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Decoupling of morphological disparity and taxonomic diversity during the end-Permian mass extinction

Published online by Cambridge University Press:  01 February 2021

Junyu Wan Open the ORCID record for Junyu Wan [Opens in a new window] ,
William J. Foster ,
Li Tian ,
Thomas L. Stubbs Open the ORCID record for Thomas L. Stubbs [Opens in a new window] ,
Michael J. Benton Open the ORCID record for Michael J. Benton [Opens in a new window] ,
Xincheng Qiu  and
Aihua Yuan Open the ORCID record for Aihua Yuan [Opens in a new window]
Junyu Wan
Affiliation:
School of Earth Sciences, China University of Geosciences, Wuhan430074, China. E-mail: aihuay@qq.com.
William J. Foster
Affiliation:
School of Earth Sciences, University College Dublin, Dublin 4, Ireland. E-mail: william.foster@ucd.ie
Li Tian
Affiliation:
State Key Laboratory of Biogeology and Environmental Geology, China University of Geosciences, Wuhan430074, China. E-mail: tianlibgeg@163.com, qxch0309@163.com
Thomas L. Stubbs
Affiliation:
School of Earth Sciences, University of Bristol, BristolBS8 1TQ, U.K. E-mail: tom.stubbs@bristol.ac.uk, Mike.Benton@bristol.ac.uk
Michael J. Benton
Affiliation:
School of Earth Sciences, University of Bristol, BristolBS8 1TQ, U.K. E-mail: tom.stubbs@bristol.ac.uk, Mike.Benton@bristol.ac.uk
Xincheng Qiu
Affiliation:
State Key Laboratory of Biogeology and Environmental Geology, China University of Geosciences, Wuhan430074, China. E-mail: tianlibgeg@163.com, qxch0309@163.com
Aihua Yuan*
Affiliation:
School of Earth Sciences, China University of Geosciences, Wuhan430074, China. E-mail: aihuay@qq.com.
*
Corresponding author.
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Abstract

An increasing number of unexpectedly diverse benthic communities are being reported from microbially precipitated carbonate facies in shallow-marine platform settings after the end-Permian mass extinction. Ostracoda, which was one of the most diverse and abundant metazoan groups during this interval, recorded its greatest diversity and abundance associated with these facies. Previous studies, however, focused mainly on taxonomic diversity and, therefore, left room for discussion of paleoecological significance. Here, we apply a morphometric method (semilandmarks) to investigate morphological variance through time to better understand the ecological consequences of the end-Permian mass extinction and to examine the hypothesis that microbial mats played a key role in ostracod survival. Our results show that taxonomic diversity and morphological disparity were decoupled during the end-Permian extinction and that morphological disparity declined rapidly at the onset of the end-Permian extinction, even though the high diversity of ostracods initially survived in some places. The decoupled changes in taxonomic diversity and morphological disparity suggest that the latter is a more robust proxy for understanding the ecological impact of the extinction event, and the low morphological disparity of ostracod faunas is a consequence of sustained environmental stress or a delayed post-Permian radiation. Furthermore, the similar morphological disparity of ostracods between microbialite and non-microbialite facies indicates that microbial mats most likely represent a taphonomic window rather than a biological refuge during the end-Permian extinction interval.

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Paleobiology , Volume 47 , Issue 3 , August 2021 , pp. 402 - 417
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This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
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Copyright © The Author(s), 2021. Published by Cambridge University Press on behalf of The Paleontological Society

Introduction

The end-Permian mass extinction was the most catastrophic biotic crisis of the Phanerozoic, with the extinction of more than 80% of marine invertebrate species (Stanley Reference Stanley2016), and it occurred over a short interval (~60 kyr) that spans the Permian/Triassic boundary (Burgess et al. Reference Burgess, Bowring and Shen2014; Wang et al. Reference Wang, Sadler, Shen, Erwin, Zhang, Wang, Wang, Crowley and Henderson2014). The pattern of extinction is, however, still disputed and often described as a single pulse (Jin et al. Reference Jin, Wang, Wang, Shang, Cao and Erwin2000), multiple pulses (Song et al. Reference Song, Wignall, Tong and Yin2013), an extinction interval (Wang et al. Reference Wang, Sadler, Shen, Erwin, Zhang, Wang, Wang, Crowley and Henderson2014), or with long-term environmental deterioration starting before the main extinction pulse (Kiessling et al. Reference Kiessling, Schobben, Ghaderi, Hairapetian, Leda and Korn2018). In part, these different interpretations are due to sea-level changes overprinting on our understanding of the timing and pattern of extinction (Yin et al. Reference Yin, Jiang, Xia, Feng, Zhang and Shen2014; Holland and Patzkowsky Reference Holland and Patzkowsky2015). In addition to taxonomic losses, the end-Permian extinction recorded widespread ecological disruption and turnover (e.g., Foster and Twitchett Reference Foster and Twitchett2014; Foster et al. Reference Foster, Lehrmann, Yu, Ji and Martindale2018; Song et al. Reference Song, Wignall and Dunhill2018; Martindale et al. Reference Martindale, Foster and Velledits2019). Following the onset of the extinction, there were also sedimentological changes that include the widespread occurrence of microbially precipitated carbonates in shallow-marine carbonate settings, for example, calcite crystal fans, microbialites, and oolitic limestones, which have been attributed to reduced skeletal carbonate production and supersaturated conditions (Hips and Haas Reference Hips and Haas2006; Pruss et al. Reference Pruss, Bottjer, Corsetti and Baud2006; Friesenbichler et al. Reference Friesenbichler, Richoz, Baud, Krystyn, Sahakyan, Vardanyan, Peckmann, Reitner and Heindel2018; Li et al. Reference Li, Gong, Burne, Tang, Su, Zeng, Zhang and Tan2019; Foster et al. Reference Foster, Heindel, Richoz, Gliwa, Lehrmann, Baud, Kolar-Jurkovsek, Aljinovic, Jurkovsek, Korn, Martindale and Peckmann2020). The formation of these microbially precipitated carbonates is associated with persistent environmental stress during the extinction interval (Clarkson et al. Reference Clarkson, Kasemann, Wood, Lenton, Daines, Richoz, Ohnemueller, Meixner, Poulton and Tipper2015; Li et al. Reference Li, Yan, Chen, Ogg, Tian, Korngreen, Liu, Ma and Woods2015; Foster et al. Reference Foster, Lehrmann, Yu, Ji and Martindale2018), but despite this, a relatively high abundance and diversity of ostracods and other metazoans have been reported from these microbially precipitated carbonate facies (Angiolini et al. Reference Angiolini, Carabelli, Nicora, Crasquin-Soleau, Marcoux and Rettori2007; Crasquin and Forel Reference Crasquin and Forel2014; Hautmann et al. Reference Hautmann, Bagherpour, Brosse, Frisk, Hofmann, Baud, Nützel, Goudemand and Bucher2015; Yang et al. Reference Yang, Chen and Ou2015; Foster et al. Reference Foster, Lehrmann, Hirtz, White, Yu, Li and Martindale2019a; Wan et al. Reference Wan, Yuan, Crasquin, Jiang, Yang and Hu2019).

