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Article

Chilean Darwin Wasps (Ichneumonidae): Biogeographic Relationships and Distribution Patterns

by
Diego G. Pádua
1,
Andrés Moreira-Muñoz
2,
Vanezza Morales-Fierro
3,4 and
Rodrigo O. Araujo
1,*
1
Laboratorio de Entomología General y Aplicada, Centro de Investigación de Estudios Avanzados del Maule, Universidad Católica del Maule, Avenida San Miguel, 3605, Talca 3460000, Chile
2
Instituto de Geografía, Pontificia Universidad Católica de Valparaíso, Avenida Brasil, 2241, Valparaíso 2340025, Chile
3
Herbario EIF & Laboratorio de Evolución y Sistemática, Facultad de Ciencias Forestales y de la Conservación de la Naturaleza, Universidad de Chile, Av. Santa Rosa, 11315, La Pintana, Santiago 8820808, Chile
4
Museo Nacional de Historia Natural, Interior Quinta Normal, s/n, Santiago 8350410, Chile
*
Author to whom correspondence should be addressed.
Insects 2024, 15(6), 415; https://doi.org/10.3390/insects15060415
Submission received: 6 March 2024 / Revised: 27 May 2024 / Accepted: 28 May 2024 / Published: 4 June 2024
(This article belongs to the Collection Hymenoptera: Biology, Taxonomy and Integrated Management)
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Abstract

:

Simple Summary

The global biodiversity crisis poses many challenges for humanity, and continuing to classify and gain knowledge of the “hidden biodiversity” of less studied groups considered hyper-diverse insect groups, such as the parasitoid wasp (Ichneumonidae), is one of them. There is a particular need for more taxonomic and distributional knowledge of the Neotropics and its neighboring regions. We assessed the current knowledge of the Ichneumonidae, otherwise known as Darwin wasps, in Chile, a country with a diverse ecogeographic gradient, from the southern cold and humid tip of South America approaching the Antarctic Circle to the arid Atacama beyond the Tropic of Capricorn. Following the most up-to-date taxonomic knowledge, we assessed biogeographic relationships at the genus level and the spatial patterns of biodiversity at the species and genera levels along the latitudinal gradient. The results show that biogeographic relationships are based on six faunistic elements (cosmopolitan; endemic; Neotropical; Holarctic–Oriental; south-temperate; and Australasian), reinforcing the early view of two different areas for Chilean ichneumonids: a northern province and a Neantarctic realm, with a high percentage of endemic genera and species. Spatial biodiversity patterns assessed at different scales show a bimodal distribution of richness: around 34° and 38° S in the Metropolitan and Araucanía Regions. From an ecoregional perspective, richness is concentrated in the Valdivian temperate forests, but when assessed at a 0.5 × 0.5 cell scale, several outstanding cells are in the contact zone between the temperate forests and the Chilean Matorral in the Central Chilean biodiversity hotspot. Interpreting richness involves two phenomena difficult to disentangle: genuine species diversity and collection bias closer to areas with larger human populations. In contrast, the Atacama Desert shows little or no presence of Darwin wasps, which is to be expected due to the lack of potential hosts. These results reinforce the need to continue sampling and studying available collections to help close the knowledge gaps already recognized as Wallacean and Linnean shortfalls in order to gain additional information on potential threats to endemic genera and species.

Abstract

Ichneumonidae, or Chilean Darwin wasps, are an important component of South American hymenopteran diversity, but the taxonomic and distributional knowledge on this insect is still deficient. Taking advantage of recently updated taxonomic knowledge, we assessed biogeographic relationships at the genus level and biodiversity spatial patterns along the latitudinal gradient. The results show the presence of 264 species in Chile, arranged in 102 genera and 22 subfamilies. Biogeographic relationships are based on six elements (cosmopolitan (n = 50; 36%), endemic (n = 29; 21%), Neotropical (n = 22; 16%), Holarctic–Oriental (n = 19; 14%), south-temperate (n = 16; 11%) and Australasian) and composed of just three genera: Anacis, Labena, and Meringops. Species and genera show a bimodal distribution along the latitudinal gradient: around 34° and 38° S. From an ecoregional perspective, richness is concentrated in the Valdivian temperate forests, but when assessed at a 0.5 × 0.5 cell scale, several outstanding cells are in the contact zone between the temperate forests and the Chilean Matorral. On the other hand, the Atacama Desert shows little or no presence of Darwin wasps. The results agree with Charles Porter, who identified a northern province composed of Neotropical and cosmopolitan genera with their own representatives in the far north (11 genera), a distributional gap in the core of the Atacama Desert, and around 128 genera in Porter’s Neantarctic realm, covering all of Chile from 25° S to Cape Horn, including the Juan Fernandez islands. These results reinforce knowledge gaps and the need for more sampling and studies of available collections. Due to sampling gaps at this stage, identifying a continued increase or decrease in richness towards higher latitudes is not possible. More taxonomic and distributional information is also needed to assess potential threats to endemic genera and species.

1. Introduction

If we take a close look at the bark of a tree in a subtropical forest, we will have a high likelihood of finding a Darwin wasp (Ichneumonidae) (Figure 1) in the struggle to secure a host for its eggs. Ichneumonidae are parasitoid wasps, a major component of global biodiversity, and at the same time a poorly studied group [1]. They comprise the most speciose group of Hymenoptera (one of the most species-rich orders on Earth), participate in a wide range of ecological processes, and provide humanity with essential ecosystem services [2]. Nevertheless, there are various impediments to improving our knowledge of the diversity and functional roles of parasitoid wasps, such as the Linnean shortfall (most species have not been described) and Wallacean shortfall (the distribution of many described species is unknown) [3].
These various impediments have dramatic consequences for insect conservation [4,5], especially actions to protect and manage so-called “hidden biodiversity” [6], and apply especially to (a) laboriously identifiable species; (b) those with unknown socio-economic potential; and (c) those which can only be collected in areas difficult to access [7]. The knowledge gaps related to parasitoid wasps and their systematic underestimation “biases our understanding of multi-trophic tropical interactions and determination of large-scale biodiversity patterns” [7] (p. 4697).
The lack of specialized entomologists and accurate, standardized, and cost-effective sampling protocols are added impediments to the plight to advance our knowledge of parasitoid wasps [2].
Though accurate updated numbers are lacking, estimates suggest that Hymenoptera diversity in the Neotropics is greater than in the Nearctic, Palearctic, and Australian regions [8].
Ichneumonidae are the largest Hymenoptera family, and are currently divided into 42 subfamilies [9] with over 25,000 valid species [10]. Besides having the highest endemism rates, this family is also highly relevant for the practice of biological control since the species that comprise it obligatorily deposit their eggs in arthropods [8].
The Chilean biota has attracted much attention due to its connection with the Neotropics on the one hand, and its connection with Australasia as a remnant of an ancient Gondwanan biota on the other [11]. Indeed, the long latitudinal gradient and the presence of different environments along this gradient make Chile a biogeographic laboratory. The rapid uplift of the Andes since the Late Miocene prompted the isolation of biota, leading to remarkable levels of endemism [11].
Regarding species richness, in the northern hemisphere, there are indications of an inverse richness pattern; that is, an increase in richness towards higher latitudes. In the southern hemisphere, the lack of complete inventories creates difficulty in testing general-to-regional distribution patterns, and the richness of several groups tends to be concentrated in mid-latitudes. This pattern still needs to be tested regarding several explanations related to life history traits and attack strategies, mainly divided into different ovipositor lifestyles: idiobionts and koinobionts [12,13].
Chile has a very unique Ichneumonidae fauna, with differences in comparison to the Neotropics (see [14,15,16]). Porter [15] mentions that Chilean Darwin wasps differ significantly from the rest of South America and cannot be included as a sub-element of the Neotropical, due to “its exceptionally high number of endemic genera and its surprisingly few Neotropic genera for an area in geographic proximity to the American tropics” [15] (p. 38).
Indeed, Ichneumonidae are the family with the most endemic genera and species in Chile (including one endemic subfamily: Claseinae). The last published catalog reports a total of 36 endemic genera and 170 endemic species, out of a total of 88 genera and 193 recorded species [17]. The Chilean fauna includes representatives of cosmopolitan, Holarctic or Holarctic–Oriental, Neotropical, Andino-Patagonian, and Transantarctic (sharing species with Australia and New Zealand) genera, in addition to some genera that are widely but disjunctively distributed in both the Northern and Southern Hemispheres [15].
Porter [15] hypothesizes that the aberrant and endemic Chilean Darwin wasp fauna probably represents survivors that moved north from Antarctica before the glaciation and that evolved in isolation for the last 40 million years due to mountains, desertification, and a cold climate affecting the region’s eastern and northern boundaries by the mid-Cenozoic.
Thorough research into Chilean ichneumonid fauna ecology is crucial to understanding interspecies interactions and distribution patterns. The main goal is to pinpoint endemic areas for the conservation and investigation of native species for the effective biological control of agricultural pests.
We took advantage of the most up-to-date taxonomic revision of the Chilean Ichneumonidae, allowing us to make progress towards two specific goals: (a) disentangling the biogeographic relations of Chilean Darwin wasps at the genus level; (b) discovering the spatial patterns of biodiversity along the latitude and altitude gradients.

