Prionopetalum
publication ID |
https://doi.org/ 10.5852/ejt.2016.215 |
DOI |
https://doi.org/10.5281/zenodo.5695717 |
persistent identifier |
https://treatment.plazi.org/id/03D3D100-FFE6-C408-F297-FBFB7F33FE48 |
treatment provided by |
Plazi |
scientific name |
Prionopetalum |
status |
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A key to the species of Prionopetalum View in CoL
This key builds extensively on previous keys provided by Kraus (1960) and VandenSpiegel & Pierrard (2009).The new species described here is included, but Aquattuor fasciatus View in CoL is excluded, and P. stuhlmanni View in CoL is treated as a synonym of P. kraepelini View in CoL (cf. above). I follow VandenSpiegel & Pierrard (2009) in not considering Spinotarsus werneri Attems, 1910 View in CoL as a species of Prionopetalum View in CoL , although Kraus (1960) suggested such a relationship (but still listed S. werneri View in CoL under ”species incertae sedis ”).
1. Coxa with a straight, mostly long lateral spine pointing basad, laterobasad or laterad ( Fig. 9 View Fig. 9 A –L) ......................................................................................................................................................2 – Coxa different, sometimes with another type of lateral process, but not a straight basad, laterobasad or laterad spine.................................................................................................................................13
2. Lateral coxal spine directed laterad, set off by right angles from main coxal margin ( Fig. 9 View Fig. 9 A) ...... ......................................................................................................... P. megalacanthum Attems, 1912 View in CoL – Lateral coxal spine different.............................................................................................................3
3. Lateral coxal spine directed basad, in part overlying main body of coxa ( Fig. 9 View Fig. 9 B) ....................... ............................................................................................................. P. frundsbergi (Attems, 1927) View in CoL – Lateral coxal spine different.............................................................................................................4
4. Tip of distal telomere process (tdp) divided into two equal branches ( Fig. 10 View Fig. 10 A). Gonopod coxa profile as Fig. 9 View Fig. 9 C ............................................................ P. bifidum VandenSpiegel & Pierrard, 2009 – Tip of distal telomere process not divided into two equal branches, but one or two small subapical processes may be present..................................................................................................................5
5. Distal telomere process (tdp) ending in three dark spines ( Fig. 10 View Fig. 10 B). Gonopod coxa profile as Fig. 9 View Fig. 9 D ................................................................................................ P. tricuspis Brolemann, 1920 View in CoL – Tip of distal telomere process at most with a single accessory process/spine...........................6
6. Proximal telomere process (tpp) distally expanded, asymmetrically club-shaped ( Fig. 11 View Fig. 11 A –F)......7 – Proximal telomere process not strongly expanded distally ( Fig. 11 View Fig. 11 G–K).......................................12
7. Distal telomere process (tdp) with a small accessory process ( Fig. 10 View Fig. 10 C)....................................8 – Distal telomere process without accessory process (like Fig. 10 View Fig. 10 D).............................................9
8. Lateral coxal spine relatively short, directed almost basad ( Fig. 9 View Fig. 9 E). Proximal telomere process (tpp) moderately asymmetrical ( Fig. 11 View Fig. 11 A) ............................................. P. aculeatum Attems, 1914 View in CoL – Lateral coxal spine directed almost laterad ( Fig. 8 View Fig. 8 F). Proximal telomere process strongly asymmetrical ( Fig. 11 View Fig. 11 B) ............................................................. P. ndelei VandenSpiegel & Pierrard, 2009
9. Coxa mesapically rounded ( Fig. 9 View Fig. 9 G). Proximal telomere process as in Fig. 11 View Fig. 11 C ............................... ...................................................................................................................... P. serratum Attems, 1909 View in CoL – Coxa mesapically with a spinous projection ( Fig. 9 View Fig. 9 H–J, arrows)................................................10