Ostracods show a significant turnover due to the end-Permian event, yet a broad range of Permian survivors and newly evolved species dominated a “survival stage” into the earliest Griesbachian and a subsequent “poverty phase” from the Griesbachian Isarcicella staeschei conodont zone into the Dienerian (Crasquin and Forel Reference Crasquin and Forel2014). Furthermore, the ostracods from the survival stage are typically associated with microbialite facies (Crasquin-Soleau et al. Reference Crasquin-Soleau, Marcoux, Angiolini, Sylvain, Alda, Baud and Yann2004; Forel Reference Forel2012, Reference Forel2014; Forel et al. Reference Forel, Crasquin, Hips, Kershaw, Collin and Haas2013a,Reference Forel, Crasquin, Kershaw and Collinb, Reference Forel, Crasquin, Chitnarin, Angiolini, Gaetani and Wang2015; Crasquin and Forel Reference Crasquin and Forel2014; Wan et al. Reference Wan, Yuan, Crasquin, Jiang, Yang and Hu2019), with only a few exceptions (Foster et al. Reference Foster, Lehrmann, Yu and Martindale2019b; Qiu et al. Reference Qiu, Tian, Wu, Benton, Sun, Yang and Tong2019; Gliwa et al. Reference Gliwa, Forel, Crasquin, Ghaderi, Korn and Wang2020a, Reference Gliwa, Ghaderi, Leda, Schobben, Tomás, Foster, Forel, Tabrizi, Grasby, Struck, Ashouri and Kornb). The co-occurrence of microbialites and ostracods led Forel et al. (Reference Forel, Crasquin, Kershaw and Collin2013b) to suggest that microbial mats provided favorable settings, or refuges, during the extinction interval that could support diverse and abundant ostracod communities.

Ecologically, the ostracod survival stage also records significant decreases in body sizes (i.e., Lilliput effect), precocious sexual dimorphism, and heterochronic growth (deceleration) of ostracods (Forel Reference Forel2014; Forel et al. Reference Forel, Crasquin, Chitnarin, Angiolini, Gaetani and Wang2015). Even if it is unclear which environmental stressor caused these ecological changes (i.e., was it the consequence of high temperatures, deoxygenation of the oceans, changes in nutrient availability, ocean acidification, or a synergistic combination from among these?), ostracod communities do record the ecological implications of the extinction event. The ecological impact of mass extinction events on metazoans can be investigated by studying changes in functional diversity, such as different modes of life (e.g., a combination of tiering, motility, and feeding), which can be recognized typically at the family or superfamily level (Bush and Bambach Reference Bush and Bambach2011; Dineen et al. Reference Dineen, Fraiser and Sheehan2014; Foster and Twitchett Reference Foster and Twitchett2014; Aberhan and Kiessling Reference Aberhan and Kiessling2015). However, the methods noted cannot be applied robustly to ostracods during the Permian–Triassic transition, because ostracod assemblages before and after the extinction present the same ecological characteristics and are dominated by deposit-feeding forms, especially the Bairdioidea superfamily (Forel et al. Reference Forel, Crasquin, Kershaw, Feng and Collin2009; Forel Reference Forel2012; Wan et al. Reference Wan, Yuan, Crasquin, Jiang, Yang and Hu2019). Furthermore, this traditional assertion is currently challenged by the outstanding adaptive potential of the Bairdioidea superfamily (Forel Reference Forel2014).

An alternative way to study the ecological evolution of metazoan communities is to investigate how mass extinctions and diversification events affected the disparity of metazoan communities. In fact, disparity analyses have been applied widely in ecological diversity and macroevolutionary studies around the end-Permian mass extinction, especially for vertebrates, because of their evident functional morphological traits (e.g., Stubbs and Benton Reference Stubbs and Benton2016; Smithwick and Stubbs Reference Smithwick and Stubbs2018). These studies show that when investigating the evolution of metazoans, it is worth considering changes in both taxonomic diversity and morphological disparity, and morphological evolution is tentatively interpreted as having been driven by environmental changes. Although there is limited functional morphological information in the skeletal components of ostracods, several morphometric studies have investigated shape variance in living ostracods and fossil ostracods with distinguishable shell characteristics (Ramos et al. Reference Ramos, Cusminsky, Schwalb and Alperin2016; Martins et al. Reference Martins, Puckett, Lockwood, Swaddle and Hunt2018; Wrozyna et al. Reference Wrozyna, Meyer, Gross, Ramos and Piller2018). These studies found a close relationship between shell morphology, ontogenetic stage, and the environment. Even for smooth-shelled ostracods, a group that dominates the Permian–Triassic transition, semilandmark and outline methods have been applied successfully to some extant assemblages (Baltanás et al. Reference Baltanás, Brauneis, Danielopol and Linhart2003; Wrozyna et al. Reference Wrozyna, Neubauer, Meyer and Piller2016; Karanovic et al. Reference Karanovic, Lavtizar and Djurakic2017). To improve our understanding of the ecological consequences of the end-Permian mass extinction and the relationship between the diversity and ecological functioning of ostracod communities, we reexamined morphological disparity and taxonomic diversity of the fossil record of Permian–Triassic ostracods. Further, we investigate whether the taxonomic “microbialite refuge” hypothesis (sensu Gingras et al. Reference Gingras, Hagadorn, Seilacher, Lalonde, Pecoits, Petrash and Konhauser2011; Forel et al. Reference Forel, Crasquin, Kershaw and Collin2013b) allows for greater survival of morphological disparity during the mass extinction interval.

Materials and Methods

Ostracod Data

In total, 373 well-preserved specimens of 349 species were selected from published studies with scanning electron microscope images that cover the Permian/Triassic boundary successions and record both microbialites and ostracod assemblages (Fig. 1). The data used in this study, therefore, come from Bálvány-North, Bükk Mountains, Hungary (Forel et al. Reference Forel, Crasquin, Hips, Kershaw, Collin and Haas2013a); Çürük Dağ, Taurus Mountains, Turkey (Crasquin-Soleau et al. Reference Crasquin-Soleau, Marcoux, Angiolini, Sylvain, Alda, Baud and Yann2004; Forel Reference Forel2014); Elikah River, central Alborz Mountains, Iran (Forel et al. Reference Forel, Crasquin, Chitnarin, Angiolini, Gaetani and Wang2015); Zuodeng, Guangxi, South China (Wan et al. Reference Wan, Yuan, Crasquin, Jiang, Yang and Hu2019); and Dajiang, Guizhou, South China (Forel Reference Forel2012).

Figure 1. Global paleogeographic map of the Permian/Triassic boundary time interval showing locations of sample sites in this study, based on reconstruction by Golonka (Reference Golonka, Kiessling, Flügel and Golonka2002). Hu: Bálvány-North, Hungary; Ir: Elikah River, north Iran; SC: Zuodeng and Dajiang, South China; Tk: Çürük Dağ, Turkey.