2. Materials and Methods

2.1. Study Area

Due to its current geographical conditions, Chile is considered a biogeographic island, bordering the Sechura desert in Peru beyond the Capricorn Tropic to the north, the Andean highlands to the east, the Pacific Ocean to the west, and Cape Horn approaching the Antarctic Circle to the south. The latitudinal gradient spans from the northern dry areas of the most arid desert in the world, Atacama, toward subtropical scrubs, Mediterranean sclerophyllous forests, deciduous forests, and the temperate evergreen Valdivian Forest in the south. Further south are the subantarctic moors and dwarf forests of Magallanes approaching Cape Horn. This high diversity in environments and their temporal evolution give insects like hymenopteran, coleopteran, and other diverse groups opportunities to diversify, resulting in a high proportion of endemic species and genera. A useful map of Chilean environments, suitable for continental comparisons, is the map of ecoregions by Dinerstein et al. [18]. The main ecoregions in the country from north to south are the Atacama Desert, Chilean Matorral, Valdivian temperate forests, and the Magellanic subpolar forests. On the borders with Argentina and Peru, we also have representation of the Sechura Desert, the Central Andean dry Puna, the Southern Andes Steppe, and the Patagonian Steppe. Taking these ecoregions as a base, we plotted the number of species and genera (Figure 2).

2.2. Biogeographic Relationships

For this analysis, 139 genera registered in Chile were considered according to Araujo et al. [19], except the introduced genera Megarhyssa and Rhyssa. We also included 35 genera with undetermined species (a total of 139 genera) (see Table S1). The genus Stiboscopus was not considered in the biogeographic classification because the genus is recorded by Porter [15] without species identification, and currently the genus has been divided into several genera, with Stiboscopus being synonymous with the genus Lysibia. It is also because we do not know which genus/genera the specimens belong to. The assessment of biogeographic relationships, including the classification of biotic elements, is a traditional task in biogeography [20,21,22,23]. We based our analysis on previous classifications of Chilean biota [11,15,24,25].
Porter [15], based on the knowledge available at the time, presented a fine description of biogeographic relationships among Chilean Ichneumonidae. He recognized 131 genera (including a couple undescribed) and arranged them in two main groups: (a) the genera restricted to the northern province, north of 25° S, including valleys in a desertic matrix and the high Andes adjacent to Peru and Bolivia; and (b) the Neantarctic realm south of 25° S encompassing all of central and southern Chile. Porter arranged 121 genera into five biogeographic elements in this Neantarctic realm: (a) endemic, (b) cosmopolitan, (c) Holarctic–Oriental, (d) Neotropical, (e) Australasian or Transantarctic, and (f) Holarctic–Neotropical–Australasian disjunct.
Following current taxonomic and distributional knowledge, we retrieved the following faunistic elements: (a) endemic, (b) cosmopolitan, (c) Holarctic–Oriental, and (d) Neotropical and Australasian. We added a specific element retrieved by Moreira-Muñoz [11] for Chilean flora: the south-temperate element, which encompasses Neotropical genera but occurs only south of 33° S in Chile and adjacent Argentina, mainly in temperate forests.
According to current knowledge, Porter’s Holarctic–Neotropical–Australasian disjunct element is composed only of the genus Isdromas, but this genus can easily be considered subcosmopolitan.

2.3. Biodiversity Spatial Patterns

For this analysis, we only considered genera with determined species (a total of 102 genera, according to Araujo et al. [19]).
Data cleaning included reviewing the geo-referencing of 939 individuals. We used geographic name repositories (Geonames and Mapcarta) and our own localities database. We had to disregard 2.7% of the data due to misspellings or incomplete distributional information (e.g., a whole region, confused names, etc.). After database cleaning and the erasure of duplicates coordinated in individual collections, our database consisted of 914 records, encompassing 264 species in 101 genera (Table S2).
Maps were generated on two scales using ArcGis 10.3, considering ecoregions and cells of 0.5 × 0.5 degrees. This cell size has been shown to perform well at a national scale compared to 1 × 1 degree, which is better for visualization at the level of administrative regions (Figure 2). This has no biological meaning but is informative for richness and collection efforts.

3. Results

3.1. Biogeographic Relationships

For this analysis, all genera documented in Chile (totaling 139 genera) were taken into account following Araujo et al. [19].
The biogeographic relationships at the genus level showed a remarkable presence of 50 cosmopolitan (36%) and 29 endemic genera (21%) (Table 1). Porter [15] has already noted that the proportion of endemic genera is similar to or greater than Madagascar, New Zealand, and Australia [22]. Endemic genera (Neantarctic genera—sensu Porter) [14] are mostly represented by one unique species collected in a few localities.
The other strong elements in the Chilean Darwin wasp genera are the Neotropical (n = 22; 16%), Holarctic–Oriental (n = 19), and south-temperate (n = 16) elements. The least represented element is the Australasian (Transantarctic in the sense of Porter [15]), with just three genera: Anacis, Labena, and Meringops (see Section 4).

3.1.1. Cosmopolitan Element

The cosmopolitan element of Chilean Darwin wasp genera is composed of 50 genera: Habronyx, Parania, and Therion (Anomaloninae); Exetastes and Lissonota (Banchinae); Brachycyrtus (Brachycyrtinae); Campoletis, Campoplex, Casinaria, Diadegma, Dusona, Hyposoter, Meloboris, and Venturia (Campopleginae); Pristomerus and Trathala (Cremastinae); Cryptus and Mesostenus (Cryptinae); Diplazon, Syrphoctonus, and Woldstedtius (Diplazontinae); Diphyus, Eutanyacra, Hoplismenus, Ichneumon, Melanichneumon, Setanta, Dicaelotus, Tycherus, and Platylabus (Ichneumoninae); Cidaphus and Mesochorus (Mesochorinae); Colpotrochia and Hypsicera (Metopiinae); Enicospilus and Ophion (Ophioninae); Megastylus, Symplecis, and Stenomacrus (Orthocentrinae); Dichrogaster, Gelis, Xenolytus, Charitopes, and Atractodes (Phygadeuontinae); Clistopyga, Tromatobia, Itoplectis, and Pimpla (Pimplinae); and Netelia (Tryphoninae). Isdromas (Phygadeuontinae) is distributed in Chile (Tarapacá region), Argentina, Brazil, Peru, and Ecuador in the Neotropics, Honduras in Central America, the United States in North America, and Australia. Hence, it can be considered subcosmopolitan (see Table S1). Indeed, most genera included in the element have a wide distribution in more than two continents or more than two main climatic zones (e.g., tropical and temperate). The element should be called subcosmopolitan (or semicosmopolitan, according to Porter [15]) because only half the genera occur in all continents, while the other half occur in the Nearctic, Oriental, Eastern and Western Palearctic, Neotropical, and European regions (Table S1).

3.1.2. Endemic Element

The endemic element is composed of genera distributed in continental Chile and the Juan Fernandez Islands. There is one endemic subfamily (Claseinae) and 29 endemic genera: Archoprotus and Valdiviglypta (Banchinae); Clasis and Ecphysis (Claseinae); Caenopelte, Araucacis, Nothischnus, and Periplasma (Cryptinae); Pedinopa, Cacomisthus, Petilium, and Stipomoles (Ctenopelmetinae); Barronia (Eucerotinae), Chilelabus, Ithaechma, and Zophoplites (Ichneumoninae); Gauldianus (Labeninae), Chineater, and Latilumbus (Mesochorinae); Pedunculus (Pedunculinae), Acidnus, Rhabdosis, Surculus, Peumocryptus, Bilira, and Teluncus, (Phygadeuontinae); and Notophrudus (Tersilochinae).
These genera are distributed in Central Chile (Archoprotus, Periplasma, and Chilelabus), Central–Southern Chile (Araucacis and Ithaechma), and most predominantly in Southern Chile (Valdiviglypta, Ecphysis, Caenopelte, Nothischnus, Clasis, Pedinopa, Cacomisthus, Petilium, Stipomoles, Barronia, Zophoplites, Gauldianus, Chineater, Latilumbus, Pedunculus, Acidnus, Rhabdosis, Surculus, Peumocryptus, Bilira, Teluncus, and Notophrudus).

3.1.3. Neotropical Element

The Neotropical element is composed of 22 genera, with Cryptinae the predominant one (Dotocryptus Trachysphyrus Cyclaulus, Aeglocryptus, Cosmiocryptus, Hypsanacis, Itamuton, Neocryptopteryx, Phycitiplex, and Xylacis), in addition to a few other genera of subfamilies such as Cecidopimpla, and Diradops (Banchinae); Prochas (Campoplegionae); Coelorhachis (Ctenopelmatinae); Carinodes, Diacanthatius, and Thymebatis (Ichneumoninae); Alophophion (Ophioninae), Grotea (Labeninae), Calliephialtes, and Odontopimpla (Pimplinae); and Stethantyx (Tersilochinae) (see Table S1).

3.1.4. Holarctic–Oriental Element

The Holarctic–Oriental element is composed of Glypta (Banchinae), Cymodusa, Campoctonus, Microcharops, Nemeritis, and Phobocampe (Campopleginae); Sussaba (Diplazongtinae), Scolomus, and Seticornuta (Metopiinae); Apoclima, Helictes, and Gnathochorisis (Orthocentrinae); Aclastus, Ethelurgus, Stilpnus, and Distathma (Phygadeuontinae); Stenobarichneumon (Ichneumoninae); and Liotryphon and Polysphincta (Pimplinae).

