Phylogeny and biogeography of southern hemisphere high-mountain Cardamine species (Brassicaceae)

The biogeography and phylogenetic relationships of Southern Hemisphere Cardamine L. species were analysed using nuclear rDNA ITS and cpDNA (trnL intron, trnL-F spacer) sequences. The analyses indicate that the montane species from Australia and New Zealand (C. corymbosa Hook.f., C. lilacina Hook. and C. debilis Banks ex DC.) are closely related to the South American C. glacialis (Forster) DC. Low sequence divergence between C. glacialis and the Australian and New Zealand species suggests relatively recent (less than 500 000 years ago) long-distance dispersal from South America to Australasia, or vice versa. The relationship of the New Guinean species, C. keysseri O.E.Schulz and C. africana L., to the Australian species remained unresolved. Accessions of the high-mountain, pan-continental species C. africana from Africa, South America and New Guinea differed widely in their positions on both the ITS tree and the cpDNA tree, suggesting a polyphyletic origin. The East African high-mountain species C. obliqua Hochst. grouped with European species on the cpDNA tree. The African species, C. trichocarpa Hochst., formed a sister group to all the other Cardamine species analysed.

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Phylogenetic relationships within Dendroligotrichum and Polytrichadelphus (Polytrichaceae, Polytrichopsida) in the Palaeoaustral region. Studies in austral temperate rainforest bryophytes 32

Australian Systematic Botany ◽

10.1071/sb07005 ◽

2008 ◽

Vol 21 (1) ◽

pp. 39 ◽

Cited By ~ 6

Author(s):

Michael Stech ◽

Tanja Pfeiffer ◽

Wolfgang Frey

Keyword(s):

New Zealand ◽

South America ◽

Phylogenetic Relationships ◽

Sequence Data ◽

Sequence Divergence ◽

Trnl Intron ◽

South American ◽

South American Species ◽

Southern South America ◽

The One

Plastid trnT–F and atpB–rbcL spacer sequences as well as AFLP fingerprints are utilised to infer phylogenetic relationships of Dendroligotrichum and Polytrichadelphus taxa (Polytrichaceae) in the palaeoaustral region. Phylogenies based on DNA sequence data support the monophyly of each genus. Relationships within Dendroligotrichum remain ambiguous owing to low sequence divergence. AFLP fingerprinting, however, allows a clear distinction of all included Dendroligotrichum and Polytrichadelphus taxa at the species level. The morphological, distributional, ecological and molecular differences justify the recognition of the following three species in Dendroligotrichum: D. dendroides (Brid. ex Hedw.) Broth. and D. squamosum (Hook.f. & Wilson) Cardot in southern South America, as well as D. microdendron (Müll. Hal.) G.L.Sm. in New Zealand; and the following two species in Polytrichadelphus: P. magellanicus (Hedw.) Mitt. s.str. in southern South America and P. innovans (Müll. Hal.) A.Jäger in Australia and New Zealand. For Polytrichadelphus, the molecular topologies correspond with a vicariance scenario, with a basic split of taxa in the palaeoaustral region followed by migration of southern South American taxa northwards into the Neotropics. In Dendroligotrichum, substitutions and indels in the trnL intron and atpB–rbcL spacer are ambiguous in supporting either a basic split between the South American species and D. microdendron, similar to the one in Polytrichadelphus, or a trans-oceanic dispersal event between New Zealand and southern South America.

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A molecular phylogeny of the circum-Antarctic Opiliones family Neopilionidae

Invertebrate Systematics ◽

10.1071/is21012 ◽

2021 ◽

Author(s):

Gonzalo Giribet ◽

Kate Sheridan ◽

Caitlin M. Baker ◽

Christina J. Painting ◽

Gregory I. Holwell ◽

...