For the paleoecological analyses, taxonomic diversity is calculated by richness of different taxa, that is, total numbers of species, genera, and families. Morphological data have been collected from every species with one representative at each section. The valve outline contains primary morphological information for smooth-shelled ostracods, which represent the majority of the Permian–Triassic transition ostracod fauna. The left valve outline in right lateral view was chosen for this study, because for most Permian–Triassic transition ostracods (e.g., Bairdioidea), the left valves overlap the right valves and best represent the overall outline of the carapace. If the right lateral view was not available, the left lateral view was horizontally flipped.

In the morphometric analyses, the ostracods were divided into three time bins: Permian pre-extinction interval (Pre-E.), extinction interval that spans the Permian/Triassic boundary (Ext.) and Griesbachian postextinction interval (Post-E.). Conodont stratigraphy has been undertaken at all the investigated sections where Hindeodus parvus, whose first appearance datum (FAD) defines the base of the Triassic (Yin et al. Reference Yin, Zhang, Tong, Yang and Wu2001), typically occurs near the base of the microbialites facies, and the Isarcicella staeschei biozone occurs above the microbialite interval (Yang et al. Reference Yang, Hao and Wang1999; Richoz Reference Richoz2006; Sudar et al. Reference Sudar, Perri and Haas2008; Jiang et al. Reference Jiang, Lai, Sun, Wignall, Liu and Yan2014; Forel et al. Reference Forel, Crasquin, Chitnarin, Angiolini, Gaetani and Wang2015). Furthermore, in most Permian/Triassic boundary successions, the microbialites also have irregular contact with the underlying skeletal packstone, which marks the end-Permian mass extinction horizon (Payne et al. Reference Payne, Lehrmann, Follett, Seibel, Kump, Riccardi, Altiner, Sano and Wei2007; Chen et al. Reference Chen, Beatty, Henderson and Rowe2009; Jiang et al. Reference Jiang, Lai, Sun, Wignall, Liu and Yan2014). Some studies recognize the entire microbialite successions as being Triassic due to the isochronism of event deposits and based on biostratigraphic evidence (Jiang et al. Reference Jiang, Lai, Sun, Wignall, Liu and Yan2014; Brosse et al. Reference Brosse, Bucher and Goudemand2016). In Çürük Dağ, however, Isarcicella isarcica, which marks a later biozone of the Griesbachian, occurs with the FAD of H. parvus, yet the chemostratigraphy suggests that the microbialites are the same age as those at the other sections (Richoz Reference Richoz2006). Therefore, in our study, these three time bins also correspond to the layers underlying the microbialite interval, the microbialite interval itself, and the layers overlapping the microbialite interval. Both the data before and within the mass extinction interval are available from all the investigated sections, which means that changes in morphological disparity as a consequence of the end-Permian mass extinction can be investigated at all the sections. However, after the mass extinction interval, ostracods have only been recorded in the Zuodeng and Çürük Dağ sections. In addition, to investigate the microbialite refuge hypothesis, we subsequently divided the samples from Zuodeng and Çürük Dağ during the extinction interval into microbialite and non-microbialite samples, as these different facies were not distinguished at the other sections.

The database of the species and metadata of the ostracod assemblages from each section are available in the Supplementary Table 1, which includes data source, taxon, location, stratigraphic age, and lithology.

Geometric Morphometrics

Landmark-based geometric morphometrics was used to collect the outline shape data of ostracod valves. The convexity of the valve was not included, as not all publications provided these data for the species investigated here. First, two type III landmarks (LM 1 and 2) were defined by the maximum curvature at the anterior and posterior positions of the valve. Second, two curves, each comprising 15 equidistant semilandmarks, were drawn between LM 1 and LM 2, along the dorsal and ventral borders, respectively (Fig. 2). Both landmarks and semilandmarks were set on images with the program TpsDig v. 2.31 (Rohlf Reference Rohlf2015). Third, landmarks were appended to curves, and the sliding directions of the semilandmarks were determined using TpsUtil v. 1.78 (Rohlf Reference Rohlf2015).

Figure 2. An example of the landmark configuration used to investigate changes in morphospace on the left valve outline, in right lateral view, shown using a specimen of Bairdiacypris ottomanensis Crasquin-Soleau et al., Reference Crasquin-Soleau, Marcoux, Angiolini, Sylvain, Alda, Baud and Yann2004 in Wan et al. (Reference Wan, Yuan, Crasquin, Jiang, Yang and Hu2019). Scale bar, 0.1 mm.

A generalized Procrustes analysis (GPA) with a minimized bending algorithm was used to remove the effects of size, location, and orientation of the specimen images using the two-dimensional landmark data, based on the two fixed landmarks and 30 semilandmarks (Gower Reference Gower1975; Rohlf and Slice Reference Rohlf and Slice1990). The shape of each specimen was then plotted using the landmark configuration from the GPA.

A principal component analysis (PCA) was carried out on the aligned, post-GPA landmarks to show the morphological variation within each section and between each time interval. In this study, the first three axes explain ~80% of the morphological variances, and two morphospace plots of PC 1–PC 2 and PC 2–PC 3 were therefore plotted for each section. Shape variation can be distinguished by using thin-plate spline grids and comparing the hypothetical shapes and the mean shape (Claude Reference Claude2008). The two common disparity statistics—the sum of variances and the volume of morphospace—were both calculated in our study. The former is a measurement of the distances between the points in a morphospace scatter plot and is robust to sample size differences, so it is considered to be the main disparity metric for examining quantitative differences in overall morphological variation between groups herein. But the latter, often correlating strongly with sample size, especially when sample size is small (Ciampaglio et al. Reference Ciampaglio, Kemp and McShea2001), was only used as a subsidiary measure to describe the size of occupied morphospace. A bootstrap analysis (100 replicates with replacement) was applied to most groups for disparity calculation, except the groups without enough data.

All these analyses were conducted in R v. 4.0.0 (R Core Team 2020), using the packages geomorph (Adams et al. Reference Adams, Collyer and Kaliontzopoulou2019) and dispRity (Guillerme Reference Guillerme2018). In addition, to symmetrically trace the changes of taxonomic diversity and morphological disparity, the log ratios of changes in each measure, including species richness (log S) and sum of variances (log SoV), were calculated respectively between different time-bin and lithofacies groups.

Results

The results of the PCA maximize and order the interspecific shape differences, and ~80% of the variance can be explained by the first three principal components (Table 1). Variations along PC 1 correspond to changes in the elongation of the ostracod carapaces, and PC 2 records changes in the convexity of the dorsal and ventral borders. Generally, variance along PC 3 relates to changes in the position of the maximum height of the valve, whereas at the Elikah River section, the variance is explained by the position of the maximum length of the valve. Thin-plate spline grids show mean shapes and hypothetical and practical shapes at the extreme position of each axis (Fig. 3, all five sections; Supplementary Figs. 1–5, Zuodeng, Dajing, Çürük Dağ, Bálvány-North, Elikah River, respectively).

Figure 3. Principal component (PC) analysis results and thin-plate splines of morphological variances of ostracods from all five sections in this study. A, Percentages of the first 10 PC axes; B, scatter plots of PC 1 and PC 2 and PC 2 and PC 3; C, thin-plate splines of mean shape, hypothetical shapes (left), and sample shapes (right) at extreme scores.