3.1.5. South-Temperate Element

The south-temperate element is composed of genera distributed in the Chilean Andes Mountains and adjacent Argentina. In Chile, 16 genera of Darwin wasps were found within this element: Tatogaster (Tatogastrinae); Geraldus (Banchinae); Aglaodina, Chilecryptus, Myrmecacis, Oecetiplex, Picrocryptoides, Sciocryptus, and Xiphonychidion (Cryptinae); Cataptygma and Tetrambon (Ctenopelmatinae); Barythixis, Chilhoplites, Notophasma (Ichneumoninae); Torquinsha (Labeninae); and Lepidura (Mesochorinae). All species of the genera classified under the south-temperate element have a Neantarctic distribution mainly in the Chilean part, and most south-temperate Darwin wasps with distribution in adjacent Argentina are present in Neuquén Province. The only exception could be Aglaodina (Cryptinae), reaching Antofagasta at 23°17′ south latitude.
Petilium and Notostilbops, classified as endemic, may in the future be classified as south-temperate, mainly due to the species distributed in Natales and Punta Arenas that are probably also in Argentina.

3.1.6. Australasian Element

The Australasian element (Transantarctic in the sense of Porter [15]) is composed of genera distributed in Australia, South America, and the Pacific islands. In Chile, only three genera comprise this element: Anacis (Cryptinae), Labena (Labeninae), and Meringops (Phygadeuontinae).

3.2. Spatial Pattern of Biodiversity along the Latitudinal Gradient

For this section, we focused on genera with identified species as revised by Araujo et al. [19]. This database is composed of 922 records encompassing 264 species arranged in 102 genera. More than half of the genera (n = 65) are composed of only one species (Figure 3).
Regarding the assessment of ecoregions, the largest number of species and genera (including 65 monospecific genera) are in the Valdivian temperate forests (167 species and 66 genera). The second ecoregion is the Chilean Matorral (with 89 species and 48 genera). Both ecoregions together make up the Chilean Winter Rainfall–Valdivian Forests biodiversity hotspot [26,27].
Regarding administrative regions following the latitudinal gradient, there is a bimodal distribution of species and genera richness: around 34° S in the Metropolitan Region and 38° S in the Araucanía Region (Figure 4 and Figure 5). The regions least suited for ichneumonid wasps are the arid northern regions, especially the Antofagasta Region at the center of the Atacama Desert (Figure 3, Figure 4 and Figure 5).
Plotted in cells of 0.5 × 0.5 degrees, the concentration of ichneumonid biodiversity is highest in the Santiago Andes (Figure 6). Several cells in the Andes of the Maule, Ñuble, and Araucanía Regions, as well as the coast of Biobío and Chiloé, also stand out (Figure 6).

