. 2003; Gibbs et al. 2012a, b; Fig. 2 View FIGURE 2 ). It is unfortunate that the application to set aside the priority of Sphecodogastra and Hemihalictus was rejected ( Gibbs et al. 2009; ICZN 2011) since this decision has resulted in many more name changes than would have otherwise been required.

The decision to recognise L. ( Hemihalictus ) and L. (Dialictus) based primarily on colour was made expressly for retaining a consistent subgenus for as many species as possible. Some known exceptions to this colour-based classification are as follows. Lasioglossum (Sudila) belongs to the L. ( Hemihalictus ) clade ( Danforth et al. 2003; Gibbs et al. 2012b) but includes some weakly metallic species ( Sakagami et al. 1996). The definition of L. ( Hemihalictus ) must therefore expand to include the traits used to recognise L. ( Sudila ), including the presence of a mesepisternal tubercle and pectinate male inner metatibial spurs. Pectinate inner metatibial spurs are also present in L. (Mediocralictus), considered by previous authors to be a synonym of L. (Dialictus) s. l. (e. g. Michener 2007; Gibbs 2011), but included here in L. ( Hemihalictus ), which highlights the arbitrary nature of maintaining L. ( Sudila ) as distinct. One of the notable features of L. ( Sudila ) is the large headed males, with sabre-like mandibles. Although less extreme, this state is also present in other L. ( Hemihalictus ) species, including a number of Nearctic species such as L. lustrans , the fedorense species-group, and the pectinatum species-group ( Figs. 6 View FIGURE 6 , 84 View FIGURE 84 ), as well as the Old World sexstrigatum species-group ( Pesenko 2007a). The genus-group Afrodialictus Pauly (1984) also contains both dark and metallic forms. This group could be recognised separately until its phylogenetic placement is determined with certainty, but it is likely more closely related to L. (Dialictus) than L. ( Hemihalictus ) (JG, unpublished results). There are also some large, metallic, Neotropical species, such as L. figueresi , historically placed into L. (Dialictus) (e. g. Wcislo 1990; Engel et al. 2007), that are sufficiently different from either L. ( Hemihalictus ) or L. (Dialictus) to warrant separate status ( Danforth et al. 2003; Gibbs et al. 2012b). Some of these metallic Neotropical species are structurally similar to L. ( Eickwortia ) McGinley (1999), which lacks metallic colouration, and may be closely related. There are other Neotropical species, such as L. gattaca Danforth and Wcislo (1999) and L. hartmanni Danforth and Wcislo (1999) , that fall within the metallic L. (Dialictus) clade ( Danforth et al. 2003; Gibbs et al. 2012b) but only have distinct metallic colouration in the male ( Danforth & Wcislo 1999; JG pers. obs.). In the most robust phylogeny of the genus published to date, Gibbs et al. (2012b) recovered L. gattaca as sister to the main clade of metallic Nearctic L. (Dialictus). This clade, including L. gattaca , shares an appressed patch of hairs on metasomal tergum 1 of females, which is apparently a synapomorphy uniting most L. (Dialictus) ( Gibbs 2009b; JG pers. obs.), albeit secondarily lost in a small number of species (e. g. L. microlepoides ( Ellis 1914)) .

The diagnosis of the subgenus L. ( Sphecodogastra ) must now include the subgeneric characters of “carinate Evylaeus ” (see Ebmer 1995). This is unfortunate because L. ( Sphecodogastra ), as originally defined, lack a propodeal carina. However, some species of “carinate Evylaeus ”, such as some members of the L. pauxillum species-group, also have reduced propodeal carinae ( Pesenko 2007a) so it is not new for subgeneric diagnoses to include both states. There are some Palaearctic species of “carinate Evylaeus ” which are also crepuscular, including L. pallidum ( Radoszkowski 1888) , which has enlarged ocelli ( Ebmer 2008). The distinction between L. ( Sphecodogastra ) and a paraphyletic L. ( Evylaeus ) is thus based mainly on the form of the metatibial scopa, which in the Onagraceae specialized L. ( Sphecodogastra ) s. s. is reduced to a single row of simple, apically hooked hairs. A reduced scopa is a derived trait associated with specialization on Onagraceae , and similar modifications can be seen in some other bees that specialize on these plants (Cockerell 1937; LaBerge & Thorpe 2008; Ebmer 2008). Some authors have placed more emphasis on the ocelli when treating L. texanum and L. noctivaga as a distinct subgenus from the other Onagraceae specialists, such as L. oenotherae and L. lusorium , which have been included in L. ( Evylaeus ) ( Hurd 1979; Moure & Hurd 1987); but increased ocellar size is to be expected in more nocturnally active species.

Adjustments to the classification proposed herein will be required as additional phylogenetic information becomes available. A solution to retain many species in L. ( Evylaeus ) is not readily available because L. ( Sphecodogastra ) is nested within the so-called “carinate Evylaeus ” ( Danforth et al. 2003; Gibbs et al. 2012a, b). Since the type species of L. ( Evylaeus ) is L. cinctipes , which is not nested within the L. ( Sphecodogastra ) clade ( Danforth et al. 2003; Gibbs et al. 2012b), retention of this subgenus in a restricted sense is required by the evidence. Should more robust phylogenies place this group as a basal branch of L. ( Sphecodogastra ), then synonymising the two names would be become an option. There is no clear morphological basis for diagnosing L. ( Evylaeus ) separately from L. ( Sphecodogastra ) s. l., when considered globally. Lasioglossum cinctipes is morphologically similar to some species known to be nested within L. ( Sphecodogastra ) s. l., such as the laticeps group ( Pesenko 2007a). Future phylogenetic inferences of Lasioglossum , based upon combined molecular and morphological data, with improved taxon sampling, will hopefully shed light on the relationships of these important taxa and characters useful for their diagnosis.

Alternative strategies to the one above for recognition of monophyletic groups would be to recognise fewer or many more subgenera. All subgenera of weak-veined Lasioglossum could be lumped into one massive subgenus, which would be known as L. ( Hemihalictus ). This would have the advantage of easy diagnosibility but would obscure much of the phylogenetic information contained in a more finely divided classification. Recognition of species-groups within this large genus, however, would partially alleviate this difficulty. Lasioglossum (Hemihalictus) could also be used to include all metallic species, thus being nearly identical to the L. (Dialictus) s. l. used by some authors (e. g. Michener 2007). A disadvantage of both of these classifications would be the increased number of nomenclatural changes, since hundreds more species would undergo subgeneric changes than with the classification proposed above.

Another option would be to recognise many more subgenera, following Warncke (1975) and Pesenko (2007a). An advantage of this strategy would be that L. ( Sphecodogastra ) and L. ( Hemihalictus ) could remain narrowly delimited. However, the monophyly of many of these nominal groups is not well-established and the number of taxa that would change subgenera from standard usage would not be much less than suggested herein. Until a comprehensive phylogeny of Lasioglossum is completed, correct subgeneric placement of many species would be more difficult. A more finely divided classification may be desirable and ultimately may prove necessary, but we believe it would best be applied once more phylogenetic information is available.

A global phylogenetic study of Lasioglossum s. l. is currently in progress that will include a number of problematic taxa (e. g. L. ( Afrodialictus )) hitherto not included in any robust phylogeny. The goal of this project is to help resolve the outstanding taxonomic and nomenclatural problems within Lasioglossum . Once completed, a more stable classification with more carefully circumscribed subgenera may be possible; however, based on available phylogenetic results and unpublished data it is unlikely to prevent the broad application of L. ( Sphecodogastra ) and L. ( Hemihalictus ) to species historically placed in other subgenera. It is expected that the classification for the species treated above, some of which have been included in previous phylogenetic studies, will remain largely unaffected.

