Testing Geology with Biology: Plate Tectonics and the Diversification of Microhylid Frogs in the Papuan Region.

IF 2.2 4区 生物学 Q2 BIOLOGY
Ethan C Hill, Diana F Gao, Dan A Polhemus, Claire J Fraser, Bulisa Iova, Allen Allison, Marguerite A Butler
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引用次数: 0

Abstract

Studies of the Papuan region have provided fundamental insights into the evolutionary processes generating its exceptional biodiversity, but the influence of geological processes merits further study. Lying at the junction of five tectonic plates, this region has experienced a turbulent geological history that has not only produced towering mountains allowing elevational specialization and island archipelagos with varying degrees of isolation promoting vicariance, but also active margins where land masses have collided and been subsequently rifted apart creating a mosaic of intermixed terranes with vastly different geological histories. Asterophryine frogs are a hyperdiverse clade representing half the world's microhylid diversity (over 360 species) centered on New Guinea and its satellite islands. We show that vicariance facilitated by geological history explains this far and wide distribution of a clade that should have poor dispersal abilities. We recovered a mainland tectonic unit, the East Papua Composite Terrane (EPCT), as the center of origin for Asterophryinae and no fewer than 71 instances of what appear to be long-distance dispersal events, 29 of which are between mainland regions, with 42 from the mainland to the islands, some presently as far as 200 km away from source populations over open ocean. Furthermore, we find strong support for a "Slow and Steady" hypothesis for the formation of the northern margin of New Guinea by many separate accretion events during the Miocene, over other major geological alternatives, consistent with the 20 M year age of the clade and arrival via the EPCT. In addition, the historical biogeography of our frogs strongly supports an affiliation of the Louisiade Archipelago and Woodlark Island with the Owen Stanley Range on the EPCT, and the recent proximity of the large New Britain Island. Our results show that Asterophryinae did not have to repeatedly and independently disperse across large ocean barriers to the offshore islands, against the predictions of island biogeography theory, but that the current distribution can be explained through vicariance and short-distance oceanic dispersal as historical land connections disappeared and islands slowly became separated from each other. We show that islands have a life history, changing in distance from other land masses, with consequent opportunities for dispersal, isolation, and cladogenesis of their biotas. More broadly, we can begin to see how the geological history of the Papuan region can result in the rapid accumulation and staggering number of extant species.

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用生物学检验地质学:巴布亚地区的板块构造和微水螅蛙的多样化。
对巴布亚地区的研究为产生其独特的生物多样性的进化过程提供了基本的见解,但地质过程的影响值得进一步研究。该地区位于五个构造板块的交汇处,经历了动荡的地质历史,不仅产生了高耸的山脉,使海拔专业化,岛屿群岛与不同程度的隔离促进了差异,而且还产生了活跃的边缘地带,在那里,陆地块碰撞并随后被撕裂,形成了具有截然不同地质历史的混合地形的马赛克。星形蛙是一个高度多样化的分支,代表了以新几内亚及其附属岛屿为中心的世界上一半的微杂生物多样性(超过360种)。我们的研究表明,由地质历史促成的变异解释了这种远而广泛的分布,这种分布应该具有较差的扩散能力。我们发现了一个大陆构造单元,即东巴布亚复合地层(EPCT),作为Asterophryinae的起源中心,并发现了不少于71个似乎是长距离扩散事件的实例,其中29个发生在大陆地区之间,42个从大陆到岛屿,其中一些目前距离原始种群200公里远。此外,我们发现“缓慢而稳定”的假说强有力地支持了新几内亚北缘在中新世期间由许多单独的沉积事件形成的假说,而不是其他主要的地质假说,与进化枝的2000万年年龄和通过EPCT到达的假说相一致。此外,我们的青蛙的历史生物地理学有力地支持了路易斯安那群岛和伍德拉克岛与EPCT上的欧文斯坦利山脉的隶属关系,以及最近大的新不列颠岛的邻近。我们的研究结果表明,Asterophryinae不需要像岛屿生物地理学理论预测的那样,反复地、独立地跨越大型海洋屏障扩散到近海岛屿,而是可以通过历史上陆地联系消失和岛屿慢慢分离的间隙性和短距离海洋扩散来解释当前的分布。我们表明,岛屿有一个生命史,随着与其他陆地块的距离的变化,它们的生物群有了分散、隔离和进化的机会。更广泛地说,我们可以开始看到巴布亚地区的地质历史是如何导致现存物种的快速积累和惊人数量的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.70
自引率
6.70%
发文量
48
审稿时长
20 weeks
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