4. Discussion

Current estimates suggest that the Neotropics host the highest Hymenoptera diversity globally [8]. By modeling host–parasitoid systems, Forbes et al. [28] proposed that there may be 2.5 to 3.2 times more Hymenoptera species than Coleoptera. This is not just a clue for entomologists, but also useful from ethological and ecological perspectives. As potential biological pest control agents, and in their still little-known ecological roles, the importance of these estimates to insect conservation is enormous.
Regarding Chilean ichneumonids, our understanding is still limited in terms of taxonomic and distributional aspects (Linnean and Wallacean shortfalls, respectively), even with the recent availability of an updated catalog [19]. There are currently a total of 139 genera classified in 23 subfamilies [19]. This represents 37% more than the last authoritative catalog [17] and is closer to the numbers produced by Porter [15] over 3 decades ago. Porter considered the Chilean ichneumonid fauna to be composed of 131 genera and over 170 species (see also [29]). At the time, Porter increased taxonomic knowledge by 100% over previous studies. He considered that increasing taxonomic knowledge would result in the discovery of 1000 to 1500 species. We are still far from these numbers, but they are continuously increasing. Still, 35 genera recognized by Porter and considered valid for Chile lack any specimens classified at the species level. The stability of numbers at the genus level and the gaps at the species level respond to two possible phenomena: the lack of specialists to increase these numbers (i.e., identification, collection with specific traps, etc.), and the presence of a depauperate fauna in Chile, rich in endemism but not as rich in species numbers as in the rest of the Neotropics. The country’s prolonged biogeographic isolation accounts for the high proportion of endemism at the genus and species levels, but continuous environmental disturbances at a geological scale could also lead one to hypothesize innumerable extinctions [15].
The biogeographic relationships of Chilean ichneumonids have an intrinsic relationship to the evolution of Chilean biota as a whole, but one that is not well studied. Porter [15] arranged the Chilean genera in two main groups: (a) the genera restricted to the northern province, north of 25° S, including valleys in the Atacama Desert and the high Andes adjacent to Peru and Bolivia; and (b) the Neantarctic realm south of 25° S encompassing all of central and southern Chile.
According to this approach, the northern province is mainly composed of Neotropical and cosmopolitan genera, with their representatives in the far north shared with Peru and Bolivia, such as species from the genera Brachycyrtus, Carinodes, Cosmiocryptus, Cyclaulus, Cymodusa, Hypsanasis, Isdromas, Itoplectis, and Mesostenus. We can now add representatives of Lissonota and Microcharops to this list (one species each from the Azapa Valley).
All the other 120 genera belong to Porter’s Neantarctic realm, encompassing all of Chile south of 25° S toward Cape Horn, including the Juan Fernandez islands. The debate between the existence of a Neotropical realm and a Neantarctic realm has been permanent in Austral biogeography (see [30,31]). At least for well-documented groups such as vascular plants, the existence of an “austral realm” has long been established [32], and more recently confirmed [11,33]. The terms Neantarctic, Holantarctic, Australasiatic, and Austral have similar meanings, emphasizing the biogeographical relationships of the disjunct distribution across the Pacific, mainly in southern South America and Australasia (New Zealand and Australia), with a minor relationship to the Cape Region in South Africa. Analyzing the distribution of vascular plants, Moreira-Muñoz [33] concluded that “there are 15 families and c. 60 genera that, under current taxonomic treatment, support the segregation of an Austral realm” [33] (p. 1657).
In Porter’s concept of ichneumonid biogeography, 39 genera (32%) belong to the endemic element; 31 genera (25%) correspond to the cosmopolitan element; 20 genera (16%) belong to the Holarctic–Oriental element; 17 genera (14%) correspond to the Neotropical element; just 4 genera comprise the Transantarctic (Australasian) element; and 3 genera belong to the disjunct Holarctic–Neotropical–Australasian element.
The four main elements—endemic, cosmopolitan, Holarctic–Oriental, and Neotropical—are recognizable according to current knowledge as follows: cosmopolitan element (n = 50, 36%), endemic element (n = 29, 21%), Neotropical element (n = 22, 16%), Holarctic–Oriental (n = 19, 14%). We also now recognize a south-temperate element (n = 16, 11%) and, following taxonomic updating, the Australasian element is now only composed of three genera: Anacis (Cryptinae), Labena (Labeninae) and Meringops (Phygadeuontinae).
According to Porter [15], these endemic genera sharply define the Neantarctic realm. The Neantarctic realm has a variety of landscapes ranging from semi-desert with sclerophyllous woods to humid Nothofagus forests in the south. It also has a disjunct relationship with certain genera in Australia and the Holarctic region, revealing the absence of dominant Neotropical taxa. In addition, Porter [15] divided the Neantarctic realm into four provinces according to the biota and phytophysiognomy of its environments: Atacamense; Mediterranean or Central; Valdivian; and Magallanic. The Valdivian province is the Chilean region with the greatest diversity of Neantarctic Ichneumonidae. This is because Darwin wasps prefer to frequent humid environments or close forests. After all, most species are hygrophilous and sylvatic (but, especially under cool thermal regimes, they also tend to invade open forests and grasslands) [16]. Valdivian vegetation is characterized by temperate evergreen forest, typically with neatly developed herbaceous, shrubby, and arboreal strata. The dominant tree niche is occupied mainly by various Nothofagus, Eucryphia, Gevuina, Embothrium, Lomatia, and Drimys species. This province is one of the best-defined centers of endemism in South America [15,34].
Moreira-Muñoz [11] says that it would be better to refer to the Neotropical element as an “American” element that ranges from the Northwestern United States to Mexico, Central America, the Northern Andes, Amazonia, the Central Andes, and the Southern Andes, including Chile and Argentina. However, Porter [15] emphasizes the fact that Chilean ichneumonid fauna differs from the rest of the Neotropics due to having the highest presence of endemic taxa and the lack of a predominance of Neotropical taxa in the Neantarctic realm south of 27 degrees [15,16]. According to Araujo et al. [19], six neotropical genera have widely distributed species in northern and southern Chile (Dotocryptus, Trachysphyrus, Itamuton, Thymebatis, Alophophion, and Calliephialtes), five genera are exclusive to Northern Chile (Cyclaulus, Cosmiocryptus, Hypsanacis, Microcharops, and Carinodes), three genera are exclusive to Central Chile (Phycitiplex, Prochas, and Diacanthatius), five genera are distributed in Central–Southern Chile (Aeglocryptus, Neocryptopterys, Cecidopimpla, Diradops, Coelorhachis, and Stethantyx), one neotropical genus (Xylacis) is exclusive to Southern Chile, and the genus Odontopimpla has uncertain distribution in Chile.
The Neotropical element can be further split into several subgroups (described as generalized tracks in Moreira-Muñoz [11]): Wide Neotropical track—composed of genera occurring in NW United States, from Mexico to Chile. Among Darwin wasps, seven neotropical genera were identified: Diacantharius, Diradops, Microcharops, Carinodes, Calliephialtes, Odontopimpla, and Stethantyx. Two genera (Diacantharius and Odontopimpla) reach Mexico but not the United States. Wide Andean track—composed of genera occurring in Costa Rica and ranging from Colombia to Chile. Five genera were identified: Cecidopimpla, Dotocryptus, Trachysphyrus, Hypsanacis, and Alophophion. Only Cecidopimpla reached Costa Rica. Central Andean or Altiplano track—composed of genera occurring in the Andean Altiplano in Peru, Chile, Bolivia, and Argentina. Five genera were identified: Cyclaulus, Cosmiocryptus, Itamuton, Phycitiplex, and Xylacis. South Amazonian track—composed of genera occurring in the Andes and southern Amazonia. Five genera were identified: Prochas, Aeglocryptus, Neocryptopteryx, Thymebatis, and Alophophion. According to Fernandes et al. [35], in Brazil these five genera are distributed mainly in the South, Southwest, and Northeast regions. Phycitiplex is only distributed in Argentina, Chile, and Uruguay.
Regarding the Holarctic–Oriental element, Porter [15] mentions that the Holarctic genera arrived in the Eocene and Oligocene eras, mainly because the Oligocene and subsequent periods experienced cold pulses (the world has undergone repeated changes from cold to tropical and from humid to arid climatic regimes since the Oligocene) that allowed for the exchange of Holarctic biota across the Andes and Central American mountains to the south and from the Andean–Patagonian regions to the north.
Australasian (or Transantarctic) genera present in the New World and Australia are very similar to the oldest insect orders (e.g., Ephemeroptera, Odonata, Plecoptera, Mecoptera), as they frequently appear among vascular plants [11]. According to the evidence, Labeninae radiated throughout Gondwana after the separation of Africa, India, and Madagascar, but before the separation of Australia [36]. This indicates a plausible pathway for biotic exchange between South America and Australia, possibly via Antarctica. Biogeographic inference also reveals that North American groups underwent more recent range expansions before the formation of the Isthmus of Panama land bridge [37]. This implies a more intricate scenario for Labeninae biogeography than previously anticipated.
Porter [15] already proposed that Chilean Darwin wasps have a connection to Antarctica. According to the hypothesis, the major lineages of this family already existed during the Cretaceous era, which was characterized by a much warmer and more humid global climate than today, and South America was still connected to Antarctica. During this period, a diverse biota evolved in Antarctica, which was extensively shared with southern America and Australia. Antarctica and South America remained connected until about 25 mya [38]. The unusual and endemic biota of Neantarctic South America probably survived by moving north from Antarctica before its glaciation. The mid-Cenozoic era marked the isolation of the Neantarctic realm along its eastern and northern boundaries due to mountain building, desertification, and cold climatic changes. As a result, the region’s insect biota has evolved in isolation for the last 25 million years (though more recent relations across the sea have also been proven) [39].
For the diversity analysis along the latitudinal gradient, we were able to plot occurrences for 264 species arranged in 102 genera, of which 65 were composed of just one species, which again indicates a depauperate fauna and/or knowledge gaps. Other regions such as Mexico also show a high proportion of genera (n = 123) composed of just one species [40].
In Chilean ichneumonid fauna, many species are represented by only one specimen, such as Aeglocryptus nigricornis (Brullé, 1846); Acidnus ensifer (Townes, 1970); Aglaodina hyperbas (Porter, 1967); Barronia araucaria (Gauld & Wahl, 2002), Microcharops anticarsiae (Gupta, 1987); and Venturia porteri (Brèthes, 1913). Others reach almost 20 species, such as Nemeritis scaramozzinoi Di Giovanni & Araujo, 2021 and Trachysphyrus agenor Porter, 1967, while others reach a dozen species, such as Tycherus chileator Diller, 2009 and Trachysphyrus penai Porter, 1967. Most genera are represented by few species, and these species are represented by few specimens. At this stage, it is not possible to discern between species that are indeed rare in the field from those that are under-collected due to limited collection efforts and a lack of specialists (a characteristic of the concept of “hidden biodiversity”).
A total of 264 species and 102 genera is not a large number compared to megadiverse countries such as Brazil or Mexico (with 1066/239 and 1031/373 species/genera, respectively). Mexico registers 45% endemic species, while Brazil registers just 3.1% endemic species [35,40].
Comparing the richness of Chilean Ichneumonidae with the biogeographical regions of Tenebrionidae in Chile proposed by Peña [41], as well as the more recent ecoregions proposed by Morrone [42], Darwin wasps are mainly found in the central regions of coastal Cordillera and southern Andean Cordillera [41], currently classified by Morrone [42] as the districts of Santiago Province (33–37° S) in the Central Chilean subregion and the Northern Valdivian Forest and Valdivian Forest regions [41]. Both regions are classified by Morrone [42] as provinces (in part) of the Subantarctic Region, with the Northern Valdivian Forest in Maule Province (37–39° S) and the Valdivian Forest in the Valdivian Forest Province (39–47° S).
The distribution pattern of Chilean Darwin wasps at the regional level does not support an increasing richness towards the tropics nor an increasing richness towards the south, with the highest richness maintained at mid-latitudes, as has been shown for comparable groups such as Chilean bees [43]. Chilean butterflies also display the highest richness at mid-latitudes [44].
This pattern supports the traditional (but debated) latitudinal trend of increasing richness towards the tropics. But in the case of ichneumonids, the taxonomic and distributional knowledge is still too limited (Wallacean and Linnean shortfalls); however, changes in this tendency can confidently be expected in the coming years (if more specialists join the challenge). The pattern is similar in comparable megadiverse botanical groups such as the Asteraceae; Chile harbors much less diversity than Brazil or Peru [45]. This is a consistent pattern in this biotic group, where the taxonomic and distributional knowledge is much more reliable.
In the case of Ichneumonidae, even if the Linnean and Wallacean shortfalls are better filled in the coming years, the richness pattern will continue to have a bimodal distribution and be concentrated at mid-latitudes due to the presence of the Atacama Desert, which constitutes a physical barrier for the diversification of life. This fact does not imply a merely barren environment, but an evolutionary arena favoring several groups such as Cactaceae [11] (p. 202) and Nolaneae [46] in the case of plant groups adapted to aridity.
The inverse latitudinal pattern of ichneumonids and the concentration at mid-latitudes, if confirmed for the Southern Hemisphere, still need to be tested regarding several explanations related to life history traits and attack strategies, as revised by Santos and Quicke [12]. Attack strategies are divided into different ovipositor lifestyles: idiobionts and koinobionts. According to Santos and Quicke [12] (and references therein), the concentration of the richness towards the south could be based on certain non-mutually exclusive explanations, such as (a) the resource fragmentation hypothesis, proposing that the diversity of hosts rises towards the equator, but that the density of each host population is too low to support koinobiont species; (b) the predation on hosts hypothesis, suggesting that predation on herbivores in the tropics is greater than in temperate regions; (c) the interphyletic competition hypothesis that parasitoids have to compete for hosts with other parasitic organisms that are more diverse in the tropics; and (d) the “nasty hosts hypothesis,” based on the tendency of tropical plants to have more chemical toxins than their temperate counterparts [12] (p. 374).
The concentration of Chilean ichneumonids at mid-latitudes is coincident with the highest presence of tree species at middle latitudes around 36° and 40° S, at the transition from the Mediterranean matorral to the temperate forest ecoregions [34]. This issue has been described as a “Gondwanan legacy” [47]. Nothofagus tree species, a potential habitat for parasitoid hosts, range from 33° S toward Cape Horn, but their richness is concentrated from 35° S to 42° S [11] (p. 256). Some studies note defoliator species such as the “sawfly from roble and raulí”, parasited by Clasis sp. [48].
Though species and generic richness are concentrated in several cells at mid-altitudes in the contact zone between the Valdivian Forests ecoregion and the Chilean Matorral, the need for additional sampling and the explicit assessment of collection biases and gaps through richness estimators is evident (see [49]).
Comparing altitudinal patterns, Flinte et al. [50] discovered that low- and mid-altitude areas on a mountain in the Brazilian Atlantic Forest contained significant diversity in terms of Darwin wasps, unlike their high-altitude counterparts. Moreover, distinct species were observed at various elevations along the mountain. These results imply that tropical forests could potentially host concentrated populations of Darwin wasps and deforestation poses a substantial risk of losing this biodiversity. Prioritizing the conservation of forests at low-to-middle altitudes may prove most effective in safeguarding the diversity of these wasps, though ensuring protection across a broad altitude range is essential for the preservation of all species.
The knowledge of Chilean ichneumonid biodiversity richness is biased towards the most human-populated regions in the country. On the other hand, the highest levels of richness are in several cells in the contact zone between the Valdivian Forests ecoregion and the Chilean Matorral (Figure 7). It should be noted that several cells represent emblematic collection localities, such as the Santiago Range, the Nahuelbuta Coastal Range, the Araucanía Range, and Torres del Paine National Park in Magallanes. In contrast, the Atacama Desert shows little or no presence of Darwin wasps (Figure 5), which is to be expected due to the lack of a forest ecosystem rich in potential hosts and humidity. According to Porter [16], ichneumonids are generally restricted to forests or jungles (regions with frequent dew or rainfall), with semi-arid and arid zones being unfavorable for them and their hosts as, according to Townes [51], adult Darwin wasps need to drink water once a day (in the form of condensed dew on plant leaves). Meanwhile, Gauld [52] comments the following on the Costa Rican Darwin wasp: “Species-richness is generally greatest in forests or other humid areas, whilst there are relatively few species in more open, dry habitats […]” [52] (p. 25). This may be one of the reasons for the scant richness of Darwin wasps in the Chilean North.
Several authors have already emphasized that the global distributional knowledge of Ichneumonidae is too limited to be able to reach conclusions about latitudinal and altitudinal trends in the family [7,53]. Our results reinforce the still limited taxonomic and distributional information on Chilean subtropical and temperate ichneumonid fauna. This also has implications for the conservation of “hidden biodiversity” [54]. We also have a long way to go regarding understanding the relationships between parasitoids and their hosts (e.g., [55]) so we can better understand functions within and across ecosystems and latitudinal gradients.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/insects15060415/s1, Table S1: Chilean genera, ordered by Darwin wasp (Ichneumonidae) elements: (1) Cosmopolitan, (2) Endemic, (3) Neotropical, (4) Holarctic-Oriental, (5) South-temperate, (6) Australasian; Table S2: Chilean Ichneumonidae database [55,56,57,58,59,60,61,62,63,64,65,66,67,68,69,70,71,72,73,74,75,76,77,78,79,80,81,82,83,84,85,86,87,88,89,90,91,92,93,94,95,96,97,98,99,100,101,102,103,104,105,106,107,108,109,110,111,112,113,114,115,116,117].