10. Distal margins of proximal telomere process (tpp) smooth ( Fig. 10 View Fig. 10 D). Gonopod coxa profile as Fig. 9 View Fig. 9 H .................................................................................................. P. dentigerum Verhoeff, 1941 View in CoL – Distal margin of proximal telomere process wavy or with a denticle ( Fig. 11 View Fig. 11 E–F).........11
11. Distal margin of proximal telomere process (tpp) wavy ( Fig. 11 View Fig. 11 E). Gonopod coxa profile as Fig. 9 View Fig. 9 I ............................................................................................................. P. tanganjikum Verhoeff, 1941 View in CoL – Distal margin of proximal telomere process with a single denticle ( Fig. 11 View Fig. 11 F, arrow). Gonopod coxa profile as Fig. 9 View Fig. 9 J .............................................................................. P. xerophilum (Carl, 1909) View in CoL 12. Proximal telomere process (tpp) straight, apically rounded ( Fig. 11 View Fig. 11 G). Body diameter 5.5 mm. Gonopod coxa profile as Fig. 9 View Fig. 9 K ..................................................... P. clarum ( Chamberlin, 1927) View in CoL – Proximal telomere process slightly curved, pointed ( Fig. 11 View Fig. 11 H). Body diameter 3 mm. Gonopod coxa profile as Fig. 9 View Fig. 9 L .............................................................................. P. pulchellum Kraus, 1960 View in CoL
13. Coxa with a strongly curved lateral spine ( Fig. 9 View Fig. 9 M–N)............................................................14 – Lateral coxal spine, if present, not strongly curved.....................................................................15
14. Gonopod coxa profile as Fig. 9 View Fig. 9 M. Body diameter 2.5 mm ............ P. etiennei Damange, 1982 View in CoL – Gonopod coxa profile as Fig. 9 View Fig. 9 N. Body diameter 3.3–3.8 mm ........................................................ ............................................................................................ P. lindi VandenSpiegel & Pierrard, 2009
15. Lateral coxal spine sizeable, directed apicad and partly overlying main body of coxa. Coxa apically bifid ( Fig. 9 View Fig. 9 O–Q)...............................................................................................................16 – Coxa at most with a tiny lateral spine or bump ( Fig. 9 View Fig. 9 R–W).............................................18
16. Both apical branches of coxa pointed, the mesal branch hook-like ( Fig. 9 View Fig. 9 O) ................................ ................................................................................................................... P. coronatum Kraus, 1958 View in CoL – Mesal-apical branch of coxa not pointed ( Fig. 9 View Fig. 9 P–Q)...............................................................17
17. Gonopod coxa profile as Fig. 9 View Fig. 9 P ........................................................ P. exaratum ( Attems, 1938) View in CoL – Gonopod coxa profile as Fig. 9 View Fig. 9 Q ............................................................ P. cornutum Kraus, 1958 View in CoL
18. Proximal telomere process (tpp) with several lobes along one side ( Fig. 11 View Fig. 11 I). Gonopod coxa profile as Fig. 9 View Fig. 9 R ................................................................................. P. kraepelini ( Attems, 1896) View in CoL – Proximal telomere process at most with a single lateral lobe ( Fig. 11 View Fig. 11 J–K)..........................19
19. Coxal apex hook-like ( Fig. 9 View Fig. 9 S). Body diameter 2.5 mm .................... P. glomeratum Attems, 1935 View in CoL – Coxal apex not hook-like ( Fig. 9 View Fig. 9 T–W). Body diameter 4.4–5 mm ............................................20
20. Coxal apex with three mesad processes ( Fig. 9 View Fig. 9 T) ................................ P. urbicolum (Carl, 1909) View in CoL – Coxal apex with two mesad processes ( Fig. 9 View Fig. 9 U–W)................................................................... 21 21. Both mesad processes of coxal apex pointed ( Fig. 9 View Fig. 9 U) ...................... P. suave (Gerstäcker, 1873) View in CoL – Subapical mesad process of coxal apex rounded ( Fig. 9 View Fig. 9 V–W).....................................................22
22. Gonopod coxa profile as Fig. 8 View Fig. 8 V. Solenomere with a short accessory branch at c. ⅔ of its length. Proximal telomere process as Fig. 11 View Fig. 11 J. ............................................................ P. fryeri ( Turk, 1956) View in CoL – Gonopod coxa profile as Fig. 8 View Fig. 8 W. Solenomere without an accessory branch. Proximal telomere process as Fig. 11 View Fig. 11 K ........................................................................................... P. asperginis View in CoL sp. nov.
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