KEYS TO SPECIES OF BLACK HEMIHALICTUS SERIES (WEAK-VEINED LASIOGLOSSUM View in CoL ) IN NORTH AMERICA, EAST OF THE MISSISSIPPI RIVER

Key to sexes

Flagellomeres 10; metasomal terga 6; T5 with distinct prepygidial area; scopa present............................... females Flagellomeres 11; metasomal terga 7; T5 without distinct prepygidial area; scopa absent............................... males

Key to females

1. Metafemoral scopa composed of numerous plumose hairs ( Fig. 74A View FIGURE 74 ); metatibia with ventral hairs not much longer than distal width of tibia ( Fig. 74A View FIGURE 74 ); ocellar diameter shorter than ocellocular distance..................................... 2

- Metafemoral scopa composed of a single row of hairs ( Fig. 74B View FIGURE 74 ); metatibia with ventral hairs much longer (about 2X) than distal width of tibia ( Fig. 74B View FIGURE 74 ); ocellar diameter variable, shorter or longer than ocellocular distance ( Fig. 43H View FIGURE 43 ) ( Sphecodogastra sensu McGinley [2003] ; oligoleges on Onagraceae View in CoL )................................................. 18

2. Mesoscutum rugose anteriorly, reticulate-punctate between parapsidal lines; lateral and posterior surfaces of propodeum covered with dense appressed hairs, obscuring integument and sharply contrasting against bare metapostnotum ( Fig. 75A View FIGURE 75 )........................................................................................ L. (H.) nelumbonis View in CoL

- Mesoscutum punctate anteriorly, punctate with clear interspaces between parapsidal lines; lateral and posterior surfaces of propodeum with sparse erect hairs, not obscuring integument or sharply contrasting against metapostnotum ( Fig. 75B, 75C View FIGURE 75 )................................................................................................... 3

3. Mesepisternum entirely coarsely rugose, including region adjacent to mesocoxa ( Fig. 76C View FIGURE 76 )............ L. (H.) pectorale View in CoL

- Mesepisternum rugulose or punctate, at least in part, never coarsely rugose in region adjacent to mesocoxa ( Figs. 76A, 76B, 76D–F View FIGURE 76 ) (if mesepisternum moderately rugose then head wide: L/W ratio = 0.83–0.93)............................ 4

4. Pronotum with sharply angled dorsolateral ridge (metasoma colour variable; reddish orange to black-brown).......... 5

- Pronotum smoothly rounded, without sharply angled lateral ridge (metasoma colour black-brown)................... 8

5. Metatibial inner spur with approximately 15–20 teeth, teeth not much longer than wide ( Fig. 5H View FIGURE 5 ); supraclypeal area sparsely punctate (i=1–2d), punctures similar in size to clypeal punctures ( Fig. 4H View FIGURE 4 )......................... L. (H.) pectinatum View in CoL

- Metatibial inner spur with 4 to 5 teeth, at least basal tooth much longer than wide ( Figs. 5B, 5J, 5K View FIGURE 5 ); supraclypeal area densely punctate (i<d), punctures much smaller in size than clypeal punctures ( Figs. 4B, 4J, 4K View FIGURE 4 ).................... 6

6. Metapostnotum coarsely rugose ( Fig. 77A View FIGURE 77 ); mesoscutum polished, shiny............................ L. (H.) sopinci View in CoL

- Metapostnotum rugulose, posterior margin imbricate ( Fig. 77B, 77C View FIGURE 77 ); mesoscutum dull........................... 7

7. Hypoepimeral area punctate ( Fig. 78A View FIGURE 78 ); dorsolateral ridge of pronotum with carina ending posterior of oblique sulcus............................................................................................. L. (H.) swenki View in CoL

- Hypoepimeral area impunctate ( Fig. 78B View FIGURE 78 ); dorsolateral ridge of pronotum with carina extending anterior of oblique sulcus....................................................................................... L. (H.) fedorense View in CoL

8 (4). Mesepisternum punctate (as in Fig. 76B View FIGURE 76 ) (size small, length 4.8–6.6 mm; T2 and T3 with basolateral patches of tomentum)................................................................................................... 9

- Mesepisternum rugulose to rugose (as in Figs. 76A, 76C, 76F View FIGURE 76 ) (size and metasomal terga pubescence variable)....... 10

9. Head short (L/W ratio = 0.94–0.99) ( Fig. 4A View FIGURE 4 )................................................ L. (H.) birkmanni View in CoL

- Head long (L/W ratio = 1.02–1.09) ( Fig. 4F View FIGURE 4 )............................................. L. (H.) macoupinense View in CoL

10 (8). Metapostnotum coarsely rugose ( Figs. 79A, 79B View FIGURE 79 ); head wide (L/W ratio = 0.83–0.93) ( Figs. 43A, 43I View FIGURE 43 ).............. 11

- Metapostnotum rugulose ( Figs. 79 View FIGURE 79 C-79F, 82A-82C); head usually longer (L/W ratio> 0.92) ( Figs. 4C, 4E, 4F View FIGURE 4 , 43B, 43C, 43F, 43G View FIGURE 43 )........................................................................................ 12

11. T2 apical impressed area punctate; propodeal lateral carinae divergent dorsally; ocellocular area finely rugulose, punctures indistinct; inner metatibial spur denticulate, teeth shorter than width of rachis ( Fig. 5M View FIGURE 5 ); pronotum dorsolateral angle obtuse....................................................................................... L. (E.) cinctipes View in CoL

- T2 apical impressed area impunctate; propodeal lateral carinae subparallel dorsally; ocellocular area polished, punctures distinct; inner metatibial spur pectinate, teeth longer than width of rachis ( Fig. 5Q View FIGURE 5 ); pronotum dorsolateral angle orthogonal........................................................................................ L. (S.) truncatum View in CoL

12 (10). Propodeum “carinate”: lateral carina reaching dorsal surface, lateral and posterior surfaces completely separated by carina ( Figs. 75B View FIGURE 75 , 79 View FIGURE 79 C-79F)............................................................................... 13

- Propodeum “carinaless”: lateral carina reaching about halfway to dorsal surface, lateral and posterior surfaces not separated by carina dorsally ( Figs. 75C View FIGURE 75 , 82 View FIGURE 82 )..................................................................... 16

13. Head long (L/W ratio> 1.00) ( Figs. 43F, 43G View FIGURE 43 ); inner metatibial spur with basal teeth longer than width of rachis ( Figs. 5O, 5P View FIGURE 5 ); T1 dull due to fine microsculpture................................................................. 14

- Head shorter (L/W ratio <1.00) ( Figs. 43B, 43C View FIGURE 43 ); inner metatibial spur with basal teeth shorter than width of rachis ( Figs. 5M, 5N View FIGURE 5 )); T1 shiny due to lack of microsculpture........................................................ 15

14. Metasomal terga usually with comparatively dense apicolateral fimbriae ( Fig. 81C View FIGURE 81 ); head long (L/W ratio = 1.00–1.03); inner metatibial spur with basal teeth much longer than width of rachis (body size usually larger: 6.5–7 mm) … L. (S.) quebecense View in CoL

- Metasomal terga with sparse apicolateral fimbriae ( Fig. 81D View FIGURE 81 ); head longer (L/W ratio> 1.04); inner metatibial spur with basal teeth only slightly longer than width of rachis (body size usually smaller: 5.8–6.5 mm)............. L. (S.) seillean

15 (13). Head width subequal to length (L/W ratio = 0.98–1.00) ( Fig. 43B View FIGURE 43 ); propodeum with oblique carina very fine, obscure ( Fig. 79C View FIGURE 79 ).................................................................................... L. (S.) boreale View in CoL

- Head width greater than length (L/W ratio = 0.93–0.96) ( Fig. 43C View FIGURE 43 ); propodeum with oblique carina coarse, distinct ( Fig. 79D View FIGURE 79 ).............................................................................. L. (S.) comagenense View in CoL

16 (12). Inner metatibial spur serrate ( Fig. 5E View FIGURE 5 ); T1 with subappressed hairs ( Fig. 82A View FIGURE 82 ) (Submarginal cells usually two; Fig. 1B View FIGURE 1 )........................................................................................... L. (H.) lustrans View in CoL

- Inner metatibial spur pectinate ( Figs. 5C, 5D View FIGURE 5 ); T1 without subappressed hairs ( Figs. 82B, 82C View FIGURE 82 ) (Submarginal cells three; Fig. 1A View FIGURE 1 )............................................................................................. 17

17. Metapostnotum with rugae not reaching posterior margin, posterior margin smoothly rounded onto posterior propodeal surface ( Fig. 82B View FIGURE 82 )............................................................................ L. (H.) foxii View in CoL

- Metapostnotum with rugae extending to posterior margin, posterior margin sharply edged ( Fig. 82C View FIGURE 82 )... L. (H.) inconditum View in CoL

18 (1). Metasomal terga reddish to pale orange ( Fig. 50 View FIGURE 50 ); ocellar diameter greater than ocellocular distance ( Fig. 43H View FIGURE 43 ).................................................................................................. L. (S.) texanum View in CoL

- Metasomal terga black-brown to black; ocellar diameter less than ocellocular distance ( Figs. 43D, 43E View FIGURE 43 )............. 19

19. Metapostnotum rugose ( Fig. 83A View FIGURE 83 ); propodeum “carinate”: lateral carina coarse, reaching dorsal margin ( Fig. 83A View FIGURE 83 )............................................................................................. L. (S.) oenotherae View in CoL

- Metapostnotum rugulose ( Fig. 83B View FIGURE 83 ); propodeum “acarinate”: lateral carina fine, not reaching dorsal margin ( Fig. 83B View FIGURE 83 ) (Midwestern species, only known from one individual east of Mississippi River).......................... L. (S.) lusorium View in CoL

Key to males (It is recommended that males have the terminalia extruded so that the gonostylus and retrorse lobe are visible).