Keyword(s):

New Zealand ◽

South America ◽

Morphological Study ◽

18S Rrna ◽

New Caledonia ◽

Sister Group ◽

28S Rrna ◽

South American ◽

Australian Species ◽

The Family

The Opiliones family Neopilionidae is restricted to the terranes of the former temperate Gondwana: South America, Africa, Australia, New Caledonia and New Zealand. Despite decades of morphological study of this unique fauna, it has been difficult reconciling the classic species of the group (some described over a century ago) with recent cladistic morphological work and previous molecular work. Here we attempted to investigate the pattern and timing of diversification of Neopilionidae by sampling across the distribution range of the family and sequencing three markers commonly used in Sanger-based approaches (18S rRNA, 28S rRNA and cytochrome-c oxidase subunit I). We recovered a well-supported and stable clade including Ballarra (an Australian ballarrine) and the Enantiobuninae from South America, Australia, New Caledonia and New Zealand, but excluding Vibone (a ballarrine from South Africa). We further found a division between West and East Gondwana, with the South American Thrasychirus/Thrasychiroides always being sister group to an Australian–Zealandian (i.e. Australia + New Zealand + New Caledonia) clade. Resolution of the Australian–Zealandian taxa was analysis-dependent, but some analyses found Martensopsalis, from New Caledonia, as the sister group to an Australian–New Zealand clade. Likewise, the species from New Zealand formed a clade in some analyses, but Mangatangi often came out as a separate lineage from the remaining species. However, the Australian taxa never constituted a monophyletic group, with Ballarra always segregating from the remaining Australian species, which in turn constituted 1–3 clades, depending on the analysis. Our results identify several generic inconsistencies, including the possibility of Thrasychiroides nested within Thrasychirus, Forsteropsalis being paraphyletic with respect to Pantopsalis, and multiple lineages of Megalopsalis in Australia. In addition, the New Zealand Megalopsalis need generic reassignment: Megalopsalis triascuta will require its own genus and M. turneri is here transferred to Forsteropsalis, as Forsteropsalis turneri (Marples, 1944), comb. nov.

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Correction - The Australasian genera of pericomoid Psychodidae (Diptera) and the status of related Enderlein genera in the neotropics

Invertebrate Systematics ◽

10.1071/it9890721c ◽

1989 ◽

Vol 3 (6) ◽

pp. 721

Author(s):

DA Duckhouse

Keyword(s):

New Zealand ◽

Southern Hemisphere ◽

Northern Hemisphere ◽

Sister Group ◽

New Genera ◽

The Status ◽

Taxonomic Problem ◽

Actual Relationship ◽

Made In

Australasian pericomoids, psychodids resembling northern hemisphere species of Pericoma Walker (tribe Pericomini), are mostly members of the tribe Maruinini, here re-defined. Amongst Maruinini, they are like several neotropical genera named by Enderlein (1937), but their actual relationship to Enderlein's genera, and hence their identity, has been a long-standing taxonomic problem. Consideration of extensive new collections and observations made in the southern hemisphere now shows that they consist of the following: Genus Notiocharis Eaton. Tribe Maruinini: genus Didicrum Enderlein, and five new genera, Eremolobulosa, Rotundopteryx, Alloeodidicrurn, Satchellomyia and Ancyroaspis. Of these, the Australian Eremolobulosa is the possible sister group of the European Lobulosa Szabo, and the New Zealand genera Satchellomyia and Ancyroaspis are possible sister groups. Of Enderlein's neotropical genera, five classified by Quate (1963) as synonyms, or in one case a subgenus, of Pericoma (Didicrum, Desmioza, Synmormia, Syntomolaba and Podolepria) are recognised as full genera. A key to Australasian pericomoid genera is provided.

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Molecular Ecology and Systematics of Blue Mussels (Genus Mytilus) (Mytilidae; Bivalvia; Mollusca) in the Southern Hemisphere

10.26686/wgtn.16992421 ◽

2021 ◽

Author(s):

◽

Kristen Marie Westfall

Keyword(s):

