Research Article

What do morphological data tell us about the Andean-Neotropical Gripopteryginae (Plecoptera: Gripopterygidae) and related taxa?

Tácio Duarte^‡, Pitágoras C. Bispo^§, Pablo Pessacq^‡

‡ Universidad Nacional de la Patagonia San Juan Bosco, Esquel, Argentina

§ Universidade Estadual Paulista, Assis, Brazil

Corresponding author: Tácio Duarte ( tacioduarte@alumni.usp.br )

Academic editor: Steffen Pauls

This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Citation:

Abstract

The Gripopterygidae family, a diverse group of stoneflies (Plecoptera) endemic to the Southern Hemisphere, has traditionally been divided into five subfamilies, though the monophyly of most remains uncertain due to limited morphological and molecular support. Here we conducted a morphology-based cladistic analysis using 50 characters and 41 taxa, including representatives from all five Gripopterygidae subfamilies and three Austroperlidae species, to test the monophyly of Gripopteryginae and determine the phylogenetic position of a newly discovered species, Tupiperla furcata sp. nov. The analysis, rooted with Penturoperla barbata (Austroperlidae), employed parsimony with implied weighting and tree bisection reconnection methods. Results supported a core Gripopteryginae clade, with absence of a posterior sclerite in tergum 10, but excluded Neopentura semifusca, which was more closely related to Antarctoperlinae. Additionally, Paragripopteryx munoai presented morphological divergence, suggesting it may require reclassification into a new genus. These results challenge the current subfamily classifications, particularly Dinotoperlinae and Leptoperlinae, and highlight the need for further taxonomic revision. To advance the understanding of Gripopterygidae phylogeny, we suggest incorporating molecular data and expanding taxon sampling throughout the Southern Hemisphere. Such efforts would clarify evolutionary relationships and biogeographic patterns, paving the way for a more robust classification of Plecoptera.

Un resumen traducido al español puede consultarse en el suplemento electrónico (File S1).

Keywords

Morphology, Neotropical region, Patagonia, Phylogenetic Systematics, South America

1. Introduction

Stoneflies, belonging to the Plecoptera Order, comprise over 4,500 described species, fossil species included (Burmeister 1839; DeWalt et al. 2025). This order is divided into two suborders: Arctoperlaria, primarily distributed in the Northern Hemisphere and containing 13 families, and the circum-Antarctic Antarctoperlaria, which consists of four families (DeWalt et al. 2025). Zwick (2000) proposed that Antarctoperlaria originated in Gondwana. However, Letsch et al. (2021) challenged this view, suggesting that Plecoptera diversified into three lineages (Antarctoperlaria, Euholognatha, and Systellognatha) in northern Pangaea. According to their study, Antarctoperlaria migrated south, diversified in Gondwana approximately 180 Mya, and became extinct in Laurasia. Letsch et al. (2021) concluded that long-distance dispersal, rather than vicariance, played a more significant role in shaping Plecoptera’s global distribution. The Gripopterygidae family (Antarctoperlaria) emerged as an independent lineage around 155 Mya during the Upper Jurassic, triggering diversification in the Lower Cretaceous (Letsch et al. 2021).

Presently, the Gripopterygidae are the most diverse family within Antarctoperlaria, with 55 genera and around 330 species (Pessacq et al. 2019) (Fig. 1), following the distribution pattern of the suborder. The nymphs are primarily scrapers or shredders, inhabiting clean, fast-flowing streams and associating with boulder surfaces, pebbles, tree trunks, moss, and leaf packs. Given their ecological role, the nymphs contribute significantly to the decomposition of organic matter in freshwater ecosystems, playing a key role in nutrient cycling. Adults are weak fliers, typically found on riparian vegetation or rocks near streams (Brundin 1967, 1972; Hynes 1976; Zwick 2000; McCulloch et al. 2009).

Figure 1.

Historical classification of Gripopterygidae based on reviews by Enderlein (1909), Illies (1963), Zwick (1973), and McLellan (1977). The current number of species per genus is provided in parentheses, and colored circles represent the distribution of each genus.

Enderlein (1909) established the family and proposed its division into two subfamilies: Antarctoperlinae and Gripopteryginae (Fig. 1). Antarctoperlinae included the genera Antarctoperla Enderlein, 1905, Notoperla Enderlein, 1909, and Paranotoperla Enderlein, 1909, while Gripopteryginae comprised the genera Gripopteryx Pictet, 1841, Paragripopteryx Enderlein, 1909, Eusthenia Westwood, 1832, and Stenoperla McLachlan, 1866.

Illies (1963) reviewed Gripopterygidae and suggested a new classification with five subfamilies. In addition to Antarctoperlinae and Gripopteryginae, Illies raised the Leptoperlini tribe to subfamily status (Leptoperlinae), recovered Andiperlinae (Banks 1913; Aubert 1956; Illies 1960, 1963), and proposed the subfamily Paragripopteryginae. Zwick (1973) later deemed the system deficient because it anchored taxa based on plesiomorphic characters. The Andiperlinae genera were then reassigned to the subfamilies Antarctoperlinae (Megandiperla Illies, 1960) and Paragripopteryginae (Andiperla Aubert, 1956, and Andiperlodes Illies, 1963).

Finally, McLellan (1977) reviewed Gripopterygidae and introduced the currently accepted classification (Fig. 1): the subfamily Paragripopteryginae, representing South American genera, was considered a junior synonym of Gripopteryginae, and two new subfamilies were introduced, Dinotoperlinae and Zelandoperlinae. The first includes genera from Australia previously classified in Paragripopteryginae and Gripopteryginae, and the second includes genera from New Zealand previously grouped in Gripopteryginae and Leptoperlinae, as well as the South American genus Notoperlopsis Illies, 1963.

In the mid-2010s and early 2020s, two significant phylogenetic studies included substantial representation of South American Gripopterygidae: McCulloch et al. (2016) and Pessacq et al. (2020). The molecular-based phylogeny by McCulloch et al. (2016) analyzed 14 South American Gripopterygidae genera and species, with Gripopteryginae represented by seven genera and species. This accounted for approximately 50% of the known genera and 10% of the known species of the subfamily. The Austroperlidae species Acruroperla atra (Šámal, 1921) was recovered as sister to Notoperla within Gripopterygidae. Additionally, the analysis revealed that most Antarctoperlinae clustered together, Zelandoperlinae were recovered monophyletic, and Gripopteryginae was polyphyletic. However, McCulloch et al. (2016) did not specifically aim to test the monophyly of Gripopterygidae subfamilies, as this was beyond their scope and sampling.

Pessacq et al. (2020) conducted a morphology-based phylogenetic analysis focused on testing the monophyly of Antarctoperlinae. The study included most Andean-Patagonian representatives of Gripopterygidae and revealed Antarctoperlinae as polyphyletic, resulting in its redefinition. This reclassification excluded Vesicaperla kuscheli McLellan, 1977, and cast doubt on the position of Plegoperla punctata (Froehlich, 1960), which was recovered nested within the same clade as members of the Gripopteryginae. The placement of Plegoperla punctata was attributed to a significant amount of missing data in the analysis (Pessacq et al. 2020).

Letsch et al. (2021) later re-analyzed McCulloch et al. (2016) dataset for Gripopterygidae and obtained similar results regarding family-level relationships. However, changes were observed in the positions of terminal taxa, including Acruroperla atra, which was placed outside of Gripopterygidae in their analysis.

Gripopteryginae is restricted to South America and currently consists of 15 genera and around 80 species, representing distinct regional components (Pessacq et al. 2019; Duarte et al. 2024). Most Gripopteryginae genera are endemic to southern Argentina and Chile (Andean-Patagonian species, sensu Morrone 2015), including Andiperla, Andiperlodes, Aubertoperla Illies, 1963, Falklandoperla McLellan, 2001a, Limnoperla Illies, 1963, Neopentura Illies, 1965, Potamoperla Illies, 1963, Rhithroperla Illies, 1963, Teutoperla Illies, 1963, and Uncicauda McLellan & Zwick, 2007. Except for Teutoperla, they are either monotypic or have two species (Duarte et al. 2024). Claudioperla Illies, 1963, which is composed of four species, spans the Andes Mountains from Colombia to northern Argentina and Chile. The Neotropical region (sensu Morrone 2014) is home to four other genera: Gripopteryx (18 species), Guaranyperla Froehlich, 2001 (6 species), Paragripopteryx (15 species), and Tupiperla Froehlich, 1969 (27 species), which range in their distribution from the Brazilian Atlantic Forest and inland to northeastern Argentina, southern Paraguay, and Uruguay (Duarte et al. 2024; Sarmento et al. 2025).