1. Mandible elongate, extending well beyond opposing clypeal angle, nearly reaching opposing mandibular base ( Figs. 84A, 84B View FIGURE 84 ); pronotal dorsolateral ridge sharply angled at least in part............................................... 2

- Mandible shorter, not reaching opposing clypeal angle or only slightly extending beyond it ( Fig. 84C View FIGURE 84 ); pronotal dorsolateral ridge smoothly rounded.............................................................................. 6

2. Clypeus entirely black (Figa. 6E, 84B); submarginal cells usually two ( Fig. 1B View FIGURE 1 )...................... L. (H.) lustrans View in CoL

- Clypeus yellow, in part ( Figs. 6B, 6H, 6J, 6K View FIGURE 6 , 84A View FIGURE 84 ); submarginal cells three ( Fig. 1A View FIGURE 1 )............................. 3

3. Clypeus black-brown with yellow distal band ( Fig. 6H View FIGURE 6 ); mesoscutal punctation relatively sparse, interspaces laterad to parapsidal line approximately 2–3 puncture diameters; metasomal sterna with long hairs (1.5–2.5 OD)... L. (H.) pectinatum View in CoL

- Clypeus yellow with brown basolateral patches ( Figs. 6B, 6J, 6K View FIGURE 6 , 84A View FIGURE 84 ); mesoscutal punctation relatively dense, interspaces laterad to parapsidal line approximately 1 puncture diameter; metasomal sterna with short hairs (1–1.5 OD)........... 4

4. Metapostnotum with coarse rugae, posterior margin sharply angled (as in Fig. 77A View FIGURE 77 ) (Eastern)............ L. (H.) sopinci View in CoL

- Metapostnotum with fine rugae, posterior margin smoothly rounded (as in Figs. 77B, 77C View FIGURE 77 ) (Midwestern)............. 5

5. Gena width subequal to eye, widest point below midlength of eye, towards mandible ( Fig. 16 View FIGURE 16 ); mesepisternum mostly impunctate (as in Fig. 78B View FIGURE 78 )............................................................... L. (H.) fedorense View in CoL

- Gena narrower than eye, widest point near midlength of eye; mesepisternum finely punctate (as in Fig. 78A View FIGURE 78 ) L. (H.) swenki View in CoL

6 (1). Flagellomeres 2–10 short, length at most subequal to width; clypeus entirely black ( Fig. 6G, 6I View FIGURE 6 ) (mesepisternum coarsely rugose, Figs. 28 View FIGURE 28 , 34 View FIGURE 34 , 76A View FIGURE 76 )............................................................................ 7

- Flagellomeres 2–10 long, length usually 1.5 to 2 times width; clypeus yellow distally............................. 8

7. Mesoscutum rugose anteriorly; propodeum with sparse tomentum.............................. L. (H.) nelumbonis View in CoL

- Mesoscutum punctate anteriorly; propodeum with erect hairs only................................ L. (H.) pectorale View in CoL

8 (6). Metasomal sterna with short hairs (<2 OD) ( Fig. 85A View FIGURE 85 ), if longer (2—2.5 OD), then erect; S6 without medial, longitudinal elevation ( Fig. 85A View FIGURE 85 )................................................................................. 9

- Metasomal sterna with long (2–2.5 OD) posteriorly directed hairs ( Fig. 85B View FIGURE 85 ); S6 with medial, narrow, longitudinal elevation ( Fig. 85B View FIGURE 85 ) ( Sphecodogastra s. s.)..................................................................... 18

9. Mesepisternum smooth, with distinct punctures (as in Fig. 76B View FIGURE 76 )............................................. 10

- Mesepisternum rugulose to rugose, without distinct punctures (as in Figs. 76A, 76D View FIGURE 76 )............................ 11

10. Head shorter (L/W ratio = 0.95–1.00) ( Fig. 6A View FIGURE 6 ); supraclypeal area with close punctures (i≤d).......... L. (H.) birkmanni View in CoL

- Head long (L/W ratio = 1.06–1.09) ( Fig. 6F View FIGURE 6 ); supraclypeal area with sparse punctures (i=1–2d)..... L. (H.) macoupinense View in CoL

11(9). Metasomal sterna with relatively long erect hairs (1.5–2.5 OD); propodeum “carinaless” with posterior and lateral surfaces only separated ventrally by weak carina ( Figs. 82B, 82C View FIGURE 82 ); metabasitarsus usually brown, uncommonly yellowish ( Figs. 19 View FIGURE 19 , 22 View FIGURE 22 ) ............................................................................................. 12

- Metasomal sterna with relatively short erect hairs (≤ 1.5 OD) ( Fig. 85A View FIGURE 85 ); propodeum “carinate” with posterior and lateral surfaces completely separated by distinct carina ( Fig. 79 View FIGURE 79 ); metabasitarsus yellow (e. g. Figs. 48 View FIGURE 48 , 54 View FIGURE 54 ).................... 13

12. Metapostnotal rugae not reaching posterior margin ( Fig. 82B View FIGURE 82 )........................................ L. (H.) foxii View in CoL

- Metapostnotal rugae reaching posterior margin ( Fig. 82C View FIGURE 82 )..................................... L. (H.) inconditum View in CoL

13(11). Mesoscutum polished; head wide to round (L/W ratio =0.87–1.01) ( Figs. 44A, 44I View FIGURE 44 ).............................. 14

- Mesoscutum dull due to microsculpture; head usually longer (L/W ratio = 1.01–1.08) ( Figs. 44B, 44C, 44F, 44G View FIGURE 44 )..... 15

14. Head wider (L/W ratio = 0.87–0.93), clypeus only weakly protruding below suborbital tangent ( Fig. 44A View FIGURE 44 ); T2 apical impressed area with relatively dense punctation, similar to basal area of tergum ( Fig. 86A View FIGURE 86 ); gonostylus short, with short setae ( Fig. 45A View FIGURE 45 ); retrorse lobe absent ( Fig. 46A View FIGURE 46 ).................................................... L. (E.) cinctipes View in CoL

- Head longer (L/W ratio = 0.95–1.01), clypeus more strongly protruding below suborbital tangent ( Fig. 44I View FIGURE 44 ); T2 apical impressed area with irregular punctation, sparser than basal area of tergum ( Fig. 86B View FIGURE 86 ); gonostylus long, with long, plumose setae ( Fig. 45I View FIGURE 45 ); retrorse lobe present ( Fig. 46I View FIGURE 46 )............................................... L. (S.) truncatum View in CoL

15(13). Retrorse lobe strongly recurved at apex ( Fig. 87B View FIGURE 87 ); head usually shorter (L/W ratio = 1.01–1.04) ( Fig. 44C View FIGURE 44 ); S2 punctures fine, sparse (i=1–4d) ( Fig. 88A View FIGURE 88 )........................................................ L. (S.) comagenense View in CoL

- Retrorse lobe not recurved at apex ( Figs. 87A, 87C, 87D View FIGURE 87 ); head usually longer (L/W ratio = 1.04–1.10) ( Figs. 44B, 44F, 44G View FIGURE 44 ); S2 punctures variable ( Fig. 88 View FIGURE 88 ).................................................................. 16

16. Mesoscutum usually completely reticulate, lacking interspaces between punctures; retrorse lobe longer than gonostylus, apex strongly attenuated, narrow ( Fig. 87C View FIGURE 87 ); S2 punctures fine (as in Fig. 88A View FIGURE 88 )......................... L. (S.) quebecense View in CoL

- Mesoscutum medially punctate, with small but distinct interspaces between punctures; retrorse lobe either subequal in length to gonostylus ( Fig. 87A View FIGURE 87 ) or much longer but with rounded apex ( Fig. 87F View FIGURE 87 ); S2 punctures variable.................. 17

17. Retrorse lobe short, about as long as gonostylus ( Fig. 87A View FIGURE 87 ); metatibia basally with large yellow patch, longer than width of tibia; S2 punctures distinct, denser (i=1–1.5d) ( Fig. 88B View FIGURE 88 ).......................................... L. (S.) boreale View in CoL

- Retrorse lobe long, much longer than gonostylus ( Fig. 87D View FIGURE 87 ); metatibia basally brown or with small yellow spot, shorter than width of tibia; S2 punctures obscure, sparser (i = 1–5d) (as in Fig. 88A View FIGURE 88 ).............................. L. (S.) seillean

18 (8). Metasomal terga ferruginous/testaceous ( Fig. 51 View FIGURE 51 ); ocellar diameter greater than ocellocular distance ( Fig. 44H View FIGURE 44 )................................................................................................. L. (S.) texanum View in CoL

- Metasomal terga black-brown to black ( Figs. 60 View FIGURE 60 , 63 View FIGURE 63 ); ocellar diameter less than ocellocular distance................ 19

19. Metapostnotum rugose (as in Fig. 83A View FIGURE 83 ); propodeum “carinate”, with posterior and lateral surfaces completely separated by distinct carina......................................................................... L. (S.) oenotherae View in CoL

- Metapostnotum rugulose (as in Fig. 83B View FIGURE 83 ); propodeum “carinaless”, with posterior and lateral surfaces only separated ventrally by weak carina (Western species, only know from one individual east of Mississippi River)........ L. (S.) lusorium View in CoL

ACKNOWLEDGEMENTS

We would like to thank the following people for providing loans or gifts of material for study. Chris Dietrich and Dmitry Dmitriev (INHS) for facilitating the transfer of Evylaeus loan material to JG. The curators and collection managers of the many institutions listed above for loans of material. In particular, Brian Harris and Seán Brady (NMNH), Manuela Vizek (Naturhistorisches Museum Wien), and Jason Weintraub (ANSP) for arranging loans of type material. We thank Jack Neff (CTMI) and Mike Arduser (Missouri Department of Conservation) for providing specimens of L. fedorense . We are grateful to T’ai Roulston for providing specimens of L. pectinatum and for discussions with JG on the likely host-plant preferences of that species. Sam Droege ( United States Geological Survey) provided numerous specimens from across the eastern United States that were invaluable for DNA barcoding studies (retained at PCYU). Shannon Hedtke (Cornell University) assisted in collecting of L. pectinatum from Physalis plants in New York State.