Author Contributions

Conceptualization, D.G.P. and R.O.A.; methodology, D.G.P., R.O.A., V.M.-F. and A.M.-M.; software, A.M.-M. and V.M.-F.; validation, D.G.P., R.O.A., V.M.-F. and A.M.-M.; formal analysis, D.G.P., V.M.-F. and A.M.-M.; investigation, D.G.P., A.M.-M. and R.O.A.; resources, R.O.A. and A.M.-M.; data curation, D.G.P. and R.O.A.; writing—original draft preparation, D.G.P. and A.M.-M.; writing—review and editing, D.G.P., R.O.A. and A.M.-M.; visualization, D.G.P. and A.M.-M.; supervision, R.O.A. and A.M.-M.; project administration, R.O.A. and A.M.-M.; funding acquisition, A.M.-M. All authors have read and agreed to the published version of the manuscript.

Funding

This research was supported by the “Agencia Nacional de Investigación y Desarrollo (ANID)”, Chile, through the project “FONDECYT Regular” n° 1221879.

Data Availability Statement

Details regarding the supporting data will be reported soon in the World Ichneumonidae Database. The data can also be requested directly from the corresponding author.

Acknowledgments

We thank Vilma A. Sarto Zeferino from USP/ESALQ/Divisão de Biblioteca (Comutação Bibliografica) for finding and sending us old hard-to-obtain papers. We also thank Diego Reyes, Guillermo Arenas, Jose Luis Inostroza, Pablo Nuñez, Paulo Valencia, and Pedro Vargas, who allowed us to reproduce their photographs of Chilean Darwin wasp species.

Conflicts of Interest

The authors declare no conflicts of interest.