Gene Flow ◽

New Zealand ◽

South America ◽

Southern Hemisphere ◽

Northern Hemisphere ◽

Molecular Ecology ◽

Population Subdivision ◽

Kerguelen Islands ◽

Blue Mussels ◽

The World

<p>The Mytilus edulis species complex, comprised of M. edulis, M. galloprovincialis and M. trossulus, is antitropically distributed in temperate coastal regions of all oceans and main seas of the world. This genus has been heavily studied in the Northern hemisphere but Southern hemisphere populations have received much less attention. This thesis aims to place Southern hemisphere blue mussels into global evolutionary relationships among Mytilus species and investigate aspects of their molecular ecology, including, effects of non-native Northern hemisphere species introductions, biogeography across the Southern hemisphere, regional phylogeographic patterns and population genetics within New Zealand. Southern hemisphere blue mussel phylogenetic reconstruction resulted in the detection of a monophyletic M. galloprovincialis lineage. Two new molecular markers developed with specificity for this lineage and congruence among phylogenetic investigations indicates a panhemispheric distribution of this M. galloprovincialis lineage with implications for naming a new sibling species of the M. edulis complex. This proposed new species, M. meridianus, is distributed in South America, the Kerguelen Islands, New Zealand and Australia at latitudes between ~ 30°S and ~ 55°S. Non-native M. galloprovincialis introduced from the Northern hemisphere have been present in NZ, Australia and Chile for at least ten years and hybridise with native blue mussels. Introgression is observed in New Zealand and Australian but not Chilean hybrid regions. The limited number of introduced mussels in Australia induces hybrid swamping of non-native alleles but an interlineage gender bias towards non-native maternal parents may result in eventual loss of the unique genomic content of native blue mussels in NZ. Southern hemisphere blue mussels form a monophyletic sister clade to a haplogroup shared by Northern hemisphere M. edulis and M. galloprovincialis. Although single gene histories are not congruent with respect to evolutionary relationships within the Northern hemisphere due to introgressive hybridisation after speciation, it is clear that Southern hemisphere blue mussels arose from a species native to the northeast Atlantic Ocean after speciation of the three ‘M. edulis complex’ members. Within the Southern hemisphere monophyletic clade lies three reciprocally monophyletic clades restricted to the geographic regions South America/Kerguelen Islands, New Zealand and Australia. Phylogeographic analysis indicates past gene flow between South American/Kerguelen Islands and New Zealand populations that has ceased at present day and ongoing gene flow between South America and the Kerguelen Islands likely via the West Wind Drift. Within NZ, population subdivision inferred from mtDNA indicates genetic variation is distributed within an east-west phylogeographic split on the North Island. These populations experienced gene flow in the past that has ceased at present day. Microsatellite allele frequencies indicate a different population subdivision within the northwest North Island that has been narrowed down to a 15 km stretch of coastline in a sheltered bay. The abrupt discontinuity within a small geographic area does not conform to classic population subdivision in this broad-cast spawning species, therefore, further investigation into the genomic content of northwest North Island mussels with respect to introgressed non-native genes is warranted. Resolving complex phylogenetic patterns from interspecific introgression is key to understanding the evolutionary history of Southern hemisphere M. galloprovincialis. Further characterisation of hybrid introgression would increase accuracy of (1) inferences of processes contributing to hybridisation dynamics and (2) population subdivision in NZ. Probing the basis for variation of hybridisation dynamics would help to predict the outcomes of Northern hemisphere M. galloprovincialis introductions in other areas of the world.</p>

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Systematics of the spider subfamily Hexathelinae (Dipluridae : Mygalomorphae : Arachnida)

Australian Journal of Zoology ◽

10.1071/zo9780841a ◽

1978 ◽

Vol 26 (4) ◽

pp. 841

Author(s):

RJ Raven

Keyword(s):

New Species ◽

New Zealand ◽

South America ◽

Type Species ◽

Sister Group ◽

New Genera ◽

Australian Species ◽

To Receive

Two new genera, Plesiothele and Bymainiella, are erected to receive all the Australian species of the subfamily Hexathelinae, which now comprises four genera, including Hexathele with 20 species from New Zealand, and Scotinoecus with two species from South America. Plesiothele is a monotypic Tasmanian genus, type-species Hexathele fentoni Hickman, 1936. Bymainiella comprises 12 new species: B. boycei, B. boydi, B. brindabella, B. cannoni, B. grayi, B. lugubris, B. monteithi, B. montisbossi, B. otwayensis, B. polesoni, B. tubrabucca and B. variabilis; also B. montana (Hickman, 1927), and B. terraereginae (Raven, 1976), the latter being the type-species. The typespecies of Scotinoecus, S. cinereopilosus, is redescribed, and keys to the genera of the subfamily Hexathelinae, and to the Bymainiella species, are given. Two new indices are introduced to overcome the problem of bilateral variability. Bymainiella is believed to be the sister group of Scotinoecus.