We would also like to thank Ron McGinley for discussing revisionary studies of Evylaeus with JG and for encouraging this study.

We appreciate funding for travel from the Bradley Endowment at Cornell University (overseen by J. Liebherr, CUIC), which initiated this research and made examination of most material possible. DNA barcoding was supported through funding to the Canadian Barcode of Life Network from Genome Canada, NSERC, and other sponsors listed at www.BOLNET.ca.

JG was supported through funding from the Bradley Endowment and the Digital Bee Collections Network (NSF-BRI #0956388: J. S. Ascher (AMNH) PI, D. Yanega (UCRC), J. G. Rozen (AMNH), Co-PIs). Earlier research on these bees by LP was funded by the Natural Sciences and Engineering Research Council of Canada. Contributions by SD were made possible by funds from NSERC-CANPOLIN. This paper represents contribution #70 from the Canadian Pollination Initiative.

Images were taken using a Visionary Digital BK Plus imaging system using a Canon EOS 40D digital SLR camera housed at PCYU. This imaging system was purchased with funds from the Canadian Foundation for Innovation and the Ontario Research Fund through Canadensys.

We thank two reviewers, Doug Yanega and Sam Droege, and the associate editor, Claus Rasmussen, for comments which improved the accuracy and quality of the manuscript.

REFERENCES

Arduser, M. (2010) Bees (Hymenoptera: Apoidea) of the Kitty Todd Preserve, Lucas County, Ohio. The Great Lakes Entomologist, 43, 52–75.

Ascher, J. S & Pickering, J. (2012) Discover Life bee species guide and world checklist (Hymenoptera: Apoidea: Anthophila). Available from: http://www.discoverlife.org/mp/20q?guide=Apoidea_species (Accessed 19 March 2013)

Ashmead, W.H. (1899) Classification of the bees, or the superfamily Apoidea. Transactions of the American Entomological Society, 26, 49–100.

Bartomeus, I., Ascher, J.S., Gibbs, J., Danforth, B.N., Wagner, D.L., Hedtke, S. & Winfree, R. (2013) Historical changes in northeastern US bee pollinators related to shared ecological traits. Proceedings of the National Academy of Sciences, 110, 4656–4660.

http://dx.doi.org/10.1073/pnas.1218503110

Batra, S.W.T. (1966) The life cycle and behavior of the primitively social bee, Lasioglossum zephyrum (Halictidae). University of Kansas Science Bulletin, 46, 359–423.

Batra, S.W.T. (1990) Bionomics of Evylaeus comagenense (Knerer and Atwood) (Halictidae), a facultative polygynous, univoltine, boreal halictine bee. Proceedings of the Entomological Society of Washington, 92, 725–731.

Benoist, R. (1962) Viaggi di A. Giordani Soika nel Sahara. X. Hyménoptères Apidés recueilles au Hoggar par A. Giordani Soika. Bollettino del Museo Civico di Storia Naturale di Venezia, (1961), 14, 43–52.

Blüthgen, P. (1923) Beiträge zur Kenntnis der Bienengattung Halictus Latr. Archiv für Naturgeschichte. Abteilung A, 89 (5), 232–332.

Bohart, G.E. & Youssef, N.N. (1976) The biology and behaviour of Evylaeus galpinsiae Cockerell (Hymenoptera: Halictidae). Wasmann Journal of Biology, 34 (2), 185–234.

Brittain, W.H. (1933) Apple pollination studies in the Annapolis Valley, Nova Scotia. Canadian Department of Agriculture Bulletin, New Series, 162, 1–198.

Brothers, D.J. (1976) Modifications of the metapostnotum and origin of the “propodeal triangle” in Hymenoptera Aculeata. Systematic Entomology, 1, 177–182.

http://dx.doi.org/10.1111/j.1365-3113.1976.tb00036.x

Brullé, A. (1832) Expedition Scientifique de Morée. Section des Sciences Physiques, III, 1re partie, Zoologie. F.G. Levrault, Paris, 395 pp., 22 pls.

Cameron, P. (1897) Hymenoptera Orientalia, or contributions to a knowledge of the Hymenoptera of the Oriental zoological region, Part V. Memoirs and Proceedings of the Manchester Literary & Philosophical Society, 41 (4), 1–144.

Cameron, P. (1898) Hymenoptera Orientalia, or contributions to a knowledge of the Hymenoptera of the Oriental zoological region, Part VII. Memoirs and Proceedings of the Manchester Literary & Philosophical Society, 42 (11), 1–84.

Cockerell, T.D.A. (1895) New bees of the genus Halictus from New Mexico, U.S.A. Annals and Magazine of the Natural History, 6 (16), 63–69.

http://dx.doi.org/10.1080/00222939508680230

Cockerell, T.D.A. (1897 a) New and little-known bees. Transactions of the American Entomological Society, 24, 144–162.

Cockerell, T.D.A. (1897 b) The bees of the genus Halictus found in New Mexico. I. Species without any green or blue. Transactions of the American Entomological Society, 24, 163–168.

Cockerell, T.D.A. (1897 c) On the generic position of some bees hitherto referred to Panurgus and Calliopsis. The Canadian Entomologist, 29, 287–290.

http://dx.doi.org/10.4039/Ent29287-12

Cockerell, T.D.A. (1898 a) Tables for the determination of New Mexico bees. Bulletin of the Scientific Laboratories of Denison University, 11, 41–73.

Cockerell, T.D.A. (1898 b) Another yellow Perdita. Entomological News, 9, 215–216.

Cockerell, T.D.A. (1898 c) On some panurgine and other bees. Transactions of the American Entomological Society, 25, 185–198.

Cockerell, T.D.A. (1901 a) Some insects of the Hudsonian Zone in New Mexico. III. Hymenoptera Apoidea. Psyche, 9, 163–164.

Cockerell, T.D.A. (1901 b) Some insects of the Hudsonian Zone in New Mexico. VI. Hymenoptera Apoidea. II. Psyche, 9, 282– 286.

Cockerell, T.D.A. (1903) Notes on the entomology of Pecos, New Mexico. The Canadian Entomologist, 35, 342–343.

http://dx.doi.org/10.4039/Ent35342-12

Cockerell, T.D.A. (1906) The bees of Florissant, Colorado. Bulletin of the American Museum of Natural History, 22, 419–455.

Cockerell, T.D.A. (1910) Some insects from Steamboat Springs, Colo.–II. The Canadian Entomologist, 42, 366–370.

http://dx.doi.org/10.4039/Ent42366-11

Cockerell, T.D.A. (1911) Descriptions and records of bees—XXXIX. Annals and Magazine of Natural History, 8 (8), 660–673.

Cockerell, T.D.A. (1916 a) Descriptions and records of bees—LXXI. Annals and Magazine of Natural History, 8 (17), 277–286.

Cockerell, T.D.A. (1916 b) Some bees from Colorado. The Entomologist, 49, 100–102.

Cockerell, T.D.A. (1925) Bees in the collection of the California Academy of Sciences. Proceedings of the California Academy of Sciences, 24, 185–215.

Cockerell, T.D.A. (1930) Bees from Mesa Verde, Colorado, in the American Museum of Natural History. American Museum Novitates, 397, 1–8.

Cockerell, T.D.A. (1936) Bees from northern California. Pan-Pacific Entomologist, 12, 133–164.

Cockerell, T.D.A. (1937 a) African bees of the genera Ceratina, Halictus and Megachile. British Museum, London, United Kingdom, xvi + 254 pp.

Cockerell, T.D.A. (1937 b) Bees collected in Arizona and California in the spring of 1937. American Museum Novitates, 948, 1–15.