Table 1. Results of the principal component (PC) analysis (scores of first three PC axes and shape changes on these three axes). DB, dorsal border; VB, ventral border; Hmax, maximum height; Lmax, maximum length.

Temporal Variation

At the Bálvány-North, Dajiang, and Elikah River sections, the volume of morphospace shrinks (Fig. 4), whereas at the Çürük Dağ section, the volume of morphospace remains relatively stable, and in the Zuodeng section, it increases, even though the PCA plot shows the morphospaces to be very similar (Fig. 5A,B). The impact of the end-Permian mass extinction is shown by a decrease in the sum of variances for all sections except Zuodeng, where it remains constant (Fig. 5A). Generally, the pre-extinction ostracod assemblages show higher morphological disparity by a shift in morphospace occupation because of the presence of some species with extreme shapes that are not recorded from the extinction interval (Fig. 5C). Two declines in morphological disparity occurred with the end-Permian mass extinction: the major decline at the onset of the end-Permian extinction, except at Zuodeng, and then a minor one at the end of the extinction interval.

Figure 4. Morphospace occupation from the pre-extinction interval (Pre-E.) to the extinction interval (Ext.). A, Dajiang; B, Bálvány-North; C, Elikah River. From left to right for each row, we show scatter plots of principal component (PC) 1 and PC 2, scatter plots of PC 2 and PC 3, volume of morphospace (VoM), sum of variances (SoV). n = number of species in each time bin.

Figure 5. Morphospace occupation from the pre-extinction interval (Pre-E.) to the postextinction interval (Post-E.). A, Zuodeng; B, Çürük Dağ; C, all five sections. From left to right for each row, we show scatter plots of principal component (PC) 1 and PC 2, scatter plots of PC 2 and PC 3, volume of morphospace (VoM), sum of variances (SoV). n = number of species in each time bin. Note that when all five sections are combined, the data at the postextinction interval are only available from Zuodeng and Çürük Dağ.

The ostracod assemblages from the Dajiang, Bálvány-North, and Elikah River sections experience declines in log S by 0.94, 0.48, and 0.73 (61%, 38%, and 52%), respectively, through the end-Permian mass extinction interval. These sections record a smaller decrease in log SoV of ostracod assemblages by 0.56, 0.23, and 0.65 (43%, 21%, and 48%), respectively (Table 2, Fig. 6). Therefore, those sections that witnessed taxonomic declines in species richness also recorded associated declines in morphological disparity. The Zuodeng and Çürük Dağ sections, however, record large increases in log S associated with the onset of the extinction event by 0.63 and 1.04 (88% and 184%), respectively. However, log SoV records different trends, with only a 0.01 (1%) increase at Zuodeng and a 0.55 (42%) decrease at Çürük Dağ (Table 2, Fig. 6). Furthermore, even when trends are compared between higher taxonomic levels (i.e., at the genus and family levels) and morphological disparity, different rates of changes can be observed (Fig. 6). These results show that variances in morphological disparity and taxonomic richness were decoupled during the end-Permian mass extinction, that is to say, the survivors and newly evolved species during the extinction interval were morphologically similar.

Figure 6. Decoupling of log-ratio changes between taxonomic diversity and morphological disparity during the extinction interval. Asterisk (*) marks changes during the postextinction interval.

Table 2. Log ratios of changes in taxonomic diversity and morphological disparity. VoM, volume of morphospace by PC1 to PC3; SoV, sum of variances. When all five sections are combined, an asterisk (*) indicates the data at the postextinction interval are only available from Zuodeng and Çürük Dağ. Green indicates a decrease; red indicates an increase.

The high number of ostracod species during the extinction interval has been attributed to the presence of microbialites providing a biological refuge (Forel et al. Reference Forel, Crasquin, Kershaw and Collin2013b), and a subsequent decline in ostracod richness is recorded after the extinction interval (Crasquin and Forel Reference Crasquin and Forel2014). In the Zuodeng section, log S declines by 3.16 (96%) to only two species, which are insufficient to rigorously investigate the sum of variance. Even so, the two species recovered from the postextinction interval have very different morphologies (Fig. 5A). In Çürük Dağ, there is a 0.69 (50%) decrease in log S, and 27 species are recorded in the postextinction interval (Table 2). This taxonomic decline is also associated with a mere 0.06 (6%) decline in log SoV (Table 2, Fig. 5B).

Morphological Variation between Facies

Only at the Zuodeng and Çürük Dağ sections can microbialites or non-microbialite lithofacies be distinguished during the extinction interval (Fig. 7). In the Zuodeng section, the microbialite lithofacies is 0.58 (79%) greater in log S and has a larger morphospace occupation than the non-microbialite facies based on the presence of some species belonging to Bairdia, Cryptobairdia, Hungarella, Paracypris, and Silenites. However, log SoV is only 0.06 (6%) larger in the microbialite facies (Table 2, Fig. 7A). In the Çürük Dağ section, the microbialite lithofacies is 0.19 (21%) greater in log S than the non-microbialite facies, and this is associated with a larger morphospace occupation generated by some species of Bairdia, Bairdiacypris, Bythocypris, and Liuzhinia. But there is only a 0.11 (11%) increase in log SoV (Table 2, Fig. 7B). Among the species appearing in the morphospace beyond the non-microbialite facies, only one belonging to Bairdiacypris has Paleozoic affinities, but Hungarella, Liuzhinia, and Paracypris show Meso-Cenozoic affinities based on the classification by Crasquin and Forel (Reference Crasquin and Forel2014). Hungarella and Silenites are genera of Metacopina, which have been considered to be filter-feeding ostracods because the morphology of their hard parts is similar to that of Platycopina (Lethiers and Whatley Reference Lethiers and Whatley1994).

Figure 7. Morphospace occupation between microbialites (MicroB.) and non-microbialite (Non-MicroB.) samples from the extinction interval. A, Zuodeng; B, Çürük Dağ. From left to right for each row, we show scatter plots of principal component (PC) 1 and PC 2, scatter plots of PC 2 and PC 3, volume of morphospace (VoM), sum of variances (SoV). n = number of species in each time bin.