McLellan (1977) outlined the defining characteristics of the subfamilies (Table 1), with Gripopteryginae defined by the following characters: (i) legs with a pair of distoventral spurs on each tibia, (ii) forewings with a long CuA fork, (iii) hind wings with the sixth anal vein fused to the wing margin, (iv) male genitalia with an unrecurved epiproct tip (some genera with an absent or very small epiproct), (v) sclerotized tergum 10, and (vi) the absence of a posterior sclerite in tergum 10.

Emphasizing the necessity to reassess the intergeneric relationships in Gripopterygidae and redefine the current South American subfamilies, McLellan and Zwick (2007) paved the way for our primary objective: to test the monophyly of Gripopteryginae by proposing a hypothesis for the phylogenetic relationship between their genera. To achieve this goal, we inferred a morphology-based phylogeny that encompasses as many genera as possible from the five subfamilies of Gripopterygidae, specifically including all Gripopteryginae genera. In addition, we included comments on the other subfamilies of Gripopterygidae. Finally, in this study, a new species of Gripopterygidae is described, and its generic position is proposed.

Table 1.

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Diagnostic characters and distribution of Gripopterygidae subfamilies (sensu McLellan 1977; Zwick 2000).

Characters	Gripopterygidae subfamilies and character states
Characters	Dinotoperlinae	Gripopteryginae	Leptoperlinae	Zelandoperlinae	Antarctoperlinae
Forewing CuA fork	Long	Long	Absent	Absent	Absent
Hind wing (6^th anal vein)	Free of wing margin	Fused to wing margin	Fused (Australia); Free (South America)	Free of wing margin	Free of wing margin
Tibial spurs	Present (distoventral)	Present (distoventral)	Present (distoventral)	Absent	Absent
Tergum 10	Membranous; no posterior sclerite	Sclerotized; no posterior sclerite	Sclerotized; posterior sclerite present	Sclerotized; posterior sclerite present	Small posterior sclerite present
Epiproct	Curved back and down	Lacks recurved tip; may be absent	Tip varies (upcurved, hooked, or spined)	Not turned back and down	Small, sessile, or on membranous stalk
Larval habitat	Aquatic	Aquatic	Aquatic	Terrestrial or aquatic	Terrestrial or aquatic
Distribution	Australia, Andean	Andean-Neotropical	Australia, Andean	New Zealand, Andean	New Zealand, Andean

2. Material and methods

2.1. Material studied

To ensure comprehensive representation of all Gripopterygidae subfamilies, our study included multiple genera and species. Specimens from South America (including the Neotropical region, the South American transition zone, and the Andean region (sensu Morrone (2014, 2015)), as well as from Australia, were examined at the Centro de Investigación Esquel de Montaña y Estepa Patagónica (CIEMEP) in Esquel, Chubut, Argentina, and at the Collection of Aquatic Insects “Prof. Dr. Cláudio Gilberto Froehlich”, Aquatic Biology Laboratory, State University of São Paulo (UNESP), Assis, São Paulo, Brazil (Table 2). Additional Australian specimens were examined at the Stuttgart State Museum of Natural History (SMNS), Stuttgart, Germany.

Table 2.

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Outgroup and ingroup species included in the cladistic analyses. Subfamilies, according to McLellan (1977). Abbreviations: CIACGF, Collection of Aquatic Insects “Prof. Dr. Cláudio Gilberto Froehlich”, Aquatic Biology Laboratory, State University of São Paulo (UNESP), Assis, São Paulo, Brazil; CIEMEP, Centro de Investigación Esquel de Montaña y Estepa Patagónica, Esquel, Chubut, Argentina; MZUSP, Museum of Zoology of the University of São Paulo, São Paulo, Brazil; SMNS, Stuttgart State Museum of Natural History, Stuttgart, Germany. *Spans the Andes Mountains from Colombia to northern Argentina and Chile.

Groups	Families/subfamilies	Analyzed species	Distribution	Institutions
Outgroup	Austroperlidae	Klapopteryx kuscheli, Klapopteryx armillata, Penturoperla barbata	Andean-Patagonian	CIEMEP
	Gripopterygidae
	Antarctoperlinae	Antarctoperla michaelseni, Ceratoperla fazi, Chilenoperla elongata, Chilenoperla puelche, Ericiataperla puerilis, Pehuenioperla llaima, Pelurgoperla personata	Andean-Patagonian	CIEMEP
	Dinotoperlinae	Alfonsoperla flinti	Andean-Patagonian	CIEMEP
	Dinotoperlinae	Dinotoperla serricauda, Trinotoperla irrorata	Australia	SMNS
	Leptoperlinae	Notoperla fasciata, Notoperla magnaspina, Senzilloides panguipullii	Andean-Patagonian	CIEMEP
	Leptoperlinae	Cardioperla nigrifrons, Leptoperla varia, Newmanoperla thoreyi, Riekoperla perkinsi	Australia	SMNS
	Zelandoperlinae	Notoperlopsis femina	Andean-Patagonian	CIEMEP
Ingroup	Gripopteryginae	Gripopteryx cancellata, Gripopteryx liana, Guaranyperla guapiara, Guaranyperla nitens, Paragripopteryx klapaleki, Paragripopteryx blanda, Paragripopteryx munoai, Tupiperla gracilis, Tupiperla robusta	Neotropical	CIACGF, MZUSP
		Andiperla willinki, Andiperlodes tehuelche, Aubertoperla illiesi, Claudioperla tigrina, Limnoperla jaffueli, Neopentura semifusca, Potamoperla myrmidon, Rhithroperla rossi, Teutoperla maulina, Uncicauda testacea*	Andean-Patagonian	CIEMEP
		New, unnamed species from Brazil.	Neotropical	CIACGF, MZUSP

Morphological characters and primary homologies were supplemented using key original works, including Illies (1963, 1965), Froehlich (1969, 1990, 1994, 1998, 2001), McLellan (1977), and McLellan and Zwick (2007). Wing venation terminology follows Béthoux (2005).

In this work we included specimens from the following institutions: CIACGF – Collection of Aquatic Insects “Prof. Dr. Cláudio Gilberto Froehlich”, Aquatic Biology Laboratory, State University of São Paulo (UNESP), Assis, São Paulo, Brazil; CIEMEP – Centro de Investigación Esquel de Montaña y Estepa Patagónica, Esquel, Chubut, Argentina; MZUSP – Museum of Zoology of the University of São Paulo, São Paulo, Brazil; SMNS – Stuttgart State Museum of Natural History, Stuttgart, Germany.

2.2. Microscopy and image processing

The specimens’ external morphology was examined by the authors using a Leica S9E and a Leica M205A stereomicroscope. The photographs were taken using a Leica M205A stereomicroscope and processed using the image editing software Adobe® Photoshop CC. The line drawings were prepared with the aid of a camera lucida and vectored on Adobe® Illustrator CC, as well as the final topology.

2.3. Dataset and morphological treatment

We used 41 terminal taxa, with 38 (29 genera) falling under Gripopterygidae and three (two genera) falling under Austroperlidae (Table 2), in line with the recent studies that recovered a sister relationship between these families (see McCulloch et al. 2016; Ding et al. 2019; Letsch et al. 2021; García-Girón et al. 2024). The dataset was built using Mesquite 3.81 (Maddison and Maddison 2023) and exported to the format employed in the ‘Tree analysis using New Technology’ software (TNT v. 1.6; Goloboff and Morales 2023). The dataset is provided in Table S1.

Penturoperla barbata Illies, 1960 was selected as the root of the tree. For the 41 terminal taxa, we selected 50 morphological characters (28 binary and 22 multistate) and their associated states (see section “Morphological Characters List”). Character coding followed the contingency method proposed by Sereno (2007), with four logical components (locator, variable, variable qualifier, and character status), and the criteria of character types as proposed by Simões et al. (2016). In the dataset, we used a “?” when a character could not be found in each species and a “–” when a character was deemed inapplicable.

2.4. Cladistic analysis

The Parsimony analysis was utilized, treating all characters as nonadditive (Fitch 1971). We employed the “Traditional search” command in TNT, with Tree Bisection Reconnection (TBR) branch swapping, conducting 1,000 replications, saving 100 trees per replication, and collapsing trees after the search.