Covell, C.V. (1972) A catalog of the J.H. Lovell types of Apoidea with lectotype designations. Proceedings of the Entomological Society of Washington, 74, 10–18.

Crawford, J.C. (1902) Notes and descriptions of bees. The Canadian Entomologist, 34, 234–240.

http://dx.doi.org/10.4039/Ent34234-9

Crawford, J.C. (1903) Some Nebraska bees. The Canadian Entomologist, 35, 334–336.

http://dx.doi.org/10.4039/Ent35334-12

Crawford, J.C. (1906 a) Some new species of Halictus. The Canadian Entomologist, 38, 4–6.

http://dx.doi.org/10.4039/Ent384-12

Crawford, J.C. (1906 b) A new Halictus from Nebraska. Entomological News, 17, 275–276.

Crawford, J.C. (1906 c) Synopsis of bees of Oregon, Washington, British Columbia and Vancouver.—V. The Canadian Entomologist, 38, 297–304.

http://dx.doi.org/10.4039/Ent38297-9

Crawford, J.C. (1907 a) New Halictinae from the western United States. Invertebrata Pacifica, 1, 190–197.

Crawford, J.C. (1907 b) Notes on some species of the genus Halictus. Journal of the New York Entomological Society, 15, 183– 189.

Crawford, J.C. (1932) New North American bees. Proceedings of the Entomological Society of Washington, 34, 69–78.

Cresson, E.T. (1872) Hymenoptera Texana. Transactions of the American Entomological Society, 4, 153–292.

http://dx.doi.org/10.2307/25076272

Cresson, E.T. (1916) The Cresson types of Hymenoptera. Memoirs of the American Entomological Society, 1, 1–141.

Cresson, E.T. (1928) The types of Hymenoptera in the Academy of Natural Sciences of Philadelphia other than those of Ezra T. Cresson. Memoirs of the American Entomological Society, 5, 1–90.

Curtis, J. (1833) British Entomology, Vol.10. Privately published, London, pls. 434–481.

Dalla Torre, C.G. de (1896) Catalogus Hymenopterorum, Vol. 10, Apidae (Anthophila). Engelmann, Leipzig, viii + 643 pp.

Daly, H.V. (1961) Behavioral observations on Hemihalictus lustrans, with a description of the larva. Journal of the Kansas Entomological Society, 34, 134–141.

Danforth, B.N. (1991) The morphology and behavior of dimorphic males in Perdita portalis (Hymenoptera: Andrenidae). Behavioral Ecology and Sociobiology, 29, 235–247.

http://dx.doi.org/10.1007/BF00163980

Danforth, B.N. (1999) Phylogeny of the bee genus Lasioglossum (Hymenoptera: Halictidae) based on mitochondrial COI sequence data. Systematic Entomology, 24, 377–393.

http://dx.doi.org/10.1006/mpev.1999.0670

Danforth, B.N. & Wcislo, W.T. (1999) Two new and highly apomorphic species of the Lasioglossum subgenus Evylaeus (Hymenoptera: Halictidae) from Central America. Annals of the Entomological Society of America, 92, 624–630.

Danforth, B.N. & Ji, S. (2001) Australian Lasioglossum + Homalictus form a monophyletic group: resolving the “Australian enigma ”. Systematic Biology, 50, 268–283.

http://dx.doi.org/10.1093/sysbio/50.2.268

Danforth, B.N., Conway, L. & Ji, S. (2003) Phylogeny of eusocial Lasioglossum reveals multiple losses of eusociality within a primitively eusocial clade of bees (Hymenoptera: Halictidae). Systematic Biology, 52, 23–36.

http://dx.doi.org/10.1080/10635150390132687

Donovall, L.R. & vanEngelsdorp, D. (2010) A checklist of the bees (Hymenoptera: Apoidea) of Pennsylvania. Journal of the Kansas Entomological Society, 83, 7–24.

http://dx.doi.org/10.2317/JKES808.29.1

Droege, S., Davis, C.A., Steiner, W.E. Jr. & Mawdsley, J. (2009) The lost micro-deserts of the Patuxent River: using landscape history, insect and plant specimens, and field work to detect and define a unique community. Proceedings of the Entomological Society of Washington, 111 (1), 132–144.

http://dx.doi.org/10.4289/0013-8797-111.1.132.

Ebmer, A.W. (1969) Die Bienen des Genus Halictus Latr. s.l. im Grossraum von Linz. Naturkundliches Jahrbuch der Stadt Linz, 133–183. [in German]

Ebmer, A.W. (1974) Die Bienen des Genus Halictus Latr. s. 1. im Grossraum von Linz (Hymenoptera Apoidea). Nachtrag und zweiter Anhang. Naturkundliches Jahrbuch der Stadt Linz, 1973, 123–158. [in German]

Ebmer, A.W. (1987) Die europäischen Arten der Gattungen Halictus Latreille 1804 und Lasioglossum Curtis 1833 mit illustrierten Bestimmungstabellen (Insecta: Hymenoptera: Apoidea: Halictidae: Halictinae). 1. Allgemeiner Teil, Tabelle der Gattungen. Senckenbergiana biologica, 68, 59–148.

Ebmer, A.W. (1995) Asiatische Halictidae, 3. Die Artengruppe der Lasioglossum carinate- Evylaeus (Insecta: Hymenoptera: Apoidea: Halictidae: Halictinae). Linzer Biologische Beiträge, 27, 525–652. [in German]

Ebmer, A.W. (1997) Asiatische Halictidae - 6. Lasioglossum carinaless- Evylaeus: Ergänzungen zu den Artengruppen von L. nitidiusculum und L. punctatissimum s.l, sowie die Artengruppe des L. marginellum (Insecta: Hymenoptera: Apoidea: Halictidae: Halictinae). Linzer Biologische Beiträge, 29, 921–982. [in German]

Ebmer, A.W. (2000) Asiatische Halictidae—9. Die Artengruppe des Lasioglossum pauperatum (Insecta: Hymenoptera: Apoidea: Halictidae: Halictinae). Linzer Biologische Beiträge, 32, 399–453. [in German]

Ebmer, A.W. (2002) Asiatische Halictidae—10. Neue Halictidae aus China sowie diagnostische Neubeschreibungen der von Fan and Ebmer 1992 beschriebenen Lasioglossum -Arten (Insecta: Hymenoptera: Apoidea: Halictidae: Halictinae). Linzer Biologische Beiträge, 34, 819–934. [in German]

Ebmer, A.W. (2008) Neue taxa der Gattungen Halictus Latreille 1804 und Lasioglossum Curtis 1833 (Hymenoptera, Apoidea, Halictidae) aus den Vereinigten Arabischen Emiraten. Linzer Biologische Beiträge, 40 (1), 551–580. [in German]

Ebmer, A.W. & Sakagami, S.F. (1985) Taxonomic notes on the Palaearctic species of the Lasioglossum nitidiusculum group, with description of L. allodalum sp. nov. (Hymenoptera, Halictidae). Kontyû, 53, 297–310.

Eickwort, G.C. (1969) A comparative morphological study and generic revision of the augochlorine bees. University of Kansas Science Bulletin, 40, 325–524.

Ellis, M.D. (1914) New American bees of the genus Halictus (Hym.). Entomological News, 25, 151–155.

Engel, M.S. (2001) A monograph of the Baltic amber bees and evolution of the Apoidea (Hymenoptera). Bulletin of the American Museum of Natural History, 259, 1–192.

http://dx.doi.org/10.1206/0003-0090(2001)259<0001:AMOTBA>2.0.CO;2

Engel, M.S. (2009) Revision of the bee genus Chlerogella (Hymenoptera, Halictidae), Part I: Central American species. Zookeys, 23, 47–75.

http://dx.doi.org/10.3897/zookeys.23.248

Engel, M.S., Hinjosa-Díaz, I.A. & Yáñez-Ordóñez, Y. (2007) The Augochlora -like Dialictus from Guatemala and southern México (Hymenoptera: Halictidae). Acta Zoológica Mexicana, 23, 125–134.

Estes, J.R. & Thorp, R.W. (1975) Pollination ecology of Pyrrhopappus carolinianus (Compositae). American Journal of Botany, 62, 148–159.

http://dx.doi.org/10.2307/2441589

Fabricius, J.C. (1781) Species Insectorum Exibentes Eorum Differentias Specificas, Synonyma, Auctorum, Loca Natalia, Metamorphosin, Adjectis Observationibus, Descriptionibus. T. 1. C. E. Bohn (Hamburgi and Kilonii), vii + 552 pp.

Friese, H. (1918) Bienen aus Sumatra, Java, Malakka und Ceylon gesammelt von Herrn. Prof. Dr. V. Buttel-Reepen. Zoologische Jahrbücher, 41, 489–520.

Gibbs, J. (2009 a) Integrative taxonomy identifies new (and old) species in the Lasioglossum (Dialictus) tegulare (Robertson) (Hymenoptera, Halictidae) species group. Zootaxa, 2032, 1–38.