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Bioclimatic Modelling Identifies Suitable Habitat for the Establishment of the Invasive European Paper Wasp (Hymenoptera: Vespidae) across the Southern Hemisphere

Insects ◽

10.3390/insects11110784 ◽

2020 ◽

Vol 11 (11) ◽

pp. 784

Author(s):

Matthew W. F. Howse ◽

John Haywood ◽

Philip J. Lester

Keyword(s):

South Africa ◽

New Zealand ◽

South America ◽

Southern Hemisphere ◽

Range Expansion ◽

Paper Wasp ◽

Potential Range ◽

Suitable Habitat ◽

Climate Data ◽

Distribution Models

Species distribution models (SDMs) are tools used by ecologists to help predict the spread of invasive species. Information provided by these models can help direct conservation and biosecurity efforts by highlighting areas likely to contain species of interest. In this study, two models were created to investigate the potential range expansion of Polistes dominula Christ (Hymenoptera: Vespidae) in the southern hemisphere. This palearctic species has spread to invade North and South America, South Africa, Australia, and more recently New Zealand. Using the BIOCLIM and MAXENT modelling methods, regions that were suitable for P. dominula were identified based on climate data across four regions in the southern hemisphere. In South America areas of central Chile, eastern Argentina, parts of Uruguay, and southern Brazil were identified as climatically suitable for the establishment of P. dominula. Similarly, southern parts of South Africa and Australia were identified by the model to be suitable as well as much of the North Island and east of the South Island of New Zealand. Based on outputs from both models, significant range expansion by P. dominula is possible across its more southern invaded ranges.

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Amylostereum areolatum.

10.1079/cpc.108964.20210099949 ◽

2021 ◽

Author(s):

Keyword(s):

South Africa ◽

New Zealand ◽

South America ◽

Southern Hemisphere ◽

North Africa ◽

White Rot ◽

Symbiotic Association ◽

Southern South America ◽

Western Asia ◽

The Usa

Abstract A. areolatum is a basidiomycete that causes a white rot of a broad range of conifers. Its invasiveness arises from a symbiotic association with woodwasps of the genus Sirex. The species Sirexnoctilio is listed as "highly invasive" on the ISSG/IUCN website (ISSG, 2008) and is a Regulated Pest for the USA (APHIS, 2009a). The wasp and the fungus are native to Europe, North Africa and western Asia where their damage is considered secondary (Spradbery and Kirk, 1978). Introduced to areas of the Southern Hemisphere where exotic pine species are grown in plantations, these organisms have caused major losses. The insect invaded New Zealand by at least 1900, but did not cause serious concern until the 1940s (Talbot, 1977). It later spread to Tasmania and the southern parts of Australia and the wasp/fungus association was introduced into southern South America, beginning in Uruguay in 1980 (Ciesla, 2003). Invasion of South Africa occurred in 1994 (Tribe, 1995). Woodwasps are repeatedly detected in material imported to the USA, but were successfully excluded until 2004 (Wilson et al., 2009). The wasp and fungus were later found in nearby Canada (Ontario), although apparently due to a separate introduction (Bergeron et al., 2008; Wilson et al., 2009). Recent surveys found the wasp in four states of the USA (Evans-Goldner and Bunce, 2009) and 25 counties of Ontario in Canada (Shields, 2009). Schiff (2008) summarizes differences in complexity of the ecological situations in the Southern Hemisphere countries and North America that could affect spread and impact of the fungus and wasp.

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Floristics of the South American Páramo Moss Flora

Bryophyte Diversity and Evolution ◽

10.11646/bde.2.1.10 ◽

1990 ◽

Vol 2 (1) ◽

pp. 127-132

Author(s):

Dana Griffin III

Keyword(s):