We performed an initial analysis using Equal Weighting (EW) Parsimony. However, EW usually produces a consensus tree that is overly conservative, failing to accurately represent phylogenetic relationships (Goloboff et al. 2008, 2018). To address this limitation, we focused on identifying characters with greater cladistic congruence while downweighing those with a higher degree of homoplasy (Goloboff 1997). Analyses were subsequently conducted under Implied Weighting (IW) Parsimony to account for homoplastic characters (Goloboff 1993; Giribet 2003; Goloboff et al. 2008). IW employs a parameter (k, the concavity constant) to determine the degree to which homoplasy (independently evolved similar traits) is penalized during phylogenetic reconstruction. Goloboff (1993) originally introduced the method with a strong concavity (k = 3), which remains the default in the TNT software (Goloboff et al. 2018). However, later studies, particularly those involving larger datasets, showed that better results have been obtained with higher k values (e.g., k = 12; see Goloboff et al. 2008, p. 765), which apply milder penalties to homoplastic characters (Goloboff et al. 2008, 2018; Smith 2019). Following these recommendations, we employed a range of k values, from 3 to 15, to evaluate potential topological changes and assess the impact of weighting against homoplasy. We also analyzed the dataset in TNT with the option “choose k value so that the weight ratio between no homoplasy and maximum possible steps is the ratio 1 to 10,000” to identify a potential optimal k value for the dataset under analysis.

To estimate branch support, we employed Relative Bremer support (Goloboff and Farris 2001), utilizing 1,000 suboptimal trees up to ﬁve steps longer (obtained through the traditional search). This approach provided a robust measure of support for various branches in the resulting cladogram.

Characters and their states (e.g., char. 25, state 1: [25:1]) or the transformation sequence (e.g., char. 25, state 0 to 1: [25:0–1]) are mentioned in the text if needed.

2.5. Nomenclatural act

Male and female specimens that were collected during mating in the field are hereby considered probable new species. Their placement within the subfamily Gripopteryginae is examined and tested. The new name presented herein conforms to the International Code of Zoological Nomenclature and has been registered in ZooBank, the ICZN’s online registration system.

3. Results

3.1. Morphological characters list

We studied the morphology of Gripopterygidae genera, focusing on the subfamily Gripopteryginae. As a result, we selected and encoded 22 nymphal morphological characters (characters 1–22) and 28 adult morphological characters (characters 23–50), reaching 50 characters. The list presented below includes characters proposed by Illies (1963) and McLellan (1977) for the subfamilies of Gripopterygidae.

Nymphs – Body and head (characters 1–4)

1 Body; setae: (0) small spine-like, (1) vesicular-like (Fig. 2A), (2) claviform-like (Fig. 2B), (3) hook-like (Fig. 2C). (In Froehlich 1969, 2001).

2 Body; debris covering surface: (0) absence, (1) presence. (In Illies 1963).

3 Head; antennae, ring of curved hair-like setae at least on antennae basal third: (0) absence, (1) presence.

4 Head; antennae, fringe of hair-like setae: (0) absence, (1) presence (Fig. 2D).

Figure 2.

Morphological characters used in phylogenetic analyses. A Guaranyperla guapiara, nymphal vesicular-like setae (left: antennae; right: pronotum); B Paragripopteryx klapaleki, nymphal claviform-like setae; C Tupiperla robusta, nymphal hook-like setae; D Notoperla magnaspina, head, pronotum, and prolegs in dorsal view, with details of the procoxal process and dense setae on the femur; E Gripopteryx liana, nymph habitus in lateral view, with detail of the pronotum processes; F Guaranyperla guapiara, head and pronotum, with details of the paranota and anterior projection; G–K Gripopterygidae sp., shape of the metanotum mid-distal margin; L Limnoperla jaffueli, pilosity on the nynphal hind femur; M, N Gripopterygidae sp., details of the tarsal setae and spur; O Gripopteryx cancellata, nymph habitus in lateral view, with details of the abdominal processes and anal gills; P Gripopteryx liana, nymph end of abdomen, with detail of the paraproct shape; Q Tupiperla sp., detail of the femoral spine; R Tupiperla furcata, sp. nov., hindleg with femoral spine; S Guaranyperla barbosai, terminalia in dorsal view; T, U Ericiataperla puerilis, terminalia in dorsal and lateral views; V Guaranyperla barbosai, terminalia in lateral view. (Figs A, B, E, O, P modified from Froehlich (1969, 1990, 1993, 2001); Fig. L modified from McLellan and Zwick (2007); Figs T–U modified from Pessacq et al. (2020)).

Nymphs – Thorax (characters 5–12)

5 Pronotum; surface, cuticle structure: (0) smooth (without small processes), (1) with small spine-like processes or elevations (Fig. 2E). (In Illies 1963).

6 Pronotum; anterior corners, shape: (0) corners rounded, (1) corners angulated, (2) corners with strong spines, (3) corners with strong projection (Fig. 2F and Fig. 3A).

7 Pronotum; lateral margin, extension (paranota): (0) absence, (1) presence (Fig. 2F). (In Froehlich 2001).

8 Metanotum; mid-distal margin (between wing pads), shape: (0) circular, concave (Fig. 2G), (1) circular, convex (Fig. 2H), (2) angular excised (pyramid-shaped) (Fig. 2I), (3) angular (V-shaped) (Fig. 2J), (4) straight, (5) bilobated (W-shaped) (Fig. 2K).

9 Coxa; procoxal process: (0) absence, (1) presence (Fig. 2D). (In McLellan et al. 2005).

10 Femur; extensor margin, fringe of hair-like setae, shape: (0) absence, (1) very dense fringe of hair-like setae (Fig. 2D), (2) sparse fringe of hair-like setae. (In Illies 1963; McLellan 1977).

11 Femur; extensor margin, small spine-like setae: (0) absence, (1) presence (Fig. 2L).

12 Tarsus; ventral surface of the third tarsal segment, type of setae: (0) setiform, small, thin setae (Fig. 2M), (1) thick, hair-like setae (Fig. 2N). (In McLellan and Zwick 2007).

Nymphs – Abdomen (characters 13–22)

13 Abdomen, segments 4 to 9, constriction: (0) unconstrained, sides approximately parallel, (1) constrained on its middle section, (2) unconstrained, sides not parallel, segment thicker on its apical section.

14 Abdomen; terga 1–9, row of mid-dorsal hair-like setae: (0) absence, (1) presence.

15 Abdomen; terga 1–9, row of mid-dorsal processes/spines: (0) absence, (1) one row (Fig. 2O), (2) two rows (Fig. 3B, C). (In Illies 1963).

Figure 3.

Neopentura semifusca. A Nymph head and pronotum in dorsal view, with details of the anterior corners. B Nymph hind leg in lateral view, with details of the hair-like setae on the tarsal segment. C Nymph thorax and abdomen in lateral view, with details of the abdominal spine-like processes, paraprocts, and anal gills. D Adult male forewing. Abbreviations: CuA, anterior cubitus; M, media; RP, posterior radius.

16 Abdomen; distal margin of terga 1–10, type of setae: (0) setiform, small, thin setae, (1) setiform, stout setae, (2) spine-like setae, (3) claviform-like setae, (4) vesicular-like setae, (5) long, hair-like setae.

17 Abdomen; tergum 10, shape of distal margin: (0) curved, (1) trapezoidal, (2) triangular, (3) acuminated.

18 Abdomen; anal gills: (0) absence, (1) presence (Fig. 2O).

19 Abdomen; modified terminal structures (paraprocts) for breathing: (0) absence, (1) presence. (In McLellan 2001b).

20 Paraprocts; distal region (apex): (0) rounded (Fig. 2P), (1) with a long spine (Fig. 3C), (2) acute. (In Vera 2006a; Vera 2009).

21 Cerci; cercomeres, ring of small distal setae: (0) absence or weakly developed, (1) presence.

22 Cerci; long hair-like setae, shape: (0) absence, (1) scattered arrangement, (2) fringed arrangement.

Adults male and female – Head (characters 23–24)

23 Ocelli: (0) absence, (1) presence.

24 Head; maxillary palp, size of the fifth segment relative to the third: (0) subequal (nearly equal), (1) two times longer or more. (In Vera 2009).