Gibbs, J. (2009 b) New species in the Lasioglossum petrellum species group identified through an integrative taxonomic approach. The Canadian Entomologist, 141, 371–396.

http://dx.doi.org/10.4039/n09-020

Gibbs, J. (2010 a) Revision of the metallic species of Lasioglossum (Dialictus) in Canada (Hymenoptera, Halictidae, Halictini). Zootaxa, 2591, 1–382.

Gibbs, J. (2010 b) Atypical wing venation in Dialictus and Hemihalictus and its implications for subgeneric classification of Lasioglossum. Psyche, 2010 (605390), 1–6.

http://dx.doi.org/10.1155/2010/605390

Gibbs, J. (2011) Revision of the metallic Lasioglossum (Dialictus) of eastern North America (Hymenoptera: Halictidae: Halictini). Zootaxa, 3073, 1–216.

Gibbs, J., Ascher, J.S. & Packer, L. (2009) Dialictus Robertson, 1902 and Evylaeus Robertson, 1902 (Insecta, Hymenoptera): proposed precedence over Hemihalictus Cockerell, 1897, Sudila Cameron, 1898 and Sphecodogastra Ashmead, 1899. Bulletin of Zoological Nomenclature, 66, 147–158.

Gibbs, J., Albert, J. & Packer, L. (2012 a) Dual origins of social parasitism in North American Dialictus (Hymenoptera: Halictidae) confirmed using a phylogenetic approach. Cladistics, 28 (2), 195–207.

http://dx.doi.org/10.1111/j.1096-0031.2011.00373.x

Gibbs, J., Brady, S., Kanda, K. & Danforth, B.N. (2012 b) Phylogeny of halictine bees supports a shared origin of eusociality for Halictus and Lasioglossum (Apoidea: Anthophila: Halictidae). Molecular Phylogenetics and Evolution. 65 (3), 926–939.

http://dx.doi.org/10.1016/j.ympev.2012.08.013.

Giles, V. & Ascher, J.S. (2006) A survey of the bees of the Black Rock Forest Preserve, New York (Hymenoptera: Apoidea). Journal of Hymenoptera Research, 15, 208–231.

Graenicher, S. (1910) Bees of Northwestern Wisconsin. Bulletin of the Public Museum of the City of Milwaukee, 1, 221–249.

Grundel, R., Jean, R.P., Frohnapple, K.J., Gibbs, J., Glowacki, G.A. & Pavlovic, N.B. (2011) A survey of bees (Hymenoptera: Apoidea) of the Indiana Dunes and northwest Indiana, USA. Journal of the Kansas Entomological Society, 84 (2), 105–138.

http://dx.doi.org/10.2317/JKES101027.1

Hicks, C.H. (1936) Nesting habits of certain western bees. The Canadian Entomologist, 68, 47–52.

http://dx.doi.org/10.4039/Ent6847-3

Houston, T.F. & Maynard G.V. (2012) An unusual new paracolletine bee, Leioproctus (Ottocolletes) muelleri subgen. & sp. nov. (Hymenoptera: Colletidae): with notes on nesting biology and in-burrow nest guarding by macrocephalic males. Australian Journal of Entomology, 51, 248–257.

http://dx.doi.org/10.1111/j.1440-6055.2012.00867.x

Hurd, P.D. Jr. (1979) Superfamily Apoidea. In: Krombein, K.V., Hurd, P.D., Jr., Smith, D.R. & Burks B.D. (Eds.), Catalog of Hymenoptera in America North of Mexico. Smithsonian Institution Press, Washington, D.C., pp. 1741–2209.

Imai, H.T., Crozier, R.H. & Taylor, R.W. (1977) Karyotype evolution in Australian ants. Chromosoma, 59, 341–393.

http://dx.doi.org/10.1007/BF00327974

International Commission on Zoological Nomenclature [ICZN] (1999) International Code of Zoological Nomenclature, 4 th Edition. The International Trust for Zoological Nomenclature, London, xxix + 306 pp.

International Commission on Zoological Nomenclature [ICZN] (2011) Dialictus Robertson, 1902 and Evylaeus Robertson, 1902 (Insecta, Hymenoptera): proposed precedence not granted. Bulletin of Zoological Nomenclature, 68, 309–311.

Kerfoot, W.B. (1967 a) The lunar periodicity of Sphecodogastra texana, a nocturnal bee (Hymenoptera: Halictidae). Animal Behaviour, 15, 479–486.

http://dx.doi.org/10.1016/0003-3472(67)90047-4

Kerfoot, W.B. (1967 b) Nest Architecture and Associated Behavior of the Nocturnal Bee, Sphecodogastra texana (Hymenoptera: Halictidae). Journal of the Kansas Entomological Society, 40, 84–93.

Kirby, W. (1802) Monographia Apum Angliae. Vol. 2. Privately published, Ipswich, United Kingdom, 388 pp. + 18 pls.

Knerer, G. (1968) Zur Bienenfauna Niederösterrich. Die Unterfamilie Halictinae. Zoologische Anzeiger, 181, 82–117. [in German]

Knerer, G. & Atwood, C.E. (1962) An annotated check list of the non-parasitic Halictidae (Hymenoptera) of Ontario. Proceedings of the Entomological Society of Ontario, 92, 160–176.

Knerer, G. & Atwood, C.E. (1964) Further notes on the genus Evylaeus Robertson (Hymenoptera: Halictidae). The Canadian Entomologist, 96, 957–962.

http://dx.doi.org/10.4039/Ent96957-7

Knerer, G. & Atwood, C.E. (1967) Parasitization of social halictine bees in southern Ontario. Proceedings of the Entomological Society of Ontario, 97, 103–110.

Knerer, G. & MacKay, P. (1969) Bionomic Notes on the Solitary Evylaeus oenotherae (Stevens) (Hymenoptera: Halictinae), a Matinal Summer Bee Visiting Cultivated Onagraceae. Canadian Journal of Zoology, 47, 289–294.

http://dx.doi.org/10.1139/z69-060

Krombein, K.V. (1967) Superfamily Apoidea. In: Krombein, K.V. & Burks, B.D. (Eds.), Hymenoptera of America North of Mexico. (Agriculture Monograph No. 2) Second supplement. United States Government Printing Office, Washington, D.C., pp. 422–520.

Kukuk, P.F. & Schwarz, M. (1988) Macrocephalic male bees as functional reproductives and probable guards. Pan-Pacific Entomologist, 64 (2), 131–137.

LaBerge, W.E. & Thorpe, R.W. (2005) A revision of the bees of the genus Andrena of the Western Hemisphere. Part XIV— Subgenus Onagrandrena. Illinois Natural History Survey Bulletin, 37, 1–64,

Linsley, E.G. & MacSwain, J.W. (1962) A new species of Sphecodogastra associated with Oenothera in eastern Utah, New Mexico and western Texas. Pan-Pacific Entomologist, 38, 45–47.

Lippok, B., Gardine, A.A., Williamson, P.S. & Renner, S.S. (2000) Pollination by flies, bees and beetles of Nuphar ozarkana and N. advena (Nymphaeaceae). American Journal of Botany, 87, 989–902.

http://dx.doi.org/10.2307/2656897

Lovell, J.H. (1905 a) Four new species of Halictus from Maine. The Canadian Entomologist, 37, 39–40.

http://dx.doi.org/10.4039/Ent37391-11

Lovell, J.H. (1905 b) Some Maine species of Halictus. The Canadian Entomologist, 37, 299–300.

http://dx.doi.org/10.4039/Ent37299-8

Lovell, J.H. (1908) The Halictidae of Southern Maine. Psyche, 15, 32–42.

http://dx.doi.org/10.1155/1908/53473

Lovell, J.H. & Cockerell, T.D.A. (1907) The Sphecodidae of Southern Maine. Psyche, 14, 101–110.

http://dx.doi.org/10.1155/1907/12128

Maddison, W.P. & Maddison, D.R. (2010) Mesquite: a modular system for evolutionary analysis. Version 2.7. Avaiable from: http://mesquiteproject.org (Accessed 13 June 2013)

Mayr, E. (1974) Cladistic analysis or cladistic classification? Zeitschrift f ű r Zoologische Systematik und Evolutionforschung, 12, 95–128.

McGinley, R.J. (1986) Studies of Halictinae (Apoidea: Halictidae), I: Revision of New World Lasioglossum Curtis. Smithsonian Contributions to Zoology, 429, i–vi + 1–294.

http://dx.doi.org/10.5479/si.00810282.429

McGinley, R.J. (1999) Eickwortia (Apoidea: Halictidae), a new genus of bees from Mesoamerica. In: Byers, G.W.R., Hagen, R.H. & Brooks, R.W. (Eds.), Entomological Contributions in Memory of Byron A. Alexander. University of Kansas Nature History Museum Special Publication, 24, pp. 111–120.