Discussion

Impact of Sedimentary Facies

In the uppermost Changhsingian, there is a widespread transient hiatus in shallow-marine successions caused by a regression (Yin et al. Reference Yin, Jiang, Xia, Feng, Zhang and Shen2014) or collapse in carbonate sedimentation (Payne et al. Reference Payne, Lehrmann, Follett, Seibel, Kump, Riccardi, Altiner, Sano and Wei2007), but the following transgression allows the recurrence of the previous shallow-water deposition in the earliest Triassic (Yin et al. Reference Yin, Jiang, Xia, Feng, Zhang and Shen2014). The samples from the Dajiang, Zuodeng, Çürük Dağ, and Elikah River sections were collected from Changhsingian bioclastic limestones and Griesbachian microbialites, both of which were deposited on shallow-marine carbonate platforms between fair and storm weather wave bases (Lehrmann et al. Reference Lehrmann, Payne, Enos, Montgomery, Wei, Yu, Xiao and Orchard2005; Gaetani et al. Reference Gaetani, Angiolini, Ueno, Nicora, Stephenson, Sciunnach, Rettori, Price and Sabouri2009; Kershaw et al. Reference Kershaw, Crasquin, Li, Collin, Forel, Mu, Baud, Wang, Xie, Maurer and Guo2012; Fang et al. Reference Fang, Chen, Kershaw, Yang and Luo2017). The samples from the Bálvány-North section come from the Changhsingian Nagyvisnyó Limestone Formation, which was deposited in an open-marine, homoclinal carbonate ramp below a storm weather wave base, and the Griesbachian Gerennavár Limestone Formation, which also represents deposition on the same sedimentary environment but on a slightly deeper part of the ramp (Hips and Haas Reference Hips and Haas2006). These two formations are also separated by a <1 m “boundary shale” that represents the collapse of carbonate sedimentation (Hips and Haas Reference Hips and Haas2006), but no samples from this interval yielded any ostracods (Forel et al. Reference Forel, Crasquin, Hips, Kershaw, Collin and Haas2013a). In other words, the ostracods in pre-extinction and extinction communities were living in very similar settings. In addition, the impact of the stratigraphic unconformity between the pre-extinction limestones and microbialites, which would artificially condense the last appearance datum to a single horizon (Holland and Patzkowsky Reference Holland and Patzkowsky2015), is not expected to be significant, because the stratigraphic gap in the succession is considered to have been brief by geologic standards (sensu Payne et al. Reference Payne, Lehrmann, Follett, Seibel, Kump, Riccardi, Altiner, Sano and Wei2007; Burgess et al. Reference Burgess, Bowring and Shen2014). But there are changes in the lithofacies as a consequence of the mass extinction event, where habitats previously occupied by metazoan reefs and the presence of a sedimentary mixed layer are replaced by microbial buildups and undisturbed sediment, respectively, owing to the impact of the extinction on metazoan reef builders and bioturbators (Hofmann et al. Reference Hofmann, Buatois, MacNaughton and Mángano2015; Chen et al. Reference Chen, Tu, Pei, Ogg, Fang, Wu, Feng, Huang, Guo and Yang2019). Facies control on the observed patterns between the pre-extinction and extinction interval is, therefore, interpreted to be minimal.

During the postextinction interval, ostracod faunas enter the “poverty stage” (Crasquin and Forel Reference Crasquin and Forel2014), so we only have data from the Zuodeng and Çürük Dağ sections. Meanwhile, the termination of these microbialites is the complicated and varied result of global or local rapid changes in water depth (Kershaw et al. Reference Kershaw, Crasquin, Li, Collin, Forel, Mu, Baud, Wang, Xie, Maurer and Guo2012), increasing supplies of terrestrial weathered sediments (Bagherpour et al. Reference Bagherpour, Bucher, Baud, Brosse, Vennemann, Martini and Guodun2017), and recovery in competition between microbial mats and metazoans (Foster et al. Reference Foster, Heindel, Richoz, Gliwa, Lehrmann, Baud, Kolar-Jurkovsek, Aljinovic, Jurkovsek, Korn, Martindale and Peckmann2020). The overlying Griesbachian mudstone and thin-bedded micritic limestone at Zuodeng are interpreted to have been deposited in a deeper part of the platform and with an increasing terrestrial input (Fang et al. Reference Fang, Chen, Kershaw, Yang and Luo2017). On the other hand, the many oolitic layers with calcilutite interlayers following the microbialites at Çürük Dağ suggest an upward-shallowing sedimentary sequence (Marcoux and Baud Reference Marcoux and Baud1986). The productive samples here were collected only from mixed carbonate-siliciclastic beds, which were interpreted as having been deposited in a setting similar to that of the underlying microbialites (Forel et al. Reference Foster and Twitchett2014). Consequently, the simultaneous disappearances of ostracod fauna and microbialites probably indicate rapid facies changes.

Paleoecological Implications of the Mass Extinction

Ostracods have had a long evolutionary history from the Ordovician to the present day, and study of environmental controls on the morphological dynamics of modern ostracod shell shapes can be informative for understanding fossil examples. Through the end-Permian mass extinction, the most significant impact on morphospace was caused by the disappearance of some key species of the genera Polycope, Paraparchites, Samarella, and other Paleozoic forms (Fig. 3). Polycope is an extant genus that today prefers temperate climates (Kornicker Reference Kornicker1959), so its absence might be the consequence of high temperatures during the Permian–Triassic transition (Sun et al. Reference Sun, Joachimski, Wignall, Yan, Chen, Jiang, Wang and Lai2012; Wang et al. Reference Wang, Garbelli, Zhang, Zheng, Zhang, Yuan, Shi, Chen and Shen2020). In Paraparchites and Samarella, distinct sexual dimorphism has been observed (Forel et al. Reference Forel, Crasquin, Chitnarin, Angiolini, Gaetani and Wang2015), and at that time there might have been some higher extinction risk associated with sexual selection (Martins et al. Reference Martins, Puckett, Lockwood, Swaddle and Hunt2018).

Although 68% (94/139) of newly evolved species during the mass extinction belong to the well-adapted Bairdioidea superfamily, the increased morphological resemblance between ostracod species from the extinction interval might not only reflect genetic similarity but also convergent evolutionary responses to environmental pressures (Benson Reference Benson1981; Baltanás et al. Reference Baltanás, Brauneis, Danielopol and Linhart2003). Therefore, changes in morphological disparity could reflect both environmental drivers of mass extinctions and evolutionary strategies. The decoupling between diversity and disparity is also observed in the adaptive evolution of other invertebrates, such as ammonoids (McGowan Reference McGowan2004; Brosse et al. Reference Brosse, Brayard, Fara and Neige2013; Korn et al. Reference Korn, Ghaderi, Ghanizadeh Tabrizi and Gliwa2020) and some vertebrates (Ruta et al. Reference Ruta, Angielczyk, Frobisch and Benton2013; Benton et al. Reference Benton, Forth and Langer2014; Stubbs and Benton Reference Stubbs and Benton2016). The pattern of ostracod evolution at this time is interpreted as an example of the diversity-first model, as observed for ammonoids (McGowan and Smith Reference McGowan and Smith2007; Brosse et al. Reference Brosse, Brayard, Fara and Neige2013), which suggests this kind of animal speciates rapidly into vacant niches with little morphological innovation, perhaps because of the absence of competitors. Other groups, such as tetrapods, show a disparity-first model following the acquisition of a key adaptation and expansion into new ecological niches (Benton et al. Reference Benton, Forth and Langer2014). Ecological functions, rather than specific diversity, are more important to the resilience and recovery of the ecosystem (Alvarez et al. Reference Alvarez, Gibbs, Bown, Kim, Sheward and Ridgwell2019). Therefore, even though metazoan diversity is higher in microbialite facies, it does not necessarily indicate a healthy ecosystem. Furthermore, coinciding with smaller body sizes of benthic metazoans, prevalence of opportunistic taxa, and the ecological adaptations to environmental stress, a low morphological disparity of ostracods suggests unfavorable environmental conditions in microbialite facies (Foster et al. Reference Foster, Lehrmann, Yu, Ji and Martindale2018).