Adults male and female – Thorax (characters 25–37)

25 Wing; state: (0) apterous, (1) micropterous or brachypterous recorded in male or female, (2) macropterous (Fig. 5C). In some widespread Patagonian species, micropterism or brachyperism is common and variable through the distributional range; we codify it as state 1 if the character state has been recorded in at least a few specimens. Some widespread species are always macropterous (Pessacq & Duarte pers. obs., but also see Illies, 1963).

26 Wing; fore and hind wing pigmentation patterns: (0) both wings unpigmented (Fig. 5C), (1) forewing pigmentation, hind wing unpigmented, (2) both wings pigmented. — Character not applicable to taxa with state 0 in character 25.

27 Forewing; crossveins between C and Sc, number: (0) one crossvein (Fig. 5C), (1) more than one crossvein (Fig. 3D). — Character not applicable to taxa with state 0 in character 25.

28 Forewing; pterostigmatic cell, crossveins: (0) absence (Fig. 5C), (1) presence. (In Illies 1963; Froehlich 1969; McLellan 1977). — Character not applicable to taxa with state 0 in character 25.

29 Forewing; RP vein, shape: (0) unforked, (1) one fork (Fig. 5C), (2) two forks. (In Illies 1963; McLellan 1977). — Character not applicable to taxa with state 0 in character 25.

30 Forewing; anterior fork of RP vein relative to RA: (0) anterior fork of RP vein not connected to RA (Fig. 5C), (1) anterior fork of RP vein connected to RA. (In Froehlich 1969; Vera 2016). — Character not applicable to taxa with state 0 in character 29.

31 Forewing; CuA vein, shape: (0) unforked, (1) one fork (Fig. 5C), (2) two forks. (In Froehlich 1969; McLellan 1977). — Character not applicable to taxa with state 0 in character 25.

32 Hind wing; inferior branch of the M vein relative to CuA vein, shape: (0) unfused, (1) partially fused, separating near the wing margin (Fig. 5C), (2) completely fused. (In McLellan 1977).

33 Hind wing; sixth anal vein, shape: (0) sixth anal vein free of wing margin, (1) sixth anal vein fused to wing margin (Fig. 5C). (In McLellan 1977).

34 Femur; flexor margin, distal spine: (0) absence, (1) presence (Fig. 2Q, R). (In Froehlich 1969; Froehlich 2001).

35 Tibia; distoventral region, spurs: (0) absence, (1) presence (Fig. 2R). (In Froehlich 1969; McLellan 1977).

36 Tarsus; basal tarsal segment relative to apical segment: (0) basal segment as one-third of the length of the apical segment, (1) basal segment as half the length of the apical segment (Fig. 2R), (2) basal segment about as long as the apical segment. (In Illies 1963; Vera 2016).

37 Tarsus; ventral side of the basal segment, narrow membranous band: (0) absence, (1) presence. (In Vera 2009).

Adult male – Abdomen (characters 38–50)

38 Abdomen; tergum 10, anterior sclerites with oval tubercles: (0) absence, (1) presence.

39 Abdomen; tergum 10, anterior sclerites, fusion (inner margin): (0) completely or partially (at least its anterior half) fused, (1) touching at a small point or separated by a narrow membrane. (In Pessacq et al. 2020).

40 Abdomen; tergum 10, anterior sclerites relative to central sclerite: (0) completely fused with central sclerite (Fig. 2S and Fig. 5D), (1) separated from central sclerite by a suture, (2) partially fused with central sclerite, with a narrow lateral cleft (considering fusion of central and lateral sclerites), (3) separated from the central sclerite by a membrane (Fig. 2T).

41 Abdomen; tergum 10, central sclerite, distal margin, shape: (0) not protruding, (1) protruding in a simple lobe, (2) protruding with lobe divided in two parts (Fig. 5D).

42 Abdomen; tergum 10, central sclerite, denticles/teeth at the distal margin: (0) absence, (1) one denticle, (2) two denticles (Fig. 5D–F).

43 Abdomen; tergum 10, posterior sclerite clearly differentiated, base surrounded by a membrane: (0) absence (posterior sclerite fused to central sclerite), (1) presence (Fig. 2U). (In Illies 1963; McLellan 1977).

44 Abdomen; posterior sclerite, shape: (0) small spine/knob, (1) elongated, digitiform, (2) large, rounded, (3) small, rounded. — Character not applicable to taxa with state 0 in character 43.

45 Abdomen; posterior sclerite, position: (0) apical, (1) ventral. — Character not applicable to taxa with state 0 in character 43.

46 Abdomen; epiproct with a ventral sclerotized projection: (0) absence (Fig. 2V and Fig. 5E, F), (1) presence (Fig. 2U).

47 Abdomen; epiproct, shape: (0) concave, spoon-shaped, (1) flat, tip projected ventrally, (2) digitiform, curved, (3) digitiform, straight, with a wide base. (In Illies 1963). — Character not applicable to taxa with state 0 in character 46.

48 Abdomen; epiproct, lobe in the ventro-basal region: (0) absence, (1) presence. (In Illies 1963). — Character not applicable to taxa with state 0 in character 47.

49 Abdomen; epiproct, keel in the ventro-basal region: (0) absence, (1) presence. — Character not applicable to taxa with state 0 in character 46.

50 Abdomen; epiproct, inner surface, number of denticle rows: (0) absence, (1) one row of denticles, (2) two rows of denticles. — Character not applicable to taxa with state 0 in character 46.

3.2. Morphological phylogeny

The analyses conducted produced different consensus topologies based on the methods applied: (1) equal weighting (EW) (Fig. S1) and (2) implied weighting (IW) with varying k values (k = 3, 5, 7, 9, 11, 13, 15) (Fig. 4 and Figs S2–S3). As expected, and mentioned in section 2.4, the EW analysis resulted in a fully polytomous consensus topology based on 10 most parsimonious trees (MPTs) and will be no further discussed.

Figure 4.

Phylogenetic relationships among Gripopterygidae subfamily taxa. Strict consensus tree (implied weighting, k = 9.60936; consistency index = 0.371; retention index = 0.677) based on 27 most parsimonious trees. Relative Bremer support values are indicated in gray below the clades.

In contrast, the IW analyses consistently outperformed EW, recovering four well-resolved consensus topologies across the evaluated k values: k = 3, with a consensus of 66 trees; k = 5, with 27 trees; k = 7, with 9 trees; and k = 9–15, with 27 trees. For the dataset being studied in TNT, k = 9.60936 was the possible optimal k value. For this value, the consensus topology was like that of k = 9–15.

The general structure of the consensus topologies and the synapomorphies regarding Gripopteryginae taxa stayed constant, despite slight differences in the relationships between some of the taxa. K values between 9 and 15 resulted in identical topologies and synapomorphies (Fig. 4), a k value of 7 resulted in a slightly different tree (i.e. Neopentura semifusca appears in a clade together with Pehuenioperla llaima instead of a politomy, see Fig. 4 and Fig. S3), while k values of 3 and 5 resulted in completely different topologies, but with a monophyletic Gripopteryginae. From this point onward, the results will be based on the k values ranging from 7 to 15, reinforcing this decision with the optimal k value obtained with TNT (k = 9.60936). For the same reason, discussion will be based on the results obtained with k = 9.60936. However, the trees resulting from analyses with the remaining k values can be consulted in Figs S2–S3.

3.3. Family Gripopterygidae and Subfamily Arrangements

The morphological phylogenetic analyses of Gripopterygidae consistently yielded the family as monophyletic across all weighting schemes (for Relative Bremer support, see Fig. 4). Five synapomorphies supported this classification (e.g., [18:1], nymphal stage with abdominal anal gills; [19:0], nymph without terminal structures (paraprocts) modified for breathing; [32:1], adult hind wing with inferior branch of the M vein partially fused to the CuA vein and separating near the wing margin; [36:2], adult basal tarsal segment about as long as the apical segment; and [49:0], absence of keel in the ventro-basal region of epiproct) (Fig. 4).

The subfamily Gripopteryginae (Clade A, Fig. 4) was recovered as polyphyletic due to the inclusion of Neopentura semifusca Illies, 1965 (a genus whose position has been uncertain since its description, as will be discussed later) outside the subfamily’s delimitation. The remaining Gripopteryginae taxa consistently formed a clade (Clade A, Fig. 4), supported by distinct synapomorphies. For k = 9.60936 (and similarly for k = 9–15), the following characters states supported the clade: the forewing CuA vein with one fork [31:1]; the sixth anal vein of the hind wing fused to the wing margin [33:1]; a simple, protruding lobe on the distal margin of the central sclerite in tergum 10 [41:1]; and the absence of a posterior sclerite in tergum 10 [43:0] (Fig. 4).