References

  1. Klopfstein, S.; Santos, B.F.; Shaw, M.R.; Alvarado, M.; Bennett, A.M.R.; Dal Pos, D.; Giannotta, M.; Herrera Florez, A.F.; Karlsson, D.; Khalaim, K.I.; et al. Darwin wasps: A new name heralds renewed efforts to unravel the evolutionary history of Ichneumonidae. Entomol. Commun. 2019, 1, ec01006. [Google Scholar] [CrossRef]
  2. Saunders, T.E.; Ward, D.F. Variation in the diversity and richness of parasitoid wasps based on sampling effort. Peerj 2018, 6, e4642. [Google Scholar] [CrossRef] [PubMed]
  3. Cardoso, P.; Erwin, T.L.; Borges, P.A.V.; New, T.R. The seven impediments in invertebrate conservation and how to overcome them. Biol. Conserv. 2011, 144, 2647–2655. [Google Scholar] [CrossRef]
  4. New, T.R. Invertebrate Surveys for Conservation; Oxford University Press: Oxford, UK, 1998; pp. 1–240. [Google Scholar]
  5. Sanchéz-Bayo, F.; Wyckhuys, K.A.G. Worldwide decline of the entomofauna: A review of its drivers. Biol. Conserv. 2019, 232, 8–27. [Google Scholar] [CrossRef]
  6. Milić, D.; Radenković, S.; Ačanski, J.; Vujić, A. The importance of hidden diversity for insect conservantion: A case study in hoverflies (the Merodon atratus complex, Syrphidae, Diptera). J. Insect Conserv. 2019, 23, 29–44. [Google Scholar] [CrossRef]
  7. Veijalainen, A.; Wahlberg, N.; Broad, G.R.; Erwin, T.L.; Longino, J.T.; Sääksjärvi, I.E. Unprecedented ichneumonid parasitoid wasp diversity in tropical forests. Proc. R. Soc. B Biol. Sci. 2012, 279, 4694–4698. [Google Scholar] [CrossRef] [PubMed]
  8. Fernández, F.; Sharkey, M.J. Introducción a los Hymenoptera de la Región Neotropical; Sociedad Colombiana de Entomología y Universidad Nacional de Colombia: Bogotá, Colombia, 2006; pp. 1–894. [Google Scholar]
  9. Bennett, A.M.R.; Cardinal, S.; Gauld, I.D.; Wahl, D.B. Phylogeny of the subfamilies of Ichneumonidae (Hymenoptera). J. Hymenopt. Res. 2019, 71, 1–156. [Google Scholar] [CrossRef]
  10. Yu, D.S.K.; Achterberg, C.; Horstmann, K. (2016) Taxapad 2016, Ichneumonoidea 2015. Taxapad, Ottawa, Database on flashdrive. Available online: http://www.taxapad.com (accessed on 30 January 2023).
  11. Moreira-Muñoz, A. Plant and Vegetation 5: Plant Geography of Chile; Werger, M.J.A., Ed.; Springer: New York, NY, USA, 2011; pp. 1–320. [Google Scholar]
  12. Santos, A.M.C.; Quicke, D.L.J. Large-scale diversity patterns of parasitoid insects. Entomol. Sci. 2011, 14, 371–382. [Google Scholar] [CrossRef]
  13. Kishineysky, M.; Keasar, T. Trait-based characterisation of parasitoid wasp communities in natural and agricultural areas. Ecol. Entomol. 2022, 47, 657–667. [Google Scholar] [CrossRef]
  14. Porter, C.C. Zoogeografia de las Ichneumonidae Latino-Americanas (Hymenoptera). Acta Zool. Lilloana 1980, 36, 5–52. [Google Scholar]
  15. Porter, C.C. Biogeographic of Chilean Ichneumonid Flies (Hymenoptera: Ichneumonidae). Acta Entom. Chil. 1991, 16, 37–68. [Google Scholar]
  16. Porter, C.C. Guía de los Géneros de Ichneumonidae en la Región Neantática del Sur de Surdamérica. Opera Lillo. 1998, 42, 1–229. [Google Scholar]
  17. Elgueta, M.; Rojas, F. Hymenoptera de Chile. In Hacia un Proyecto CYTED para el Inventario y Estimación de la Diversidad Entomológica en Iberoamérica: PrIBES-2000; Martín-Piera, F., Morrone, J.J., Melic, A., Eds.; m3m: Monografías Tercer Milenio: Zaragoza, Spain, 2000; Volume 1, pp. 245–251. [Google Scholar]
  18. Dinerstein, E.; Olson, D.; Joshi, A.; Vynne, C.; Burgess, N.D.; Wikramanayake, E.; Hahn, N.; Palminteri, S.; Hedao, P.; Noss, R.; et al. An Ecoregion-Based Approach to Protecting Half the Terrestrial Realm. BioScience 2017, 67, 534–545. [Google Scholar] [CrossRef]
  19. Araujo, R.O.; Dal Pos, D.; Fernandes, D.R.R.; Moreira-Muñoz, A.; Pádua, D.G. Unveiling the secrets of South American Darwin Wasps: A comprehensive Catalog of the Chilean Ichneumonidae (Hymenoptera: Ichneumonidae). Cent. Investig. Estud. Av. Del Maule Univ. Católica Del Maule Talca Chile, 2024; manuscript in preparation. [Google Scholar]
  20. Darlington, P.J. Biogeography of the Southern End of the World. Distribution and History of Far-Southern Life and Land, with an Assessment of Continental Drift; Harvard University Press: Cambridge, MA, USA, 1965; pp. 1–246. [Google Scholar]
  21. Holloway, J.D.; Jardine, N. Two approaches to zoogeography: A study based on the distributions of butterflies, birds and bats in the Indo-Australian area. Proc. Linn. Soc. 1968, 179, 153–188. [Google Scholar] [CrossRef]
  22. Gauld, I.D. An Introduction to the Ichneumonidae of Australia; British Museum: London, UK, 1984; pp. 1–413. [Google Scholar]
  23. Hausdorf, B.; Hennig, C. Biotic Element Analysis in Biogeography. Syst. Biol. 2003, 52, 717–723. [Google Scholar] [CrossRef] [PubMed]
  24. Crisci, J.V.; Cigliano, M.M.; Morrone, J.J.; Roig-Junent, S. Historical Biogeography of Southern South America. Syst. Biolo. 1991, 40, 152–171. [Google Scholar] [CrossRef]
  25. Crisci, J.; Katinas, L.; Posadas, P. Historical Biogeography: An Introduction; Harvard University Press: Cambridge, MA, USA, 2003; pp. 1–264. [Google Scholar]
  26. Fuentes-Castillo, T.; Hernández, H.J.; Pliscoff, P. Hotspots and ecoregion vulnerability driven by climate change velocity in Southern South America. Reg. Environ. Chang. 2020, 20, 1–15. [Google Scholar] [CrossRef]
  27. Moreira-Muñoz, A.; Scherson, R.; Luebert, F.; Román, M.J.; Monge, M.; Diazgranados, M.; Silva, H. Biogeography, phylogenetic relationships and morphological analyses of the South American genus Mutisia L.f. (Asteraceae) shows early connections of two disjunct biodiversity hotspots. Org. Div. Evol. 2020, 20, 639–656. [Google Scholar] [CrossRef]
  28. Forbes, A.A.; Bagley, R.K.; Beer, M.A.; Hippee, A.C.; Widmayer, H.A. Quantifying the unquantifiable: Why Hymenoptera, not Coleoptera, is the most speciose animal order. BMC Ecol. 2018, 18, 21. [Google Scholar] [CrossRef]
  29. Lanfranco, L.D. Contribución al conocimiento de los icneumónidos de Chile. Rev. Chil. Entomol. 1980, 10, 77–84. [Google Scholar]
  30. Cox, C.B. The biogeographic regions reconsidered. J. Biogeogr. 2001, 28, 511–523. [Google Scholar]
  31. Morrone, J.J. Biogeographical regions under track and cladistic scrutiny. A comment on C. B. Cox (2001). J. Biogeogr. 2002, 29, 149–152. [Google Scholar] [CrossRef]
  32. Skottsberg, C. Remarks on the plant geography of the southern cold temperate zone. Proc. R. Soc. B Biol. Sci. 1960, 152, 447–457. [Google Scholar]
  33. Moreira-Muñoz, A. The Austral floristic realm revisited. J. Biogeogr. 2007, 34, 1649–1660. [Google Scholar] [CrossRef]
  34. Villagrán, C.; Hinojosa, L.F. Historia de los bosques del sur de Sudamérica, II: Análisis fitogeográfico. Rev. Chil. Hist. Nat. 1997, 70, 241–267. [Google Scholar]
  35. Fernandes, D.R.R.; Santos, B.F.; Pádua, D.G.; Araujo, R.O. Ichneumonidae in Catálogo Taxonômico da Fauna do Brasil; PNUD, 2024. Available online: http://fauna.jbrj.gov.br/fauna/faunadobrasil/18131 (accessed on 7 May 2024).
  36. Gauld, I.D.; Wahl, D.B. The Labeninae (Hymenoptera: Ichneumonidae): A study in phylogenetic reconstruction and evolutionary biology. Zool. J. Linn. Soc. 2000, 129, 271–347. [Google Scholar] [CrossRef]
  37. Santos, B.F.; Sandoval, M.; Spasojevic, T.; Giannotta, M.M.; Brady, S.G. A Parasitoid Puzzle: Phylogenomics, Total-evidence Dating, and the Role of Gondwanan Vicariance in the Diversification of Labeninae (Hymenoptera, Ichneumonidae). Insect Syst. Divers. 2022, 6, 3. [Google Scholar] [CrossRef]
  38. Grimaldi, D.; Engel, M.S. Evolution of the Insects; Cambridge University Press: New York, NY, USA, 2005; pp. 1–755. [Google Scholar]
  39. Kuschel, G. Biogeography and Ecology of South American Coleoptera. In Biogeography and Ecology in South America; Fittkau, E.J., Illies, J., Klinge, H., Schwabe, G.H., Sioli, H., Eds.; Monographiae Bioloficae; Springer: Dordrecht, The Netherlands; Berlin/Heidelberg, Germany, 2012; Volume 2, pp. 709–722. [Google Scholar]
  40. Ruíz-Cancino, E.; Kasparyan, D.R.; González-Moreno, A.; Khalaim, A.I.; Coronado-Blanco, J.M. Biodiversidad de Ichneumonidae (Hymenoptera) en México. Rev. Mex. Biodivers. 2014, 85, 385–391. [Google Scholar] [CrossRef]
  41. Peña, L.E. A Preliminary Attempt to Divide Chile into Entomofaunal Regions, Based on the Tenebrionidae (Coleptera). Postilla 1966, 97, 1–18. [Google Scholar]
  42. Morrone, J.J. Biogeographical regionalization of the Andean region. Zootaxa 2015, 3936, 207–236. [Google Scholar] [CrossRef] [PubMed]
  43. Marshall, L.; Ascher, J.S.; Villagra, C.; Beaugendre, A.; Herrera, V.; Henríquez-Piskulich, P.; Vera, A.; Vereecken, N.J. Chilean bee diversity: Contrasting patterns of species and phylogenetic turnover along a large-scale ecological gradient. Ecosphere 2023, 14, e4535. [Google Scholar] [CrossRef]
  44. Samaniego, H.; Marquet, P.A. Mammal and butterfly species richness in Chile: Taxonomic covariation and history. Rev. Chil. Hist. Nat. 2009, 82, 135–151. [Google Scholar] [CrossRef]