In terms of definition, morphological disparity is clearly different from taxonomic diversity, but a link might be expected as the null model. In other words, as species split and diversify, it might be expected that disparity would increase at the same rate, but it is often found that diversity and disparity are decoupled (Foote Reference Foote1997; Erwin Reference Erwin2007). At the onset of the end-Permian mass extinction, ostracods recorded a species-level extinction intensity of between 74% and 100%, but nearly the same high species-level renewal rate (between 65% and 100%) in the microbialite sections during the extinction interval, the time that has been called the survival stage of ostracods, as already mentioned (Crasquin and Forel Reference Crasquin and Forel2014). Even the Zuodeng (South China) and Çürük Dağ (Turkey) sections both record increases in species richness and specimen abundance. These unusual increases in diversity might be a taphonomic overprint caused by changes in the taphonomic pathways rather than an ecological signal, but the sum of variances was not affected strongly, especially for the Çürük Dağ section, just like the other sections with declining diversity, recording a distinct reduction in disparity. The only exception is the Zuodeng section, where almost the same low disparity has been recorded during the pre-extinction and extinction intervals. The reason for this sole exception might be something about the particular paleogeographic location of this isolated platform or some form of pre-extinction environmental deterioration (e.g., Kiessling et al. Reference Kiessling, Schobben, Ghaderi, Hairapetian, Leda and Korn2018), when the ostracod fauna was dominated by broadly adapted taxa in the latest Permian, but we need more ostracod data from earlier strata to test these ideas. The changes in higher taxa are not as evident as those at the species level, but the taxonomic diversity still represents different rates of change when compared with morphological disparity. The quantitative morphological analysis, therefore, shows a decoupling of morphological disparity and taxonomic richness, which implies that the sum of variances is a more robust proxy of the environmental consequences to ostracod communities than taxonomic diversity.

All our study sections record only a modest decline in the species richness (0.20 log SoV; 19%) but double the level (0.46 log SoV; 37%) in the sum of variances during the extinction (Table 2, Fig. 6), which indicates that the initial pulse of the mass extinction had distinct effects on the morphological disparity of ostracods. The ostracod survival stage, therefore, was a time of relatively high taxonomic richness with a minor reduction or even increase seen in some sections and morphologically convergent evolution. Conversely, the second pulse records a great decline in species richness by 1.84 log S (84%), but only a much smaller decline in the sum of variances by 0.29 log SoV (25%) in the postextinction interval (Table 2, Fig. 6). Although this second extinction pulse supports the two-pulse extinction pattern (Song et al. Reference Song, Wignall, Tong and Yin2013), it is probably the result of small sample sizes in the postextinction interval associated with rapid facies changes in the investigated sections. On the other hand, the sum of variances is robust to sample size, especially in the Çürük Dağ section, which has sufficiently abundant data from the postextinction interval. Therefore, the major loss of morphological disparity has been recorded at the onset of the extinction interval or maybe earlier in some places, and the low disparity continues into the postextinction interval. In other words, the ecosystem was more likely to have been catastrophically devastated during the initial pulse of the end-Permian extinction in the latest Permian, and then experienced a delayed radiation due to persistent environmental stress.

Implications for the Microbialite-Refuge Hypothesis

Microbial mat refugia were suggested to have played a critical role in the evolution of life during the Ediacaran, in that they provided oxygenated oases in otherwise anoxic environments and would have been a source of nutrients for grazing metazoans (Gingras et al. Reference Gingras, Hagadorn, Seilacher, Lalonde, Pecoits, Petrash and Konhauser2011; Ding et al. Reference Ding, Dong, Sun, Ma, Xu, Yang, Peng, Zhou and Shen2019). This concept has also been applied to ostracod faunas from the end-Permian mass extinction interval to explain their unusually high diversity and abundance, as well as the survival of other metazoans in microbialite successions (Forel et al. Reference Forel, Crasquin, Kershaw and Collin2013b, Reference Forel, Crasquin, Chitnarin, Angiolini, Gaetani and Wang2015; Crasquin and Forel Reference Crasquin and Forel2014; Forel Reference Forel2014). Based on our morphological results, only 11% of the genera that expanded morphospace occupation in microbialite facies actually have Paleozoic affinities, which contrasts with the fact that 40% to 67% of genera in all ostracod faunas of the Griesbachian have Paleozoic affinities (Crasquin and Forel Reference Crasquin and Forel2014; Wan et al. Reference Wan, Yuan, Crasquin, Jiang, Yang and Hu2019). This heterogeneous composition suggests that Paleozoic survivors were less adapted to the changed environment represented by the microbial mats, but the Mesozoic pioneers, especially some filter-feeding ostracods belonging to Metacopina (i.e., Hungeralla and Silenites), were opportunists that evolved under reduced competitive pressure (Boomer et al. Reference Boomer, Lord and Crasquin2008; Forel et al. Reference Forel, Crasquin, Bruhwiler, Goudemand, Bucher, Baud and Randon2011).

The sum of variances shows no such obvious differentiation in taxonomic diversity between microbialite and non-microbialite facies (Table 2, Fig. 7), which challenges the idea that microbial mats provided a biological refuge. Not only that, the filter-feeding ostracods, occupying a larger morphospace in the microbialite facies, preferred oligotrophic conditions (Forel et al. Reference Forel, Crasquin, Bruhwiler, Goudemand, Bucher, Baud and Randon2011; Horne et al. Reference Horne, Brandão and Slipper2011), which is inconsistent with the eutrophic conditions during the extinction interval (Schobben et al. Reference Schobben, Stebbins, Ghaderi, Strauss, Korn and Korte2016). Even for the deposit-feeding ostracods, there are no grazing traces, such as Lamonte trevallis (O'Neil et al. Reference O'Neil, Tackett and Meyer2020), recorded in the microbialites (Forel et al. Reference Forel, Crasquin, Kershaw and Collin2013b; Qiu et al. Reference Qiu, Tian, Wu, Benton, Sun, Yang and Tong2019). Therefore, the view that microbial mats served as a food source for ostracods is still equivocal, and more supporting evidence is required. Furthermore, a cyanobacteria-dominated microbial mat would be anoxic or euxinic below the surface, which is not an ideal environment for ostracods. Unlike the Ediacaran biota, which had some special adaptive abilities to withstand regular exposure to anoxia and daily cycles in oxygen production (Gingras et al. Reference Gingras, Hagadorn, Seilacher, Lalonde, Pecoits, Petrash and Konhauser2011; Ding et al. Reference Ding, Dong, Sun, Ma, Xu, Yang, Peng, Zhou and Shen2019), ostracods did not have the same adaptive capabilities. In addition, in modern thrombolites, metazoans that are well adapted to microbial habitats are typically motile and move around the surface of microbial mats to exploit spatial variance in oxygen availability (Tarhan et al. Reference Tarhan, Planavsky, Laumer, Stolz and Reid2013). Because ostracods are also motile, they might be capable of the same adaptation to the microbial environment. There are further aspects of an ostracod's life cycle and behavior that indicate ostracods are not adapted to living within a microbial mat; for example, most ostracods reproduce sexually, rather than by parthenogenesis (Cohen and Morin Reference Cohen and Morin1990).