The inclusion of Neopentura semifusca (a species currently classified in Gripopteryginae) along with the clade of Antarctoperlinae resulted in the subfamily being consistently paraphyletic. For k = 9.60936, Neopentura semifusca (Fig. 4) appeared in a polytomy with Pehuenioperla llaima Vera, 2009 (a typical Antarctoperlinae) and the remaining Antarctoperlinae taxa, while under k = 7, it appeared as the sister to Pehuenioperla llaima (Fig. S3). The synapomorphies that supported the clade are: the absence of a fringe of hair-like setae on the nymphal extensor margin of the femur [10:0]; the presence of thick, hair-like setae on the ventral surface of the third tarsal segment [12:1]; the presence of a long spine on the distal region (apex) of the nymphal paraprocts [20:1]; the absence or weak development of a ring of small distal setae on the nymphal cercomeres [21:0]; the absence of spurs in the tibia distoventral region [35:0]; and a simple, protruding lobe on the distal margin of the central sclerite in tergum 10 [41:1] (Fig. 4).

Dinotoperlinae and Leptoperlinae (sensu McLellan 1977) were consistently recovered as polyphyletic. Regarding Dinotoperlinae, Trinotoperla irrorata Tillyard, 1924, appeared at the base of Gripopterygidae, while Dinotoperla serricauda Kimmins, 1951, and Alfonsoperla flinti McLellan & Zwick, 2007, were recovered in a polytomy (Figs 4, S3).

Leptoperlinae also appeared as polyphyletic, divided in three different and separated clades. Newmanoperla thoreyi (Banks, 1920) was consistently grouped with Notoperla species, supported by [4:1], the presence of a fringe of hair-like setae on the nymphal antennae; [16:1], the presence of a row of mid-dorsal hair-like setae on nymphal terga 1–9; and [40:2], the partial fusion of anterior sclerites of tergum 10 with the central sclerite, forming a narrow lateral cleft. Cardioperla nigrifrons (Kimmins, 1951) and Leptoperla varia Kimmins, 1951, formed a clade supported by [1:3], hook-like body setae in nymphs; and [32:2], complete fusion of the inferior branch of the M vein to the CuA vein in the adult hind wing (Fig. 4). Riekoperla perkinsi Theischinger, 1985, clustered with Senzilloides panguipullii (Navás, 1928), supported by [10:2], sparse fringe of hair-like setae on the extensor margin of the nymphal femur; [15:1], presence of a row of mid-dorsal processes or spines on nymphal terga 1–9; [40:2]; and [47:3], digitiform, straight adult epiproct with a wide base.

Finally, Notoperlopsis femina Illies, 1963, the sole representative of Zelandoperlinae included in this study, was consistently recovered as the sister group to Gripopteryginae. The synapomorphies supporting this clade are as follows: [10:0], absence of hair-like setae on the extensor margin of the femur; [16:0], presence of setiform, small, thin setae on the distal margin of terga 1–10; [36:1], the basal tarsal segment being half the length of the apical segment; [39:0], complete or partial (at least anterior half) fusion of the anterior sclerites of tergum 10; and [40:0], complete fusion of the anterior sclerites with the central sclerite of tergum 10.

3.4. Subfamily Gripopteryginae

The topology of all analyses remained identical across analyses with k values between 7–15 (Fig. 4). With the exception of Paragripopteryx, remaining genera included with more than one species appeared as monophyletic.

The main synapomorphies for the main clades are (for detailed synapomorphies for all clades see Fig. 4):

Clade B: Uncicauda testacea (Vera, 2006b) is sister to Limnoperla jaffueli (Navás, 1928), supported by [42:1], adult tergum 10 central sclerite with one denticle/tooth at the distal margin (Fig. 4).

Clade C: This large clade includes most Gripopteryginae, and is supported by [10:2], nymphal extensor margin of femur with a sparse fringe of hair-like setae; and [49:0], epiproct without a keel in the ventro-basal region.

Clade D: This clade forms a politomy, is sister of Teutoperla maulina and supported by four synapomorphies: [41:2], central sclerite of tergum 10, protruding, with lobe divided in two parts; [42:2], tergum 10, central sclerite, with two denticles; [47:2], epiproct digitiform, curved; and [50:1], epiproct inner surface with one row of denticles.

Clade E: This clade includes four genera and is supported by the following synapomorphies: [1:2], body with claviform-like setae; [11:1], femur extensor margin with small spine-like setae; and [16:3], distal margin of terga 1–10 with claviform-like setae. Within this grouping, Clade F, which includes Aubertoperla illiesi (Andean-Patagonian) and Gripopteryx species (Neotropical), is supported by [41:0], central sclerite of tergum 10 with a non-protruding distal margin. Clade H, comprising Rhitroperla rossi (Froehlich, 1960) (Andean-Patagonian) and Paragripopteryx species (Neotropical), is supported by [26:0], both wings unpigmented.

Clade J: This clade is supported by the following synapomorphies: [46:0], absence of a ventral sclerotized projection on the epiproct. It includes, in a polytomy, the Andean-Patagonian genera Andiperla, Andiperlodes, and Potamoperla, as well as the Neotropical genera Guaranyperla and Tupiperla, which together form a separate clade (L) (Fig. 4).

Clade L: Tupiperla species grouped with Guaranyperla species, supported by the following characters: [1:3], body setae hook-like; [8:0], nymphal metanotum mid-distal margin with a circular, concave shape; [17:2], distal margin of tergum 10 triangular; and [34:1], presence of a distal spine on the flexor margin of the femur (Fig. 4 and Figs S2–S3). Within this grouping, the analyses placed the new species in an unresolved polytomy with other Tupiperla species, while Guaranyperla species emerged as close relatives (Fig. 4). A detailed description is provided below.

3.5. Systematics

Class Insecta Linnaeus, 1758

Order Plecoptera Burmeister, 1839

Family Gripopterygidae Enderlein, 1909

Subfamily Gripopteryginae Enderlein, 1909

Genus Tupiperla Froehlich, 1969

Paragripopteryx Illies, 1963 (nec Enderlein 1909): 178.

Tupiperla Froehlich, 1969: 28 (Type species: Semblis gracilis Burmeister, 1839, by monotypy); McLellan 1977: 121 (in Gripopteryginae); Froehlich 1998: 34; Stark, Froehlich and Zuñiga 2009: 96; Froehlich 2010: 137; Duarte, Novaes and Bispo 2019: 513.

Type species.

Tupiperla gracilis (Burmeister, 1839).

Tupiperla furcata sp. nov.

https://zoobank.org/A5463D11-62F9-477D-843A-D7516414E5CE

Figure 5A–H

Type material.

Holotype: BRAZIL • 1 ♂; Santa Catarina State, Urubici, Parque Nacional São Joaquim; 28°09’20”S, 49°38’47”W; 1,500 m a.s.l.; 23.viii-05.ix.2014; Malaise trap; L.C. Pinho leg. (in MZUSP). Paratypes: same data as holotype, except for 1 ♀ (in MZUSP); 1 ♂, 1 ♀ (in CIACGF).

Figure 5.

Tupiperla furcata sp. nov. Holotype adult male. A head and pronotum in dorsal view. B Adult female, head and pronotum in dorsal view. C Male fore and hind wings. D–F Male terminalia in dorsal, ventral, and lateral views. G, H Female terminalia in ventral and ventro-lateral views. Abbreviations: AA1, first anterior analis; AA2, second anterior analis; CuA, anterior cubitus; CuP, posterior cubitus; M, media; PC, pterostigmatic cell; RA, anterior radius; RP, posterior radius; Sc, subcosta; St7, Sternum 7; St8, Sternum 8; St9, Sternum 9; T8, tergum 8; T9, tergum 9; T10, tergum 10; T10e, projection of the tergum 10 (extension). (Scale bar: 0.5 mm).

Measurements.