  45. Moreira-Muñoz, A.; Monge, M.; Grossi, M.A.; Avila, F.A.; Morales-Fierro, V.; Heiden, G.; Britto, B.; Beck, S.; Nakajima, J.; Salgado, V.G.; et al. South America holds the greatest diversity of native daisies (Asteraceae) in the world: An updated catalogue supporting continental-scale conservation. Front. Plant Sci. 2024, 15, 1393241. [Google Scholar] [CrossRef]
  46. Moreira-Muñoz, A.; Palchetti, M.V.; Morales-Fierro, V.; Duval, V.S.; Allesch-Villalobos, R.; Gonzalez-Orozco, C.E. Diversity and Conservation Gap Analysis of the Solanaceae of Southern South America. Front. Plant Sci. 2022, 13, 854372. [Google Scholar] [CrossRef] [PubMed]
  47. Segovia, R.A.; Armesto, J.J. The Gondwanan legacy in South American biogeography. J. Biogeogr. 2015, 42, 209–217. [Google Scholar] [CrossRef]
  48. Bauerle, P.; Rutherford, P.; Lanfranco, D. Defoliadores de roble (Nothofagus obliqua), raulí (N. alpina), coigüe (N. dombeyi) y lenga (N. pumilio). Bosque 1997, 18, 97–107. [Google Scholar] [CrossRef]
  49. Pizarro-Araya, J.; Villalobos, E.V.; Alfaro, F.M.; Moreira-Muñoz, A. Conservation efforts in need of survey improvement in epigean beetles from the Atacama coast, Chile. J. Arid Environ. 2023, 214, 104995. [Google Scholar] [CrossRef]
  50. Flinte, V.; Pádua, D.G.; Durand, E.M.; Hodgin, C.; Khattar, G.; da Silveira, L.F.L.; Fernandes, D.R.R.; Sääksjärvi, I.E.; Monteiro, R.F.; Macedo, M.V.; et al. Variation in a Darwin Wasp (Hymenoptera: Ichneumonidae) Community along an Elevation Gradient in a Tropical Biodiversity Hotspot: Implications for Ecology and Conservation. Insects 2023, 14, 861. [Google Scholar] [CrossRef]
  51. Townes, H.K. The genera of Ichneumonidae, Part 4. Mem. Amer. Ent. Inst. 1971, 17, 1–372. [Google Scholar]
  52. Gauld, I.D. The Ichneumonidae of Costa Rica, I. Mem. Amer. Ent. Inst. 1991, 47, 1–589. [Google Scholar]
  53. Quicke, D.L.J. We Know Too Little about Parasitoid Wasp Distributions to Draw Any Conclusions about Latitudinal Trends in Species Richness, Body Size and Biology. PLoS ONE 2012, 7, e32101. [Google Scholar] [CrossRef] [PubMed]
  54. Jerez, V.; Zúñiga-Reinoso, A.; Muñoz-Escobar, C.; Pizarro-Araya, J. Acciones y avances sobre la conservación de insectos en Chile. Gayana 2003, 79, 1–3. [Google Scholar] [CrossRef]
  55. Jervis, M.A.; Ferns, P.N.; Heimpel, G.E. Body size and the timing of egg production in parasitoid wasps: A comparative analysis. Funct. Ecol. 2003, 17, 375–383. [Google Scholar] [CrossRef]
  56. Townes, H.K. The genera of Ichneumonidae, Part 2. Mem. Amer. Ent. Inst. 1970, 12, 1–537. [Google Scholar]
  57. Townes, H.K.; Townes, M. A catalogue and reclassification of the Neotropic Ichneumonidae. Mem. Amer. Ent. Inst. 1966, 8, 1–367. [Google Scholar]
  58. Lanfranco, L.D. Contribución al conocimiento de la icneumonofauna de la región de Magallanes (Hymenoptera - Ichneumonidae). An. Inst. Patagon. 1974, 5, 199–208. [Google Scholar]
  59. Porter, C.C. A revision of the south American species of Trachysphyrus. Mem. Amer. Ent. Inst. 1967, 10, 1–368. [Google Scholar]
  60. Alvarado, M. Revision of the South American wasp genus Alophophion Cushman, 1947 (Hymenoptera: Ichneumonidae: Ophioninae). Rev. Peru. Biol. 2014, 21, 3–60. [Google Scholar] [CrossRef]
  61. Jerez, V.; Lanfranco, L.D.; Andrade, B. Aspectos ecologicos de los ichneumonidos del Bosque de Quintero. An. Mus. Hist. Nat. Valpso. 1977, 10, 161–168. [Google Scholar]
  62. Porter, C.C. A review of the Chilean genera of the tribe Mesostenini (Hym. Ichneumonidae). Studia Ent. 1967, 10, 369–418. [Google Scholar]
  63. Porter, C.C. New species and records of Anacis (Hymenoptera: Ichneumonidae: Cryptini) from tropical and temperate Andean South America. Insecta Mundi 2004, 17, 119–127. [Google Scholar]
  64. Porter, C.C. A revision of the Chilean Mesostenini (Hymenoptera: Ichneumonidae). Contrib. Am. Entomol. Inst. 1987, 23, 1–164. [Google Scholar]
  65. Bordera, S.; Mazón, M.; Sääksjärvi, I.E. The Neotropical species of Atractodes (Hymenoptera, Ichneumonidae, Cryptinae), II: The A. pleuripunctatus species-group. Zootaxa 2016, 4161, 437–444. [Google Scholar] [CrossRef] [PubMed]
  66. Gauld, I.D.; Wahl, D.B. The Eucerotinae: A Gondwanan origin for a cosmopolitan group of Ichneumonidae? J. Nat. Hist. 2002, 36, 2229–2248. [Google Scholar] [CrossRef]
  67. Townes, H.K. The genera of Ichneumonidae, Part 3. Mem. Amer. Ent. Inst. 1970, 13, 1–307. [Google Scholar]
  68. Spinola, M. Icneumonitos. Zoologia. 6: "Historia física y politica de Chile."; Gay, C., Ed.; Paris, France, 1851; pp. 471–550. Available online: https://www.biodiversitylibrary.org/item/130101#page/7/mode/1up (accessed on 30 January 2023).
  69. Porter, C.C. Ichneumonidae de Tarapacá. 1. Subfamily Ephialtinae (Hymenoptera). Idesia 1979, 5, 157–187. [Google Scholar]
  70. Broad, G.R.; Sääksjärvi, I.E.; Veijalainen, A.; Notton, D.G. Three new genera of Banchinae (Hymenoptera: Ichneumonidae) from Central and South America. J. Nat. Hist. 2011, 45, 1311–1329. [Google Scholar] [CrossRef]
  71. Porter, C.C. Joppini (Hymenoptera: Ichneumonidae) of Tarapacá. Fla. Entomol. 1980, 63, 226–242. [Google Scholar] [CrossRef]
  72. Townes, H.K. Revisions of twenty genera of Gelini (Ichneumonidae). Mem. Amer. Ent. Inst. 1983, 35, 1–281. [Google Scholar]
  73. Wahl, D.B. Cladistics of the genera of Mesochorinae (Hymenoptera: Ichneumonidae). Syst. Entomol. 1993, 18, 371–387. [Google Scholar] [CrossRef]
  74. Dasch, C.E. Neotropic Mesochorinae (Hymenoptera: Ichneumonidae). Mem. Amer. Ent. Inst. 1974, 22, 1–509. [Google Scholar]
  75. Lee, J.W. A revision of the genus Cidaphus (Hymenoptera: Ichneumonidae: Mesochorinae). Contrib. Am. Entomol. Inst. 1991, 5, 1–48. [Google Scholar]
  76. Roman, A. Ichneumoniden von Juan Fernandez, 3: "The Natural History of Juan Fernandez and Easter Island"; Skottsberg, C., Ed.; New York Botanical Garden: New York, NY, USA, 1920; pp. 289–295. [Google Scholar]
  77. Bordera, S.; Palacio, E.; Martinez, J.J. The Neotropical species of Clistopyga (Hymenoptera, Ichneumonidae, Pimplinae). Part V: The C. diazi species group, with the description of three new species. Zootaxa 2019, 4661, 545–565. [Google Scholar] [CrossRef]
  78. Porter, C.C. A revision of Cosmiocryptus in the coastal desert of Peru and north Chile (Hymenoptera: Ichneumonidae). Psyche 1985, 92, 463–492. [Google Scholar] [CrossRef]
  79. Porter, C.C. Cyclaulus in the Peruvian coastal desert (Hymenoptera: Ichneumonidae). Fla. Entomol. 1976, 59, 353–360. [Google Scholar] [CrossRef]
  80. Haliday, A.H. Descriptions of the Hymenoptera collected by Captain P.P. King, R.N., F.R.S., in the survey of the Straits of Magellan. Trans. Linn. Soc. Lond. 1836, 17, 316–331. [Google Scholar]
  81. Guerrero, S.M.A.; Lamborot, C.L.; Arretz, V.P. Parasitic action of three Hymenopteran species on the larvae and pupae of Plutella xylostella in a cabbage field. Rev. Chil. Entomol. 1986, 13, 17–20. [Google Scholar]
  82. Muriel, S.B.; Grez, A.A. Abundancia y parasitismo de Plutella xylostella L. (Lepidoptera: Plutellidae) en parches de Brassica oleracea con diferente forma y vegetacion circundante. Actu. Biol. 2003, 25, 99–103. [Google Scholar] [CrossRef]
  83. Brèthes, J. Quelques Ichneumonidae Nouveaux. Bol. Mus. Nac. Hist. Nat. 1913, 5, 310–312. [Google Scholar] [CrossRef]
  84. Diller, E.; Schoenitzer, K. Verbreitung neotropischer Phaeogenini der Gattung Dicaelotus Wesmael (1845), mit Beschreibungen neuer Taxa (Insecta, Hymenoptera, Ichneumonidae, Ichneumoninae, Phaeogenini). Linz. Biol. Beitr. 2009, 41, 1089–1102. [Google Scholar]
  85. Dasch, C.E. The neotropic Diplazontinae. Contrib. Am. Entomol. Inst. 1964, 1, 1–77. [Google Scholar]
  86. Ruiz, P.F. Himenopteros de la Provincia de Coquimbo. Rev. Ch. Hist. Nat. 1936, 40, 159–169. [Google Scholar]
  87. Brèthes, J. Cueillette d'insectes au Rio Blanco. Rev. Ch. Hist. Nat. 1919, 22, 161–171. [Google Scholar]
  88. Townes, H.K. The genera of Ichneumonidae, Part 1. Mem. Am. Ent. Inst. 1969, 11, 1–300. [Google Scholar] [CrossRef]
  89. Broad, G.R. A review of the genus Geraldus Fitton (Hymenoptera: Ichneumonidae: Banchinae), with description of a new species. J. Nat. Hist. 2010, 44, 1419–1425. [Google Scholar] [CrossRef]
  90. Quicke, D.L.J.; Laurenne, N.M.; Fitton, M.G.; Broad, G.R. A thousand and one wasps: A 28S rDNA and morphological phylogeny of the Ichneumonidae (Insecta: Hymenoptera) with an investigation into alignment parameter space and elision. J. Nat. Hist. 2009, 43, 1305–1421. [Google Scholar] [CrossRef]
  91. Porter, C.C. A Taxonomic Revision of the Chilean Groteini. Acta Entomol. Ch. 1989, 15, 143–162. [Google Scholar]
  92. Brèthes, J. Quelques Hyménopteres du Chili. Rev. Ch. Hist. Nat. 1916, 20, 83–89. [Google Scholar]
  93. Porter, C.C. Habronyx Foerster (Hymenoptera: Ichneumonidae: Anomaloninae) in Andean and Neantarctic South America with description of new species from Bolivia and Chile. Insecta Mundi 2007, 20, 1–8. [Google Scholar]