In fact, the idea that microbial mats provided refugia during the end-Permian mass extinction has already been challenged for some metazoan groups. Hautmann et al. (Reference Hautmann, Bagherpour, Brosse, Frisk, Hofmann, Baud, Nützel, Goudemand and Bucher2015) observed that the bivalve and gastropod species found in microbialites did not differ from those in non-microbialite facies, and therefore, microbial mats cannot truly be considered as refugia. Likewise, relatively diverse, postextinction metazoan communities have been reported from non-microbialite successions (Twitchett et al. Reference Twitchett, Krystyn, Baud, Wheeley and Richoz2004; Beatty et al. Reference Beatty, Zonneveld and Henderson2008), including ostracod assemblages from South China and Iran (Qiu et al. Reference Qiu, Tian, Wu, Benton, Sun, Yang and Tong2019; Gliwa et al. Reference Gliwa, Forel, Crasquin, Ghaderi, Korn and Wang2020a,Reference Gliwa, Ghaderi, Leda, Schobben, Tomás, Foster, Forel, Tabrizi, Grasby, Struck, Ashouri and Kornb). Further, the anoxic–dysoxic signal associated with microbialite successions has been reinterpreted to represent reducing conditions within the sediment rather than in the water column (Heindel et al. Reference Heindel, Foster, Richoz, Birgel, Roden, Baud, Brandner, Krystyn, Mohtat and Koşun2018; Kershaw et al. Reference Kershaw, Tang, Li and Guo2018), which remained well mixed and oxygenated by wave-induced currents in shallow-marine settings (Tang et al. Reference Tang, Kershaw, Liu, Tan, Li, Hu, Huang, Wang, Lian and Li2017; Heindel et al. Reference Heindel, Foster, Richoz, Birgel, Roden, Baud, Brandner, Krystyn, Mohtat and Koşun2018).

An alternative explanation for the higher taxonomic diversity and morphological disparity in microbialite facies is that microbial mats were taphonomic windows (Hautmann et al. Reference Hautmann, Bucher, Brühwiler, Goudemand, Kaim and Nützel2011; Foster et al. Reference Foster, Lehrmann, Yu and Martindale2019b). This idea is supported by investigations on the spatial distribution of benthic fossils between microbialite and non-microbialite fabrics (Hautmann et al. Reference Hautmann, Bagherpour, Brosse, Frisk, Hofmann, Baud, Nützel, Goudemand and Bucher2015; Foster et al. Reference Foster, Lehrmann, Yu and Martindale2019b, Reference Foster, Heindel, Richoz, Gliwa, Lehrmann, Baud, Kolar-Jurkovsek, Aljinovic, Jurkovsek, Korn, Martindale and Peckmann2020; Suarez-Gonzalez et al. Reference Suarez-Gonzalez, Benito, Quijada, Mas and Campos-Soto2019), which suggest that the para-autochthonous metazoans were transported by episodic currents from near the microbial mats into the microbial framework, which provided a site of preferential preservation—namely, a taphonomic window. This idea can also explain the exceptional preservation of Lagerstätten through the Ediacaran and Phanerozoic, where abundant microbes, microbial mats, and microbial films have been identified as being essential for the exceptional preservation of soft tissues, articulated specimens, and trace fossils (Briggs and Wilby Reference Briggs and Wilby1996; Gall Reference Gall2001; Hu et al. Reference Hu, Zhu, Steiner, Luo, Zhao and Liu2010; Buatois and Mángano Reference Buatois and Mángano2011). One further issue is that the high degree of recrystallization and dolomitization associated with Permian/Triassic boundary microbialites would degrade fossil preservation. Nevertheless, micritic envelopes around fossils within microbialites have not only enabled enhanced preservation of the fossils but also made it easier to recover a diverse fauna through careful preparation of the samples (Hautmann et al. Reference Hautmann, Bagherpour, Brosse, Frisk, Hofmann, Baud, Nützel, Goudemand and Bucher2015; Foster et al. Reference Foster, Lehrmann, Yu, Ji and Martindale2018).

For all these reasons, we argue that microbial mats might simply have enhanced fossil preservation, rather than providing an essential oxygen and food source for benthic metazoans like ostracods.

Conclusion

Our study reexamined the fossil record of ostracod communities that span the Permian/Triassic boundary in order to investigate the ecological consequences of the end-Permian mass extinction. Morphological disparity was generally decoupled from taxonomic diversity, and the major decline at the onset of the extinction interval in most sections suggests that the major ecological changes occurred during the initial pulse of the mass extinction. After that, the sustained low morphological disparity of ostracod faunas, combined with other ecological changes observed in benthic communities across the Permian/Triassic boundary, indicates persistent environmental stress and delayed postextinction radiation. Further, we confirm that occupation of morphospace is greater in microbialites than in non-microbialite facies, but these differences in disparity are small, which suggests that microbial mats were favorable for the preservation of diverse ostracods, acting as a taphonomic window instead of refugia during the end-Permian mass extinction.

Acknowledgments

This work was supported by the National Natural Science Foundation of China (grant nos. 42030513, 41730320, 41661134047, 40902002) and the 111 project from National Bureau of Foreign Experts and Ministry of Education of China (grant no. BP0820004). M.J.B. and T.L.S. were funded by the Natural Environment Research Council (grant no. NE/P013724/1) and European Research Council (grant no. 788203). W.J.F. was supported in part by a research grant from Science Foundation Ireland (grant no. 13/RC/2092) and is cofunded under the European Regional Development Fund and by iCRAG industry partners. J.W. was funded under the short-term overseas program by School of Earth Sciences, China University of Geosciences (Wuhan), and would like to thank P. Orr for facilitating this research at the University College Dublin. We would also like to thank W. Kiessling and three anonymous reviewers for constructive comments that greatly improved the article.

Footnotes

Data available from the Dryad Digital Repository: https://doi.org/10.5061/dryad.59zw3r25v

*

Present address: School of Earth Sciences, University College Dublin, Dublin 4, Ireland. E-mail: junyuwan@gmail.com

