Molecular Insights Into the Biogeography and Species Status of New Zealand's Endemic Latrodectus Spider Species; L. Katipo and L. Atritus (Araneae, Theridiidae)

Griffiths, James W.; Paterson, Adrian M.; Vink, Cornelis

doi:10.1636/s04-11.1

Cited by 14 publications

(17 citation statements)

References 37 publications

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“…pletus complex attests to the distinctness of these species. This distance is similar to or greater than that observed among New Zealand onychophorans and insects (Trewick 2000;Trewick & Wallis 2001), about twice that observed for the oldest clades of Hawaiian tetragnathid spiders (Gillispie 1999), and almost ten times the greatest distance that separates populations of New Zealand's two widow spider species (Griffiths et al 2005). A rate of 2% (e.g., Brown et al 1979;DeSalle et al 1987;Juan, et al 1995;Gillespie 1999;Trewick & Morgan-Richards 2005) This date suggests an early to middle Pliocene origin for these species through geographical isolation on the NI and SI, respectively.…”

Section: Discussionsupporting

confidence: 75%

“…As demonstrated by studies cited above, molecular data are well suited to these tasks. In this study we use two mitochondrial genes, 16S and NADH dehydrogenase subunit ND1, both of which have been employed successfully to reconstruct the phylogenies of spider populations and species (Hedin 1997a, b;Gillespie 1999;Hedin & Maddison 2001;Bond et al 2001;Masta & Maddison 2002;Maddison & Hedin 2003;Vink & Paterson 2003;Griffiths et al 2005;Garb & Gillespie 2006).…”

Section: Introductionmentioning

confidence: 99%

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Genetic relationships of Amaurobioides (Anyphaenidae) spiders from the southeastern coast of New Zealand

Opell¹,

Berger²,

M.³

et al. 2007

Zootaxa

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Members of the genus Amaurobioides construct silk retreats in rock crevices of the marine spray zone, a harsh and unusual habitat for spiders. This study expands the distribution records of three morphological species of Amaurobioides found on the eastern and southern coasts of New Zealand's South Island and uses mitochondrial DNA to examine their relationships and characterize their dispersal capabilities. Both 16S and ND1 sequences distinguish A. pletus found on the northeastern coast from a complex of two southern species comprised of A. maritimus from the mainland and A. picunus from Stewart Island. Neither 16S DNA nor ND1 protein separates these southern species. However, ND1 parsimony and likelihood analyses place 10 of 11 Stewart Island specimens in a clade of low support that nests deeply within A. maritimus. A nested haplotype analysis characterizes A. maritimus and A. picunus populations as having restricted gene flow/dispersal but with some long distance dispersal. Genetic distances between A. pletus and the A. maritimus-A. picunus complex indicate a Pliocene origin, whereas distances between A. maritimus and A. picunus suggest a Pleistocene divergence.

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Section: Discussionsupporting

confidence: 75%

Section: Introductionmentioning

confidence: 99%

Genetic relationships of Amaurobioides (Anyphaenidae) spiders from the southeastern coast of New Zealand

Opell¹,

Berger²,

M.³

et al. 2007

Zootaxa

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show abstract

“…Griffith et al (2005) found that genetic divergence between katipo and redbacks was equivalent to that of two very closely related species and that katipo are relatively recent arrivals into New Zealand. Likewise, the diverse Lycosid wolf spiders of New Zealand share a close relationship to Australian relatives and show a New Zealand species radiation (approx.…”

Section: (Iii) Other Examplesmentioning

confidence: 97%

Evolution of New Zealand's terrestrial fauna: a review of molecular evidence

Goldberg

Trewick

Paterson

2008

Phil. Trans. R. Soc. B

119

111

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New Zealand biogeography has been dominated by the knowledge that its geophysical history is continental in nature. The continental crust (Zealandia) from which New Zealand is formed broke from Gondwanaland ca 80 Ma, and there has existed a pervading view that the native biota is primarily a product of this long isolation. However, molecular studies of terrestrial animals and plants in New Zealand indicate that many taxa arrived since isolation of the land, and that diversification in most groups is relatively recent. This is consistent with evidence for species turnover from the fossil record, taxonomic affinity, tectonic evidence and observations of biological composition and interactions. Extinction, colonization and speciation have yielded a biota in New Zealand which is, in most respects, more like that of an oceanic archipelago than a continent.

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“…Most molecular studies have suggested that groups found in New Zealand, rather than being remnants from Gondwanan times, are actually much more recent in origin and have colonized across the significant water gaps around New Zealand. Examples include southern beeches (Swenson et al 2001;Knapp et al 2005), spiders (Griffiths, Paterson & Vink, 2005), moths (Brown, Emberson & Paterson, 1999), kiwis (Cooper et al 1992) and various flightless insects (Trewick, 2000). Only a few species have levels of molecular variation that are compatible with a Gondwanan origin, such as tuatara (Rest et al 2003), leiopelmatid frogs (Roelants & Bossuyt, 2005), kauri (Stöckler, Daniel & Lockhart, 2002) and terrestrial gastropods (McDowall, 2004).…”

Section: G the Moa's Ark Heritagementioning

confidence: 99%

The Waipounamu Erosion Surface: questioning the antiquity of the New Zealand land surface and terrestrial fauna and flora

et al. 2008

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-The Waipounamu Erosion Surface is a time-transgressive, nearly planar, wave-cut surface. It is not a peneplain. Formation of the Waipounamu Erosion Surface began in Late Cretaceous time following break-up of Gondwanaland, and continued until earliest Miocene time, during a 60 million year period of widespread tectonic quiescence, thermal subsidence and marine transgression. Sedimentary facies and geomorphological evidence suggest that the erosion surface may have eventually covered the New Zealand subcontinent (Zealandia). We can find no geological evidence to indicate that land areas were continuously present throughout the middle Cenozoic. Important implications of this conclusion are: (1) the New Zealand subcontinent was largely, or entirely, submerged and (2) New Zealand's present terrestrial fauna and flora evolved largely from fortuitous arrivals during the past 22 million years. Thus the modern terrestrial biota may not be descended from archaic ancestors residing on Zealandia when it broke away from Gondwanaland in the Cretaceous, since the terrestrial biota would have been extinguished if this landmass was submerged in OligoceneEarly Miocene time. We conclude that there is insufficient geological basis for assuming that land was continuously present in the New Zealand region through Oligocene to Early Miocene time, and we therefore contemplate the alternative possibility, complete submergence of Zealandia.

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Molecular Insights Into the Biogeography and Species Status of New Zealand's Endemic Latrodectus Spider Species; L. Katipo and L. Atritus (Araneae, Theridiidae)

Cited by 14 publications

References 37 publications

Genetic relationships of Amaurobioides (Anyphaenidae) spiders from the southeastern coast of New Zealand

Genetic relationships of Amaurobioides (Anyphaenidae) spiders from the southeastern coast of New Zealand

Evolution of New Zealand's terrestrial fauna: a review of molecular evidence

The Waipounamu Erosion Surface: questioning the antiquity of the New Zealand land surface and terrestrial fauna and flora

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