Holotype, ♂: head width, 1.1 mm; pronotum width, 1.1 mm; pronotum length, 1.1 mm; forewing length, 9.0 mm; hind wing length, 8.0 mm; antennae length, 9.0 mm; number of cercomeres, 16. Paratype, ♂ (n = 1): head width, 1.1 mm; pronotum width, 1.1 mm; pronotum length, 1.1 mm; forewing length, 8.5 mm; hind wing length, 7.5 mm; antennae length, 7.8 mm; number of cercomeres, 13. Paratypes, ♀♀ (n = 2): head width, 1.2 mm; pronotum width, 1.2 mm; pronotum length, 1.2 mm; forewing length, 9.5–11.0 mm; hind wing length, 8.5–9.2 mm; antennae length, 8.5 mm (only one female); number of cercomeres, 14–15.

Diagnosis.

Tupiperla furcata sp. nov. is a medium-sized species with general coloration ranging from ochraceous to brownish. Males are characterized by elongated, deeply forked paraprocts and a large, bifurcated projection on tergum 10. Females possess a long subgenital plate with a deep medial notch.

Comparative diagnosis.

The new species, Tupiperla furcata sp. nov., is most similar to Tupiperla froehlichi Bispo & Lecci, 2011, based on the general structure of the male terminalia, particularly the paraprocts and tergum 10 (Fig. 5D–F). However, it can be distinguished from T. froehlichi and other congeners by the following combination of characters: In T. furcata sp. nov., the paraprocts form two thin, curved bars, while in T. froehlichi, a single bar-like projection is present. This bifurcation of the paraprocts is unique among known Tupiperla species. The posterior margin of tergum 10 in the new species has a swallowtail-like bifurcation (Fig. 5D–F), which resembles T. froehlichi, but differs in having a shorter, wider base and elongated lateral projections that are more sharply forked. In contrast, T. froehlichi shows a shallower indentation.

The female subgenital plate of T. furcata sp. nov. (Fig. 5G, H) is deeply notched and medially projected, a character not observed in any other described species of South American Gripopterygidae. These diagnostic features, in combination, clearly distinguish T. furcata sp. nov. from its congeners.

Description.

Holotype, adult MALE. Head: Brown with a lighter area between paired ocelli and two lighter bands from the lateral ocelli to the eyes, occiput surface rough (Fig. 5A, B). Ocelli and eyes black. Antenna brown, long, antennomeres covered with very small fine hair. — Mouthparts: Clypeus brown, labrum lighter shade of brown. Maxillary palps light brown, 5-segmented, first and fourth segments short, second, third, and fifth longer, fifth segment slightly darker than the others. Labial palps light brown, 3-segmented, the last segment slightly darker than the others. — Thorax: Pronotum square, brown, with rough surface and narrower than the head, corners slightly rounded. — Legs: Light brown to ochraceous. Legs with a large disto-ventral spine on femur, distal region of spine darker. Tibia with a perpendicular suture in the proximal region and with two spurs at the distal region. Tarsi light brown, fore- and mid-legs with first tarsomere medium, second tarsomere short, and third tarsomere long; hind leg with first and third tarsomeres subequal, long; second tarsomere short. — Wings: Forewing membranous light brown; inconspicuous darker pattern bordering veins and crossveins; pterostigmatic crossveins absent; RA unforked, RP forked; CuA long forked. Hind wing with M3+4, near its separation from M1+2, fused with CuA in part of its length, CuA short forked, sixth anal vein may be fused with hind margin of wing (Fig. 5C). — Male terminalia: Abdomen brownish to ochraceous with slightly clear band on abdominal terga 1–9. In dorsal view, tergum 10 ochraceous with clear band on the anterior region; projection of the tergum 10 brownish, large, swallowtail-like (Y-shaped), with short, wide base, and two elongated, sharply forked lateral projections, each ending in a downcurved tooth (Fig. 5D). In ventral view, paraprocts thin, directed to the projection of tergum 10. Subgenital plate ochraceous, triangular, with apex prolonged between the paraprocts (Fig. 5E). In lateral view, projection of tergum 10 curved ventrally, ending in two large teeth; paraprocts deeply forked from the last third, forming two thin bars; apex of the dorsal bar slightly upcurved, apex of the ventral bar slightly downcurved (Fig. 5F). Median sclerotized epiproct absent. — Adult FEMALE description. Same as male, except for: Abdomen: membranous; brownish to ochraceous with slightly clear band on abdominal terga and with abdominal sterna darker; sternum 7 with two small and inconspicuous sclerites; subgenital plate long, with base broadest, laterally projected, and apex reaching sternum 10; a deep U-shaped notch medially dividing the subgenital plate (Fig. 5G, H); paraprocts thin, long compared to the other congeners; apex truncated.

NYMPH.

Unknown.

Etymology.

The epithet “furcata” is derived from the Latin word “furcatus”, meaning “forked”. This refers to the forked shape of the paraprocts in males and the subgenital plate in females of this species.

Distribution.

São Joaquim National Park (PNSJ), Santa Catarina, southern Brazil.

General information about the type locality.

The PNSJ covers 49,800 hectares across five municipalities in Santa Catarina State: Urubici, Bom Jardim da Serra, Orleans, Grão Pará, and Lauro Müller. The park was established to protect Araucaria forests (Araucariaceae: Araucaria angustifolia (Bertol.) Kuntze) that were heavily logged in the mid-20th century (MMA 2011). Entirely within the Atlantic Forest biome, PNSJ is home to over 900 species of vascular plants, forming a diverse range of vegetation types, including ombrophilous forests, mixed ombrophilous forests, high-altitude fields, and cloud forests. Elevations in the park range from 300 m a.s.l. to its highest point, Morro da Igreja, at 1,820 m a.s.l. Despite a 2018 management plan, private land ownership within the park allows for some human activities, such as cattle ranching. Currently, the park is also an important tourism area in the Serra Catarinense, with Morro da Igreja providing a panoramic view of Pedra Furada as a key attraction (Lima et al. 2021). Given that Tupiperla furcata is found in a conservation priority area such as PNSJ, it is imperative that the protection of this region is maintained permanently.

Remarks.

While unresolved relationships persist within Tupiperla, the placement of Tupiperla furcata within the genus is strongly supported by both morphological and molecular evidence. The new species is excluded from Guaranyperla because it lacks key diagnostic morphological characters that are associated with adults of that genus, such as a relatively broad pronotum with remnants of projecting anterior corners, wings with reduced or absent RA forks, the presence of pterostigmatic crossveins, and a short projection of tergum 10 (Froehlich 2001, 2015). Additionally, genetic distances between new species and those with available sequences are further revealed by comparative analyses of COI sequences, which are consistent with species-level divergence within Tupiperla (Sarmento et al. 2025). Morphologically, the unique combination of diagnostic characters, particularly the forked paraprocts and subgenital plate, further distinguishes Tupiperla furcata from closely related taxa.

More molecular research using nuclear markers is necessary to more clearly determine the phylogenetic relationships within Tupiperla. Furthermore, the discovery and detailed study of the nymphal stage of Tupiperla furcata could provide valuable insights into its taxonomic placement, potentially revealing diagnostic characters of the genus Tupiperla rather than Guaranyperla.

4. Discussion

4.1. Redefinition of Gripopteryginae

Our findings revealed a polyphyletic Gripopteryginae, with Neopentura semifusca falling outside the clade, being more closely related to Antarctoperlinae taxa. In contrast, all remaining Gripopteryginae taxa were consistently recovered as a cohesive clade across all analyses (Fig. 4 and Figs S2–S3). These findings highlight the need for a re-evaluation of the taxonomic classification of Neopentura semifusca and bring light regarding the current arrangement of the Gripopteryginae subfamily.

The taxonomic history of Neopentura semifusca reflects its complex and controversial classification. Originally described by Illies (1965) within the family Penturoperlidae (currently Austroperlidae), the species was later reassigned by Illies (1969) to the family Gripopterygidae, specifically within Gripopteryginae (Vera 2006a). However, McLellan (1977), in his revision of Gripopterygidae subfamilies, excluded Neopentura from his classification. Subsequently, Vera (2006a), in his redescription of the genus, based on morphological characters, proposed a close relationship between Neopentura and the New Zealand genus Zelandobius (Antarctoperlinae); despite this, Neopentura was still categorized under Gripopteryginae by Froehlich (2010) in his Catalog of Neotropical Plecoptera.