McGinley, R.J. (2003) Studies of Halictinae (Apoidea: Halictidae), II: Revision of Sphecodogastra Ashmead, floral specialists of Onagraceae. Smithsonian Contributions to Zoology, 610, i–iii + 1–55.

Michener, C.D. (1937) Records and descriptions of North American bees. The Annals and Magazine of Natural History, 19, 313–329.

Michener, C.D. (1944) Comparative external morphology, phylogeny, and a classification of the bees (Hymenoptera). Bulletin of the American Museum of Natural History, 82, 151–326.

Michener, C.D. (1947) Some observations on Lasioglossum (Hemihalictus) lustrans (Hymenoptera, Halictidae). Journal of the New York Entomological Society, 55, 49–50.

Michener, C.D. (1951) Superfamily Apoidea. In: Muesebeck, C.F., Krombein, K.V. & Townes, H.K. (Eds.), Hymenoptera of America North of Mexico. USDA Agriculture Monograph No. 2. United States Government Printing Office, Washington, D.C., pp. 1043–1255.

Michener, C.D. (1954) Bees of Panamá. Bulletin of the American Museum of Natural History, 104, 1–176.

Michener, C.D. (1974) The Social Behavior of the Bees. Belknap Press, Cambridge, Massachusetts, 404 pp.

Michener, C.D. (1978) The parasitic groups of Halictidae (Hymenoptera, Apoidea). University of Kansas Science Bulletin, 51 (10), 291–339.

Michener, C.D. (1990) Reproduction and castes in social halictine bees. In: Engels, W. (Ed.), Social insects: An Evolutionary Approach to Castes and Reproduction. Springer, New York, pp. 77–121.

Michener, C.D. (2000) The Bees of the World. Johns Hopkins University Press, Baltimore, Maryland, xv+ 913 pp.

Michener, C.D. (2007) The Bees of the World, 2 nd Ed. Johns Hopkins University Press, Baltimore, Maryland, xvi+[i]+ 953 pp.

Mitchell, T.B. (1960) Bees of the Eastern United States: Volume I. N. C. Agricultural Experimental Station Technical Bulletin, 141, 1–538.

Mitchell, T.B. (1962) Bees of the Eastern United States: Volume II. N. C. Agricultural Experimental Station Technical Bulletin, 152, 1–557.

Miyanaga, R., Maeta, Y. & Sakagami, S.F. (1999) Geographical variation of sociality and size-linked color patterns in Lasioglossum (Evylaeus) apristum (Vachal) in Japan (Hymenoptera, Halictidae). Insectes Sociaux, 46, 224–232.

http://dx.doi.org/10.1007/s000400050138

Morawitz, F. (1865) Ueber einige Andrenidae aus der Umgegend von St.- Petersburg. Horae Societatis Entomologicae Rossicae, 3 (1), 61–79.

Morawitz, F. (1876) Bees (Mellifera). II. Andrenidae: In: Fedchenko, A.P. (Ed.), Travel to Turkestan…Izvestiya Imperatorskogo Obsh χ hestva Ljubitelei Estestvoznaniya, Antropologii i Etnografii Moscovskogo Universiteta (Proceedings of the Society of Naturalists, Anthropologists, and Etnographists of the Moscow University), 21 (pt 3, no. 2), pp. 161–303 + pls. 1–3 [in Russian]

Morawitz, F. (1877) Nachtrag zur Bienenfauna Caucasiens. Horae Societatis Entomologicae Rossicae, 14 (1), 3–112.

Morawitz, F. (1889) Insecta a cl. G.N. Potanin in China et in Mongolia novissime lecta. XIV. Hymenoptera aculeata II, III. Apidae. Horae Societatis Entomologicae Rossicae, 24, 349–385.

Moure, J.S. & Hurd, P.D. Jr. (1987) An Annotated Catalog of the Halictid Bees of the Western Hemisphere (Hymenoptera: Halictidae). Smithsonian Institution Press, Washington, D.C., pp. viii + 505.

Murao, R. & Tadauchi, O. (2007) A revision of the subgenus Evylaeus of the genus Lasioglossum in Japan (Hymenoptera, Halictidae) part I. Esakia, 47, 169–254.

Packer, L. (1993) Multiple-foundress associations in sweat bees. In: Keller, L. (Ed.), Queen Number and Sociality in Insects. Oxford University Press, New York, New York, pp. 215–233.

Packer, L. (1997) The relevance of phylogenetic systematics to biology: Examples from medicine and behavioural ecology. Mémoires du Muséum National d'Histoire Naturelle, 173, 11–29.

Packer, L. (1999) The distribution of Halictus ligatus Say and H. poeyi Lep. (Hymenoptera; Halictidae) in North America. In: Byers, G.W.R., Hagen, R.H. & Brooks, R.W. (Eds), Entomological Contributions in Memory of Byron A. Alexander. University of Kansas Nature History Museum Special Publication, 24, pp. 81–84.

Packer, L. (2010) Keeping the Bees. HarperCollins, Toronto, Canada, pp. x+273.

Packer, L. & Owen, R.E. (1989) Notes on the biology of Lasioglossum (Evylaeus) cooleyi (Crawford), an eusocial halictine bee (Hymenoptera: Halictidae). The Canadian Entomologist, 121, 431–438.

http://dx.doi.org/10.4039/Ent121431-6

Packer, L. & Taylor, J.S. (1997) How many hidden species are there? An application of the phylogenetic species concept to genetic data for some comparatively well known bee “species ”. The Canadian Entomologist, 129, 587–594.

http://dx.doi.org/10.4039/Ent129587-4

Packer, L. & Taylor, J.S. (2002) Genetic variation within and among populations of an arctic/alpine sweat bee (Hymenoptera: Halictidae). The Canadian Entomologist, 134, 619–631.

http://dx.doi.org/10.4039/Ent134619-5

Packer, L., Sampson, B., Lockerbie, C. & Jessome, V. (1989 a) Nest architecture and brood mortality in four species of sweat bee (Hymenoptera; Halictidae) from Cape Breton Island. Canadian Journal of Zoology, 67, 2864–2870.

http://dx.doi.org/10.1139/z89-406

Packer, L., Jessome, V., Lockerbie, C. & Sampson, B. (1989 b) The phenology and social biology of four sweat bees in a marginal environment: Cape Breton Island. Canadian Journal of Zoology, 67, 2871–2877.

http://dx.doi.org/10.1139/z89-407

Panzer, G.W.F. (1798) Fauna Insectorum Germanicae Initia oder Deutschlands Insekten. Felssecker (Nürnberg), Jahrgang. 5, Hefte 49–60.

Park, M.G., Orr, M.C. & Danforth, B.N. (2010) The role of native bees in apple pollination. New York Fruit Quarterly, 18, 21– 25.

Pauly, A. (1980) Descriptions prėliminaires de quelques sous-genres afrotropicaux nouveaux dans la famille des Halictidae (Hymenoptera, Apoidea). Revue de Zoologie Africaine, 94, 119–125.

Pauly, A. (1984) Classification des Halictidae de Madagascar et des iles voisines I. Halictinae (Hymenoptera, Apoidea). Verhandlungen der naturforschenden Gesellschaft in Basel, 94, 121–156.

Pérez, J. (1903) Espèces nouvelles de mellifères (paléarctiques). Procès-verbaux des Séances de la Société Linnéenne de Bordeaux, 58, ccviii–ccxxxvi.

Pesenko, Y.A. (2006) Contributions to the halictid fauna of the Eastern Palaearctic Region: genus Lasioglossum Curtis (Hymenoptera: Halictidae, Halictinae). Zoosystematica Rossica, 15, 133–166.

Pesenko, Y.A. (2007 a) Subgeneric classification of the Palaearctic bees of the genus Evylaeus Robertson (Hymenoptera: Halictidae). Zootaxa, 1500, 1–54.

Pesenko, Y.A. (2007 b) A taxonomic study of the bee genus Evylaeus Robertson of Eastern Siberica and the Far East of Russia (Hymenoptera: Halictidae). Zoosystematica Rossica, 16, 79–123.

Pesenko, Y.A., Banaszak, J., Radchenko, V.G. & Cierzniak, T. (2000) Bees of the family Halictidae (excluding Sphecodes) of Poland: taxonomy, ecology, bionomics. Wydawnictwo Uczelniane Wyz˙szej Skoły Pedagogicznej, Bydgoszczy, Poland, ix + 348 pp.

Phillips, S.J., Anderson, R.P. & Schapier, R.E. (2006) Maximum entropy modeling of species geographic distributions. Ecological Modelling, 190, 231–259.

http://dx.doi.org/10.1016/j.ecolmodel.2005.03.026

Proshchalykin, M.Y. (2004) A check list of the bees (Hymenoptera, Apoidea) of the southern part of the Russian Far East. Far East Entomologist, 143, 1–17.