  94. Porter, C.C. Ichneumoninae of the genera Hoplismenus and Platylabus in Tarapacá (Chile) (Hymenoptera: Ichneumonidae). Idesia 1986, 10, 19–28. [Google Scholar]
  95. Lanfranco, L.D. Ichneumonidos (Hymenoptera-Ichneumonidae) del Parque Nacional “Vicente Perez Rosales”. An. Mus. Hist. Nat. 1974, 7, 261–267. [Google Scholar]
  96. Porter, C.C. New Chilean Itamuton (Hymenoptera: Ichneumonidae: Mesostenini) reared from Elicura litigator (Neuroptera: Myrmeleontidae). Fla. Entomol. 1989, 72, 660–664. [Google Scholar] [CrossRef]
  97. Porter, C.C. A revision of the South American species of Itoplectis (Hymenoptera, Ichneumonidae). Acta Zool. Lill. 1970, 26, 63–104. [Google Scholar]
  98. Porter, C.C. The Transantarctic genus Labena (Hymenoptera: Ichneumonidae: Labenini) in Chile. Insecta Mundi 2005, 19, 177–185. [Google Scholar]
  99. Araujo, R.O.; Vivallo, F. Taxonomic revision of Lepidura Townes, 1971 (Hymenoptera: Ichneumonidae: Mesochorinae) with the description of three new species, new distribution records and a key to the all known species. Zootaxa 2018, 4514, 215–229. [Google Scholar] [CrossRef] [PubMed]
  100. Gupta, V.K. A revision of the genus Microcharops (Hymenoptera: Ichneumonidae). Cont. Am. Ent. Inst. 1987, 23, 1–42. [Google Scholar]
  101. Araujo, R.O.; Di Giovanni, F. Description of the first species of Nemeritis Holmgren (Hymenoptera: Ichneumonidae: Campopleginae) from the Southern Hemisphere, with a key to the New World species. Zootaxa 2021, 5023, 263–272. [Google Scholar] [CrossRef] [PubMed]
  102. Lamborot, L.; Arretz, P.; Guerrero, M.A.; Araya, J.E. Parasitism of eggs and larvae of Copitarsia turbata (Herrich & Schaffer) (Lepidoptera: Noctuidae) on horticultural crops in the Metropolitan Region of Chile. Acta Ent. Ch. 1995, 19, 129–133. [Google Scholar]
  103. Porter, C.C. First record of Phrudinae (Hymenoptera: Ichneumonidae) from South America with notice of a new genus and species from Chile. J. N. Y. Entomol. Soc. 1993, 101, 130–134. [Google Scholar]
  104. Porter, C.C. Picrocryptoides: A new genus of the tribe Mesostenini from southern South America (Hymenoptera, Ichneumonidae). Psyche 1965, 72, 167–174. [Google Scholar] [CrossRef]
  105. Porter, C.C. A revision of the South American species of Coccygomimus (Hymenoptera, Ichneumonidae). Studia Ent. 1970, 13, 1–192. [Google Scholar]
  106. Neira, C.M.; Ruff, F.J.; Mundaca, B.N. Natural enemies of Pieris brassicae L. (Lepidoptera: Pieridae) from cultivated crucifers in Valdivia. Agro-Ciencia 1989, 5, 5–10. [Google Scholar]
  107. Lanfranco, L.D.; Cerda, L. Coccygomimus fuscipes (Hym.: Ichneumonidae): Un parasitoide nativo de la Polilla del Brote, Rhyacionia buoliana (Lep.: Tortricidae). Bosque 1986, 7, 36–37. [Google Scholar] [CrossRef]
  108. Araujo, R.O.; Vivallo, F.; Santos, B.F. Discovery of two new Andean species of Scolomus (Townes & Townes), with a key to all known species (Hymenoptera: Ichneumonidae: Metopiinae). Zootaxa 2018, 4429, 189–194. [Google Scholar] [PubMed]
  109. Walkley, L.M. A second species of Ichneumonidae belonging to Scolomus Townes (Hymenoptera). Proc. Entomol. Soc. Wash. 1962, 64, 231–233. [Google Scholar]
  110. Cameron, P. On some Hymenoptera (chiefly undescribed) from Japan and the Pacific. Proc. Trans. Nat. Hist. Soc. Glasg. 1886, 1, 263–276. [Google Scholar]
  111. Cameron, P. Descriptions of one new genus and some new species of parasitic Hymenoptera. Mem. Proc. Manch. Lit. Phil. Soc. 1887, 26, 117–136. [Google Scholar]
  112. Porter, C.C. Certonotus Kriechbaumer (Hymenoptera: Ichneumonidae), an Australian genus newly recorded in South America. Fla Entomol. 1981, 64, 235–244. [Google Scholar] [CrossRef]
  113. Porter, C.C. Trachysphyrus and the new genus Aeliopotes in the coastal desert of Peru and north Chile (Hymenoptera: Ichneumonidae). Psyche 1985, 92, 513–545. [Google Scholar] [CrossRef]
  114. Diller, E.; Riedel, M.; Melzer, R.R.; Schoenitzer, K. Neotropische Phaeogenini mit Beschreibung neuer Arten der Gattung Tycherus Föerster, 1869 (Hymenoptera, Ichneumonidae, Ichneumoninae, Phaeogenini). Mitt. Müench. Entomol. Ges. 2009, 99, 3–95. [Google Scholar]
  115. Diller, E. Neue Taxa der Gattung Tycherus Foerster, (1869), aus der Neotropis, ein Nachtrag (Insecta; Hymenoptera, Ichneumonidae, Ichneumoninae, Phaeogenini). Entomofauna 2010, 31, 413–428. [Google Scholar]
  116. Porter, C.C. A new genus of the tribe Mesostenini from Chile (Hymenoptera, Ichneumonidae). Psyche 1963, 70, 117–119. [Google Scholar] [CrossRef]
  117. Durán, M.L. Las cuncunas de los pinos, un problema de entomología forestal. Agric. Tec. 1944, 4, 17–25. [Google Scholar]
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Figure 1. Darwin wasp representatives from Chile (in vivo): (a) Trachysphyrus sp. (Cryptinae); (b) Ichneumoninae sp.; (c) Dotocryptus sp. (Cryptinae); (d) Macrogrotea sp. (Labeninae); (e) Trachysphyrus sp. (Cryptinae); (f) Hoplismenus sp. (Ichneumoninae).
Figure 1. Darwin wasp representatives from Chile (in vivo): (a) Trachysphyrus sp. (Cryptinae); (b) Ichneumoninae sp.; (c) Dotocryptus sp. (Cryptinae); (d) Macrogrotea sp. (Labeninae); (e) Trachysphyrus sp. (Cryptinae); (f) Hoplismenus sp. (Ichneumoninae).
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Figure 2. Study area: (left) administrative regions; (right) ecoregions according to Dinerstein et al. [18].
Figure 2. Study area: (left) administrative regions; (right) ecoregions according to Dinerstein et al. [18].
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Figure 3. Number of species per genus among Chilean Ichneumonidae (only genera with determined species—n = 102).
Figure 3. Number of species per genus among Chilean Ichneumonidae (only genera with determined species—n = 102).
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Figure 4. Ecoregions and species/genera richness. Ecoregions on the border with Argentina, Bolivia, and Peru only include data for Chile (only genera with determined species—n = 102).
Figure 4. Ecoregions and species/genera richness. Ecoregions on the border with Argentina, Bolivia, and Peru only include data for Chile (only genera with determined species—n = 102).
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Figure 5. Species and genera richness for each administrative region (only genera with determined species—n = 102).
Figure 5. Species and genera richness for each administrative region (only genera with determined species—n = 102).
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Figure 6. The richness of Chilean ichneumonid species plotted in 0.5 × 0.5 cells: (left) number of genera; (right) number of species.
Figure 6. The richness of Chilean ichneumonid species plotted in 0.5 × 0.5 cells: (left) number of genera; (right) number of species.
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Figure 7. Species-level richness of Chilean ichneumonids is concentrated in mid-latitudes between 32° and 43° degrees south. Several cells (0.5 × 0.5 degrees) with the highest numbers occur in the contact zone between the Valdivian Forest and the Chilean Matorral ecoregions.
Figure 7. Species-level richness of Chilean ichneumonids is concentrated in mid-latitudes between 32° and 43° degrees south. Several cells (0.5 × 0.5 degrees) with the highest numbers occur in the contact zone between the Valdivian Forest and the Chilean Matorral ecoregions.
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Table 1. Darwin wasp genera elements from Chile (n = 139) (see Section 2).
Table 1. Darwin wasp genera elements from Chile (n = 139) (see Section 2).
ElementsGenera (No.)%
1Cosmopolitan5036
2Endemic2921
3Neotropical2216
4Holarctic–Oriental1914
5South-temperate1611
6Australasian32
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Pádua, D.G.; Moreira-Muñoz, A.; Morales-Fierro, V.; Araujo, R.O. Chilean Darwin Wasps (Ichneumonidae): Biogeographic Relationships and Distribution Patterns. Insects 2024, 15, 415. https://doi.org/10.3390/insects15060415

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Pádua DG, Moreira-Muñoz A, Morales-Fierro V, Araujo RO. Chilean Darwin Wasps (Ichneumonidae): Biogeographic Relationships and Distribution Patterns. Insects. 2024; 15(6):415. https://doi.org/10.3390/insects15060415

Chicago/Turabian Style

Pádua, Diego G., Andrés Moreira-Muñoz, Vanezza Morales-Fierro, and Rodrigo O. Araujo. 2024. "Chilean Darwin Wasps (Ichneumonidae): Biogeographic Relationships and Distribution Patterns" Insects 15, no. 6: 415. https://doi.org/10.3390/insects15060415

APA Style

Pádua, D. G., Moreira-Muñoz, A., Morales-Fierro, V., & Araujo, R. O. (2024). Chilean Darwin Wasps (Ichneumonidae): Biogeographic Relationships and Distribution Patterns. Insects, 15(6), 415. https://doi.org/10.3390/insects15060415

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