Our results provide phylogenetic and additional morphological support for the closer relationship of Neopentura with Antarctoperlinae rather than with Gripopteryginae. The six synapomorphies provided in results, under Antarctoperlinae, placed Neopentura in a polytomy with Antarctoperlinae taxa (k = 9–15, Fig. 4) or in a clade with Pehuenioperla llaima (k = 7, Fig. S3).

This robust cladistic evidence, along with morphological evidence as previously suggested by Vera (2006a) and the characters defined by McLellan (1977), supports the hypothesis that Neopentura should be formally reclassified within Antarctoperlinae. This reclassification not only resolves the long-standing question regarding the placement of the genus but also strengthens the morphological coherence of Antarctoperlinae as a distinct clade within Gripopterygidae, as proposed by Pessacq et al. (2020). Therefore, Antarctoperlinae now includes the following genera: Antarctoperla, Araucanioperla, Ceratoperla, Chilenoperla, Ericiataperla, Megandiperla, Neopentura, Pehuenioperla, Pelurgoperla, and Plegoperla from South America, as well as Zelandobius from New Zealand.

4.2. Gripopteryginae (sensu stricto) and related taxa

Our analyses with k = 7–15, consistently recovered an identical Gripopteryginae clade (Clade A, Fig. 4) supported by four synapomorphies: the forewing CuA vein with one fork [31:1]; the sixth anal vein of the hind wing fused to the wing margin [33:1]; a simple, protruding lobe on the distal margin of the central sclerite in tergum 10 [41:1]; and the absence of a posterior sclerite in tergum 10 [43:0] (Fig. 4). None of these synapomorphies is exclusive, some are shared by other Gripopterygidae and some revert in some Gripopteryginae (see Fig. 4).

McLellan (1977, p. 120–121) proposed the absence of a posterior sclerite as a diagnostic character to synonymize the former subfamily Paragripopteryginae under Gripopteryginae and to establish Dinotoperlinae as a separate subfamily (some of its members also lack a posterior sclerite, e.g., Dinotoperla serricauda and Trinotoperla irrorata). The other diagnostic characters proposed by McLellan (1977) for Gripopteryginae and shared with other taxa were codified in our dataset (Table 1):

(i) [31:1], the CuA vein fork in the forewings, observed in most Gripopteryginae (except apterous species) and shared with some Dinotoperlinae taxa (e.g., Alfonsoperla flinti and Dinotoperla serricauda);

(ii) [33:1], hind wing’s sixth anal vein fused to the wing margin, identified as a synapomorphy for Gripopteryginae under k = 3 and k = 15, but also shared with some Australian Leptoperlinae taxa (e.g., Cardioperla nigrifrons, Newmanoperla thoreyi, and Riekoperla species);

(iii) [35:1], distoventral tibial spurs, observed in some Dinotoperlinae (e.g., Dinotoperla serricauda and Trinotoperla irrorata), and Leptoperlinae taxa (e.g., Cardioperla nigrifrons, Notoperla species, Riekoperla species, and Senzilloides panguipullii);

(iv) [in part 46:1], male genitalia with an unrecurved or absent epiproct tip, present in some Gripopteryginae genera.

In our analyses, four synapomorphies, including three characters used by McLellan (1977), consistently supported the monophyly of Gripopteryginae.

Our findings contrast with those of McCulloch et al. (2016), who, using molecular data (nuclear 18S, H3; mitochondrial COI), and including seven out of the fourteen Gripopteryginae genera, found no evidence supporting the monophyly of Gripopteryginae. Their results indicated significant polyphyly among Gripopteryginae taxa. For example, Tupiperla sp., Andiperla sp., and Aubertoperla sp. formed a clade with Australian Dinotoperlinae and Leptoperlinae. Similarly, Claudioperla tigrina was nested within the South American Antarctoperlinae. Other taxa, such as Gripopteryx sp., grouped with New Zealand Zelandoperlinae, while Limnoperla jaffueli and Teutoperla auberti clustered with Australian Leptoperla sp. (Leptoperlinae) (see fig. 3 in McCulloch et al. 2016).

Conversely, the morphological study by Pessacq et al. (2020) placed Gripopteryginae taxa within a clade containing Plegoperla punctata (Antarctoperlinae), a species with limited morphological detail available (Froehlich 1960; Illies 1963). However, their analyses focused solely on five Andean-Patagonian Gripopteryginae species and excluded Neotropical genera, limiting their conclusions.

Contrary to the conclusions of McCulloch et al. (2016) and Pessacq et al. (2020), our analyses, which include 13 out of the 14 currently recognized Gripopteryginae genera, provide morphological evidence supporting Gripopteryginae as a monophyletic clade, excluding Neopentura. These findings support the subfamily as established by Enderlein (1909) and later reinforced by McLellan’s (1977) review.

Although, in view of the conflicting results with McCulloch et al. (2016) and Pessacq et al. (2020), our own findings should be interpreted with caution, and they support a Gripopteryginae composed of the following taxa: Andiperla, Andiperlodes, Aubertoperla, Claudioperla, Falklandoperla, Gripopteryx, Guaranyperla, Limnoperla, Paragripopteryx, Potamoperla, Rhithroperla, Teutoperla, Tupiperla, and Uncicauda.

Regarding distribution, we found no clear biogeographic pattern: Neotropical and Andean-Patagonian taxa are intermixed, with the exception of the Neotropical genera Tupiperla and Guaranyperla, and the southern Andean taxa Andiperla and Andiperlodes, which nest together.

4.3. The Case of Paragripopteryx munoai

Duarte et al. (2022) highlighted that Paragripopteryx munoai did not cluster with other species of Paragripopteryx, suggesting it may represent a separate lineage. While the authors propose the potential need to establish a new genus and recognize Paragripopteryx as non-monophyletic in its current definition, they adopt a conservative approach, opting to await additional data before making taxonomic changes.

Morphologically, Paragripopteryx munoai differs from other Paragripopteryx species in several key characters: it lacks pterostigmatic crossveins in the forewings, has half-elliptical and shortened hind wings, and presents a W-shaped bilobed mid-distal margin on the metanotum in nymphs. Additionally, its femora and tibiae are bare, lacking the fringed setae typical of other species. The eggs are hemispherical and simple, in contrast to the elliptical eggs observed in related taxa.

Our study positioned Paragripopteryx munoai in an uncertain phylogenetic relationship relative to Paragripopteryx species analyzed, which suggests that the species may not belong within Paragripopteryx as currently circumscribed. As such, Paragripopteryx munoai represents a challenge, particularly due to its limited sampling and subtle morphological variation.

The collection of fresh specimens, especially from the type locality and surrounding regions, should be prioritize to enable molecular analyses and detailed comparisons with other Paragripopteryx species and closely related genera. High-resolution imaging of morphological structures, particularly male terminalia and egg morphology, may also aid in clarifying the boundaries of the genus. Additionally, expanded taxon sampling in phylogenetic analyses could help determine whether Paragripopteryx munoai forms an early-diverging lineage within Paragripopteryx, clusters with another genus, or warrants generic status on its own.

4.4. Polyphyly in Leptoperlinae and Dinotoperlinae

Our findings, along with those of McCulloch et al. (2016), reveal that the subfamilies Leptoperlinae and Dinotoperlinae are consistently polyphyletic, challenging their traditional classifications within Gripopterygidae. Additionally, Notoperlopsis femina (Zelandoperlinae), the sole representative of its subfamily in our study, showed a closer phylogenetic affinity with Gripopteryginae. However, due to limited sampling, its broader subfamily relationships remain inconclusive, no material from the remaining representatives of the subfamily was available to us.

We studied seven Leptoperlinae taxa (six out of the seven recognized genera). Our analyses clearly render the subfamily polyphyletic (Fig. 4). McCulloch et al. (2016) analyzed all Leptoperlinae genera and also recovered the subfamily as polyphyletic. In their study, Senzilloides panguipullii clustered with a group containing Dinotoperlinae taxa, Cardioperla (Leptoperlinae), and Tupiperla sp. (Gripopteryginae). Similarly, Pessacq et al. (2020) identified Senzilloides panguipullii as sister to a paraphyletic Gripopteryginae, although their study included only one Leptoperlinae species.