Provancher, L. (1888), in 1885– 1889 Additions et Corrections au Vol. II. de la Faune Entomologique du Canada Traitant des Hyménoptères. Darveau, Quebec, pp. 1–475.

Radoszkowski, O. (1888) Fauna hyménoptèrologique Transcaspienne. (Suite). Horae Societatis Entomologicae Rossicae, 22 (3– 4), 338–349.

Ratnasingham, S. & Hebert, P.D.N. (2007) BOLD: the barcoding of life data system (www.barcodinglife.org). Molecular Ecology Notes, 7, 355–364.

Richards, M.H., Rutgers-Kelly, A., Gibbs, J., Vickruck, J.L., Rehan, S.M. & Sheffield, C.S. (2011) Bee diversity in naturalizing patches of Carolinian grasslands in southern Ontario. The Canadian Entomologist, 143, 279–299.

http://dx.doi.org/10.4039/n11-010

Robertson, C. (1890) New North American bees of the genera Halictus and Prosopis. Transactions of the American Entomological Society, 17, 315–318.

Robertson, C. (1893) Notes on bees, with descriptions of new species. Transactions of the American Entomological Society, 20, 145–149.

Robertson, C. (1895) Notes on bees, with descriptions of new species. Transactions of the American Entomological Society, 22, 115–128.

Robertson, C. (1898) New or little known North American Bees. Transactions of the Academy of Science of St. Louis, 8, 43–54.

Robertson, C. (1901) Some new or little-known bees. The Canadian Entomologist, 33, 229–231.

http://dx.doi.org/10.4039/Ent33229-8

Robertson, C. (1902 a) Some new or little-known bees—II. The Canadian Entomologist, 34, 48–49.

http://dx.doi.org/10.4039/Ent3448-2

Robertson, C. (1902 b) Synopsis of Halictinae. The Canadian Entomologist, 34, 243–250.

http://dx.doi.org/10.4039/Ent34243-9

Robertson, C. (1928) Flowers and Insects. Privately published, Carlinville, Illinois, 221 pp.

Sakagami, S.F. & Toda, M.J. (1986) Some arctic and subarctic solitary bees collected at Inuvik and Tuktoyaktuk, NWT, Canada (Hymenoptera: Apoidea). The Canadian Entomologist, 118, 395–405.

http://dx.doi.org/10.4039/Ent118395-5

Sakagami, S.F., Ebmer, A.W. & Tadauchi, O. (1996) The halictine bees of Sri Lanka and the vicinity III. Sudila (Hymenoptera, Halictidae) Part 1. Esakia, 36, 143–189.

Sandhouse, G.A. (1943) The type species of the genera and subgenera of bees. Proceedings of the United States National Museum, 92, 519–619.

http://dx.doi.org/10.5479/si.00963801.3156.519

Schenck, A. (1853) Nachtrag zu der Beschreibung nassauischer Bienen. Jahresbücher des Vereins für Naturkunde im Herzogthum Nassau, 9 (1), 88–306.

Schenck, A. (1861) Die nassauischen Bienen. Revision und Ergänzung der früheren Bearbeitungen. Jahresbücher des Vereins für Naturkunde im Herzogthum Nassau, (1859), 14, 1–414.

Schenck, A. (1874) Aus der Bienen-Fauna Nassau’s. Berliner entomologische Zeitschrift, 18, 161–173.

http://dx.doi.org/10.1002/mmnd.18740180136

Schmidt-Lebuhn, A.N. (2012) Fallacies and false premises - a critical assessment of the arguments for the recognition of paraphyletic taxa in botany. Cladistics, 28, 174–187.

http://dx.doi.org/10.1111/j.1096-0031.2011.00367.x

Schrank, F.P. (1781) Enumeratio insectorum Austriae indigenorum. Viduam E. Klett et Frank, Augsburg, 548 pp.

Scopoli, I.A. (1763) Entomologia Carniolica; Exhibens Insecta Carnioliae Indigena et Distributa in Ordines, Genera, Species, Varietates. Methodo Linnaeana. J.T. Trattner, Wien, Austria, xxxvi + 420 pp.

Sheffield, C.S., Kevan, P.G., Smith, R.F., Rigby, S.M. & Rogers, R.E.L. (2003) Bee species of Nova Scotia, Canada, with new records and notes on bionomics and floral relations (Hymenoptera: Apoidea). Journal of the Kansas Entomological Society, 76, 357–384.

Sheffield, C.S., Hebert, P.D.N., Kevan, P.G. & Packer, L. (2009) DNA barcoding a regional bee (Hymenoptera: Apoidea) fauna and its potential for ecological studies. Molecular Ecology Resources, 9 (S1), 196–207.

http://dx.doi.org/10.1111/j.1755-0998.2009.02645.x

Smith, F. (1848) Descriptions of the British species of bees belonging to the genus Halictus of Latreille. Zoologist, 6, 2037– 2044.

Smith, F. (1853) Catalogue of Hymenopterous Insects in the Collection of the British Museum Part 1. British Museum, London, i + 198 pp. + pls. i–vi.

Stevens, O.A. (1920) Notes on species of Halictus visiting evening flowers (Hym). Entomological News, 31, 35–44.

Strand, E. (1913) H. Sauter’s Formosa-Ausbeute. Apidae I (Hym.). Supplementa Entomologica, 2, 23–67.

Svensson, B.G., Ebmer, A.W. & Sakagami, S.F. (1977) Lasioglossum (Evylaeus) boreale, a new Halictinae (Hymenoptera: Apoidea) species found in northern Sweden and on Hokkaido, Japan, with notes on its biology. Entomologica Scandinavica, 8, 219–229.

http://dx.doi.org/10.1163/187631277 X00297 View Materials

Tamura, K., Peterson, D., Peterson, N., Stecher, G., Nei, M. & Kumar, S. (2011) MEGA5: Molecular Evolutionary Genetics Analysis using maximum likelihood, evolutionary distance, and maximum parsimony methods. Molecular Biology and Evolution, 28, 2731–2739.

http://dx.doi.org/10.1093/molbev/msr121

Vachal, J. (1895) Halictus nouveaux de la collection Mediná. Boletin de la Real Sociedad Española de Historia Natural, Sér. 2, 4, 147–150.

Vachal, J. (1904) Halictus nouveaux ou presume nouveaux d’Amérique (Hym.) Bulletin de la Société Scientifique, Historique et Archéologique de la Corrèze, 26, 469–486.

Viereck, H.L. (1903) Hymenoptera of Beulah, New Mexico. Transactions of the American Entomological Society, 29, 43–100.

Viereck, H.L. (1916) The Hymenoptera, or wasp-like insects of Connecticut. Connecticut State Geological and Natural History Survey Bulletin, 22, 1–824 + pls. I–X.

Warncke, K. (1975) Beiträge zur systematik und Verbreitung der Furchenbienen in der Türkei (Hymenoptera, Apoidea, Halictus). Polskie Pismo Entomologiczne, 45, 81–123. [in German]

Warncke, K. (1981) Beitrag zur Bienenfauna des Iran. 14. Die Gattung Halictus Latr., mit Bemerkungen über unbekannte und neue Halictus -Arten in der Westpaläarktis und Zentralasien. Bollettino del Museo Civico di Storia Naturale di Venezia, 32, 67–166. [in German]

Wcislo, W.T. (1990) A new species of Lasioglossum from Costa Rica (Hymenoptera: Halictidae). Journal of the Kansas Entomological Society, 63, 450–453.

Webb, D.W. (1980) Primary insect types in the Illinois Natural History Survey collection, exclusive of the Collembola and Thysanoptera. Illinois Natural History Survey Bulletin, 32, 55–191.

Winfree, R., Williams, N.M., Gaines, H., Ascher, J.S. & Kremen, C. (2008) Wild bee pollinators provide the majority of crop visitation across land-use gradients in New Jersey and Pennsylvania, USA. Journal of Applied Ecology, 45 (3), 793–802.

http://dx.doi.org/10.1111/j.1365-2664.2007.01418.x

Wolf, A.T. & Ascher, J.S. (2009) Bees of Wisconsin (Hymenoptera: Apoidea: Anthophila). The Great Lakes Entomologist, 41, 129–168.

Zayed, A. & Packer, L. (2007) The population genetics of a solitary oligolectic sweat bee, Lasioglossum (Sphecodogastra) oenotherae (Hymenoptera: Halictidae). Heredity, 99, 397–405.

http://dx.doi.org/10.1038/sj.hdy.6801013

Zayed, A., Constantin, Ş.A. & Packer, L. (2007) Successful Biological Invasion despite a Severe Genetic Load. PLoS ONE, 2 (9), e 868.

http://dx.doi.org/10.1371/journal.pone.0000868

Zetterstedt, J.W. (1838) Insecta Lapponica descripta. Sectio II. Hymenoptera. Voss, Leipzeig, Germany, pp. 315–476.