South America ◽

Southern Hemisphere ◽

Cloud Forest ◽

South American ◽

Long Distance Dispersal ◽

The South ◽

Long Distance ◽

Late Pliocene ◽

Northern Andes ◽

The Past

The South American paramos appeared in Pliocene times and persist to the present day. The moss flora of this habitat consists of an estimated 400 species that comprise 8 floristic groups. In Venezuela these groups and their percent representation are as follows: neotropical 37%, Andean 26%, cosmopolitan 18%, Andean-African 8%, neotropical-Asiatic 3%, neotropical-Australasian 2%, temperate Southern Hemisphere 2% and northern boreal-temperate 2%. Acrocarpous taxa outnumber pleurocarps by nearly 3:1. The neotropical and Andean floristic stocks likely were present prior to late Pliocene orogenies that elevated the cordillera above climatic timberlines. These species may have existed in open, marshy areas (paramillos) or may have evolved from cloud forest ancestors. Taxa of northern boreal- temperate affinities, including those with Asiatic distributions, probably arrived in the paramos during the Pleistocene, a period which may also have seen the establishment in the Northern Andes of some cosmopolitan elements. Species with temperate Southern Hemisphere and Australasian affinities likely spread first to austral South America thence migrated northward during a cool, moist interval sometime over the past 2.5-3 million years or may have become established in the paramos as a result of long- distance dispersal.

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Biogeographic congruence in the South Pacific

Australian Systematic Botany ◽

10.1071/sb9910127 ◽

1991 ◽

Vol 4 (1) ◽

pp. 127 ◽

Cited By ~ 18

Author(s):

O Seberg

Keyword(s):

New Zealand ◽

South America ◽

Southern Hemisphere ◽

Classical Problem ◽

Distribution Patterns ◽

General Area ◽

Southern South America ◽

South Eastern ◽

Eastern Australia ◽

South Eastern Australia

Ever since J. D. Hooker's famous 'Introductory Essay' to Flora NOVE-Zelandise, a classical problem in biogeography has been to give a casual explanation of southern hemisphere distribution patterns. An attempt is made to see whether the cladograms for the circum-Pacific areas (South America, New Zealand, Tasmania and Australia) are congruent. The area cladograms are derived from Nothofagus (Fagacae), Embothriinae (Protaceae), Oreobolus (Cyperaceae), Cyttaria (Helotiales) and Eriococcidae (Homoptera). The resulting general area cladogram showing southern South America as the sister-area to New Zealand, south-eastern Australia and Tasmania, and Tasmania plus south-eastern Australia as sister-areas to New Zealand are compared with different geological hypotheses for the area. The biological area cladogram is shown to be congruent with widely different geological hypotheses.

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Southern hemisphere distributional patterns in plant bugs (Hemiptera:Miridae:Phylinae): Xiphoidellus, gen. nov. from Australia and Ampimpacoris, gen. nov. from Argentina, show transantarctic relationships

Invertebrate Systematics ◽

10.1071/is10002 ◽

2010 ◽

Vol 24 (5) ◽

pp. 473 ◽

Cited By ~ 11

Author(s):

Christiane Weirauch ◽

Randall T. Schuh

Keyword(s):

New Zealand ◽

South America ◽

Sister Group ◽

Morphological Characters ◽

Southern South America ◽

Clear Cut ◽

Distributional Patterns ◽

Close Relationship ◽

Tree Topologies ◽

Cladistic Analyses

Transantarctic distributional patterns are common in many groups of insects and plants including Coleorrhyncha, the sister group of Heteroptera. In contrast, evidence for such patterns within Heteroptera, or true bugs, is rare. We here describe two new genera of Phylini (Miridae : Phylinae) – Xiphoidellus, gen. nov. from Australia with six included species, and the monotypic Ampimpacoris, gen. nov. from Argentina. Xiphoidellus shows relationships to taxa in New Zealand and southern South America. Two sets of cladistic analyses, using equal and implied weights approaches, analyse relationships of the seven new species and 19 or 29 additional phyline taxa using 54 and 45 morphological characters, respectively. Both analyses support the New Zealand endemic genus Xiphoides Eyles & Schuh as the sister group to the Australian Xiphoidellus; Araucanophylus pacificus Carvalho from Chile is the sister taxon to the Xiphoides + Xiphoidellus clade. Affinities of the monotypic genus Ampimpacoris, gen. nov. are less clear cut and may be with a clade of Australian plant bugs or a Nearctic taxon. A primary Brooks parsimony analysis, based on one of the tree topologies, resulted in an area cladogram that proposes a close relationship between Australia and New Zealand, with southern South America being the sister to that area. This pattern differs from the classical vicariance pattern reported for many groups of insects, but is consistent with the ‘southern pattern’ frequently observed in plants.

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