Our results also recovered Dinotoperlinae as polyphyletic and positioned at the base of the tree (Fig. 4). However, our sampling of only three of ten genera of the subfamily warrants a cautious interpretation. Although McLellan (1977) proposed the subfamily Dinotoperlinae based on members of Gripopteryginae and shares several characteristics with that family (Table 1), including the absence of the posterior sclerite, our findings indicate a distant relationship between them. These results partially contrast with those of McCulloch et al. (2016), who also recovered Dinotoperlinae as polyphyletic, analyzing 10 taxa from seven of the ten recognized genera. In their study, some dinotoperline taxa appeared closely related to Gripopteryginae, such as Dundundra sp. + Tupiperla sp. and Alfonsoperla flinti + Aubertoperla sp. Our analyses, however, left the relationships within the subfamily unresolved due to the inclusion of only three dinotoperline taxa.

One remarkable result of our study is that Trinotoperla irrorata consistently appeared in the first cladogenesis of Gripopterygidae, indicating an early divergence (Fig. 4). Similarly, Pessacq et al. (2020), who included five Dinotoperlinae taxa in their cladistic analysis, recovered Trinotoperla irrorata clustered with Vesicaperla kuscheli (Antarctoperlinae), further supporting a polyphyletic arrangement of Dinotoperlinae. However, Vesicaperla kuscheli was not included in our analysis.

Historically, Dinotoperlinae has been defined by a combination of morphological characters, including the absence of a posterior sclerite on tergum 10, the presence of a long CuA fork in the forewing, and the sixth anal vein of the hind wing free from the wing margin (McLellan 1977). However, taxa such as Alfonsoperla flinti, which possesses a posterior sclerite, challenge these traits as reliable synapomorphies, casting clear doubt on the monophyly of the subfamily.

The phylogenetic placement of taxa across these subfamilies highlights the need for revised classifications. Both Leptoperlinae and Dinotoperlinae may require redefinition or even division into more cohesive units. Achieving this will be necessary to expand samples of taxa to obtain a more comprehensive understanding of these subfamilies. In addition, the morphological characters traditionally used to define subfamilies should be complemented with molecular and biogeographic data to support robust phylogenetic analyses.

5. Conclusions and Future Directions

Our morphological data indicate that many characters previously considered diagnostic may represent true synapomorphies. The monophyly of Gripopteryginae was supported (with the exclusion of the genus Neopentura), whose defining characteristic is the forewing CuA vein with one fork; the sixth anal vein of the hind wing fused to the wing margin; a simple, protruding lobe on the distal margin of the central sclerite in tergum 10; and the absence of a posterior sclerite on tergum 10. However, our study also suggests the presence of some degree of homoplasy in the aforementioned characters, as none was exclusive to Gripopteryginae.

Given the incongruence with previous studies, particularly that of McCulloch et al. (2016), the results should be interpreted with caution. In future work, a combined analysis of morphological and molecular characters would be desirable.

Our analysis also suggests that Neopentura semifusca is more closely aligned with Antarctoperlinae than with Gripopteryginae, based on strong morphological evidence. To refine this placement further, future studies should incorporate Zelandobius species, as prior research proposed this genus as a sister to Neopentura (Vera 2006a).

Although McCulloch et al. (2016) and Letsch et al. (2021) recovered Antarctoperlinae as paraphyletic, our novel dataset provides new evidence supporting its monophyly. These findings align with the redefinition of the subfamily by Pessacq et al. (2020). McCulloch et al. (2016) hypothesized that the divergence between South American and Australian taxa within Gripopterygidae coincided with the opening of the Drake Passage (~41 Mya, Oligocene), a major biogeographic event that likely contributed to the disjunction between the South American and Australian continents. Letsch et al. (2021) expanded on this hypothesis, suggesting that both vicariance (e.g., continental drift) and recent long-distance dispersal mechanisms played roles in the diversification of Gripopterygidae across Gondwanan landmasses. This expanded hypothesis emphasizes the need to consider dispersal as a key driver in shaping the distribution of these taxa. The biogeographical disjunction observed in South American taxa, particularly within Gripopteryginae, remains a fascinating avenue for further exploration.

The polyphyletic patterns found in some subfamilies suggest substantial taxonomic revisions are necessary, particularly for South American genera like Senzilloides panguipullii and Notoperlopsis femina. On the other hand, the discovery of Tupiperla furcata shows us that the taxonomic diversity of Gripopterygidae still has a lot to be unraveled.

Future studies should focus on expanding taxon sampling throughout the Southern Hemisphere as well as integrating molecular and morphological data to provide a more comprehensive view of phylogenetic relationships.

6. Declarations

Authors’ contributions. Conceptualization, validation, investigation, data curation, methodology, formal analysis, writing—original draft preparation, writing—review and editing, project administration, T.D., P.C.B., and P.P. All authors have read and agreed to the published version of the manuscript.

Competing interests. The authors declare that they have no conflicts of interest in relation to this work.

Ethical aspects. There are no ethical notes or aspects to declare.

Permissions. There are no permissions to declare.

7. Acknowledgements

The authors thank Dr. Luiz Carlos de Pinho (Universidade Federal de Santa Catarina; FAPESC 11323/2012–9 and PIBIC program grant), who generously donated the material of Tupiperla furcata. We thank Dr. Arnold Staniczek (Stuttgart State Museum of Natural History, Germany), for facilitating access to Australian species. We also thank Dr. Rhainer Guillermo-Ferreira (Universidade Federal do Triângulo Mineiro), Dr. Marcos C. Novaes (Universidade de São Paulo), Dr. Frederico F. Salles (Universidade Federal de Viçosa), and Dr. Claudio G. Froehlich posthumously (Universidade de São Paulo) for their valuable contributions to the early draft of this manuscript. We acknowledge the anonymous reviewer for constructive comments that improved the quality of the paper. T.D. thanks the Fundação de Amparo à Pesquisa do Estado de São Paulo, Brazil (FAPESP, grants 2015/11580-3 and 2016/22213-4), the Consejo Nacional de Investigaciones Científicas y Técnicas, Argentina (CONICET, RESOL-2022-788-APN-DIR#CONICET), and Universidade Estadual de Santa Cruz (UESC/PROBOL). P.C.B. thanks FAPESP (grants 2019/22833-0 and BIOTA 2021/05986-8) and the Conselho Nacional de Desenvolvimento Científico e Tecnológico, Brazil (CNPq, grants 306400/2022-7 and PROTAX 441119/2020-4). P.P. thanks CONICET (PIP CONICET 11220200102559CO 2021-2023, Res-2021-1639), Darwin Initiative Project (Natural History Museum, London, UK, 2006–2009), and the Agencia Nacional de Promoción de la Investigación, el Desarrollo Tecnológico y la Innovación, Argentina (FONCYT, PICT-2011-1397).

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Supplementary materials

Supplementary material 1

File S1

Duarte T, Bispo PC, Pessacq P (2025)

Data type: .pdf

Explanation notes: Abstract and keywords of the article.

This dataset is made available under the Open Database License (http://opendatacommons.org/licenses/odbl/1.0). The Open Database License (ODbL) is a license agreement intended to allow users to freely share, modify, and use this dataset while maintaining this same freedom for others, provided that the original source and author(s) are credited.

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Supplementary material 2

Figures S1–S3

Duarte T, Bispo PC, Pessacq P (2025)

Data type: .pdf

Explanation notes: Figure S1. Phylogenetic relationships among Gripopterygidae subfamily taxa. A strict consensus topology from equal weighting analysis based on 10 most parsimonious trees. – Figure S2. Phylogenetic relationships among Gripopterygidae subfamily taxa. A strict consensus topology from implied weighting analysis (k = 3), based on 66 most parsimonious trees. – Figure S3. Phylogenetic relationships among Gripopterygidae subfamily taxa. A strict consensus topology from implied weighting analysis (k = 5), based on 27 most parsimonious trees. – Figure S3. Phylogenetic relationships among Gripopterygidae subfamily taxa. A strict consensus topology from implied weighting analysis (k = 7), based on 9 most parsimonious trees.

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Supplementary material 3

Table S1

Duarte T, Bispo PC, Pessacq P (2025)

Data type: .pdf

Explanation notes: Table S1. Morphological character matrix for Gripopteryginae species used in cladistic analysis. The dataset comprises 50 characters, with states assigned for each species. Ingroup species from 22 to 41. Characters 1–22 are nymphal traits, and characters 23–50 are adult traits. Symbols: “–” indicates inapplicable characters, and “?” denotes missing or unobserved data. Color coding: Neotropical genera are highlighted in green, Andean genera are in blue, Andean-S.A. Transition Zone in aquamarine, and Australian genera are in yellow.

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