References

Literature Cited

Aberhan, M., and Kiessling, W.. 2015. Persistent ecological shifts in marine molluscan assemblages across the end–Cretaceous mass extinction. Proceedings of the National Academy of Sciences USA 112:72077212.CrossRefGoogle ScholarPubMed
Adams, D. C., Collyer, M., and Kaliontzopoulou, A.. 2019. Geomorph: software for geometric morphometric analyses, R package version 3.1.0. https://cran.r-project.org/package=geomorph, accessed 25 November 2019.Google Scholar
Alvarez, S. A., Gibbs, S. J., Bown, P. R., Kim, H., Sheward, R. M., and Ridgwell, A.. 2019. Diversity decoupled from ecosystem function and resilience during mass extinction recovery. Nature 574:242245.CrossRefGoogle ScholarPubMed
Angiolini, L., Carabelli, L., Nicora, A., Crasquin-Soleau, S., Marcoux, J., and Rettori, R.. 2007. Brachiopods and other fossils from the Permo–Triassic boundary beds of the Antalya Nappes (SW Taurus, Turkey). Geobios 40:715729.CrossRefGoogle Scholar
Bagherpour, B., Bucher, H., Baud, A., Brosse, M., Vennemann, T., Martini, R., and Guodun, K.. 2017. Onset, development, and cessation of basal Early Triassic microbialites (BETM) in the Nanpanjiang pull-apart Basin, South China Block. Gondwana Research 44:178204.CrossRefGoogle Scholar
Baltanás, A., Brauneis, W., Danielopol, D. L., and Linhart, J.. 2003. Morphometric methods for applied ostracodology: tools for outline analysis of nonmarine ostracodes. The Paleontological Society Papers 9:101118.CrossRefGoogle Scholar
Beatty, T. W., Zonneveld, J. P., and Henderson, C. M.. 2008. Anomalously diverse Early Triassic ichnofossil assemblages in northwest Pangea: a case for a shallow-marine habitable zone. Geology 36:771774.CrossRefGoogle Scholar
Benson, R. H. 1981. Form, function, and architecture of ostracode shells. Annual Review of Earth and Planetary Sciences 9:5980.CrossRefGoogle Scholar
Benton, M. J., Forth, J., and Langer, M. C.. 2014. Models for the rise of the dinosaurs. Current Biology 24:R87R95.CrossRefGoogle ScholarPubMed
Boomer, I., Lord, A., and Crasquin, S.. 2008. The extinction of the Metacopina (Ostracoda). Senckenbergiana Lethaea 88:4753.CrossRefGoogle Scholar
Briggs, D. E., and Wilby, P. R.. 1996. The role of the calcium carbonate-calcium phosphate switch in the mineralization of soft-bodied fossils. Journal of the Geological Society 153:665668.CrossRefGoogle Scholar
Brosse, M., Brayard, A., Fara, E., and Neige, P.. 2013. Ammonoid recovery after the Permian–Triassic mass extinction: a re-exploration of morphological and phylogenetic diversity patterns. Journal of the Geological Society 170:225236.CrossRefGoogle Scholar
Brosse, M., Bucher, H., and Goudemand, N.. 2016. Quantitative biochronology of the Permian–Triassic boundary in South China based on conodont unitary associations. Earth-Science Reviews 155:153171.CrossRefGoogle Scholar
Buatois, L. A., and Mángano, M. G.. 2011. The déjà vu effect: recurrent patterns in exploitation of ecospace, establishment of the mixed layer, and distribution of matgrounds. Geology 39:11631166.CrossRefGoogle Scholar
Burgess, S. D., Bowring, S., and Shen, S. Z.. 2014. High-precision timeline for Earth's most severe extinction. Proceedings of the National Academy of Sciences USA 111:33163321.CrossRefGoogle ScholarPubMed
Bush, A. M., and Bambach, R. K.. 2011. Paleoecologic megatrends in marine Metazoa. Annual Review of Earth and Planetary Sciences 39:241269.CrossRefGoogle Scholar
Chen, J., Beatty, T. W., Henderson, C. M., and Rowe, H.. 2009. Conodont biostratigraphy across the Permian–Triassic boundary at the Dawen section, Great Bank of Guizhou, Guizhou Province, South China: implications for the Late Permian extinction and correlation with Meishan. Journal of Asian Earth Sciences 36:442458.CrossRefGoogle Scholar
Chen, Z. Q., Tu, C., Pei, Y., Ogg, J., Fang, Y., Wu, S., Feng, X., Huang, Y., Guo, Z., and Yang, H.. 2019. Biosedimentological features of major microbe-metazoan transitions (MMTs) from Precambrian to Cenozoic. Earth-Science Reviews 189:2150.CrossRefGoogle Scholar
Ciampaglio, C. N., Kemp, M., and McShea, D. W.. 2001. Detecting changes in morphospace occupation patterns in the fossil record: characterization and analysis of measures of disparity. Paleobiology 27:695715.2.0.CO;2>CrossRefGoogle Scholar
Clarkson, M. O., Kasemann, S. A., Wood, R. A., Lenton, T. M., Daines, S. J., Richoz, S., Ohnemueller, F., Meixner, A., Poulton, S. W., and Tipper, E. T.. 2015. Ocean acidification and the Permo–Triassic mass extinction. Science 348:229232.CrossRefGoogle ScholarPubMed
Claude, J. 2008. Morphometrics with R. Springer, New York, p. 317.Google Scholar
Cohen, A. C., and Morin, J. G.. 1990. Patterns of reproduction in Ostracodes: a review. Journal of Crustacean Biology 10:184212.CrossRefGoogle Scholar
Crasquin, S., and Forel, M.-B.. 2014. Ostracods (Crustacea) through Permian–Triassic events. Earth-Science Reviews 137:5264.CrossRefGoogle Scholar
Crasquin-Soleau, S., Marcoux, J., Angiolini, L., Sylvain, R., Alda, N., Baud, A., and Yann, B.. 2004. A new ostracode fauna from the Permian–Triassic boundary in Turkey (Taurus, Antalya Nappes). Micropaleontology 50:281295.CrossRefGoogle Scholar
Dineen, A. A., Fraiser, M. L., and Sheehan, P. M.. 2014. Quantifying functional diversity in pre- and post-extinction paleocommunities: a test of ecological restructuring after the end-Permian mass extinction. Earth-Science Reviews 136:339349.CrossRefGoogle Scholar
Ding, W., Dong, L., Sun, Y., Ma, H., Xu, Y., Yang, R., Peng, Y., Zhou, C., and Shen, B.. 2019. Early animal evolution and highly oxygenated seafloor niches hosted by microbial mats. Scientific Reports 9:13628.CrossRefGoogle ScholarPubMed
Erwin, D. H. 2007. Disparity: morphological pattern and developmental context. Palaeontology 50:5773.CrossRefGoogle Scholar
Fang, Y., Chen, Z. Q., Kershaw, S., Yang, H., and Luo, M.. 2017. Permian–Triassic boundary microbialites at Zuodeng Section, Guangxi Province, South China: geobiology and palaeoceanographic implications. Global and Planetary Change 152:115128.CrossRefGoogle Scholar
Foote, M. 1997. The evolution of morphological diversity. Annual Review of Ecology and Systematics 28:129152.CrossRefGoogle Scholar
Forel, M.-B. 2012. Ostracods (Crustacea) associated with microbialites across the Permian–Triassic boundary in Dajiang (Guizhou Province, South China). European Journal of Taxonomy 19:134.Google Scholar
Forel, M.-B. 2014. Heterochronic growth of ostracods (Crustacea) from microbial deposits in the aftermath of the end-Permian extinction. Journal of Systematic Palaeontology 13:315349.CrossRefGoogle Scholar
Forel, M.-B., Crasquin, S., Kershaw, S., Feng, Q. L., and Collin, P. Y.. 2009. Ostracods (Crustacea) and water oxygenation in the earliest Triassic of South China: implications for oceanic events at the end-Permian mass extinction. Australian Journal of Earth Sciences 56:815823.CrossRefGoogle Scholar
Forel, M.-B., Crasquin, S., Bruhwiler, T., Goudemand, N., Bucher, H., Baud, A., and Randon, C.. 2011. Ostracod recovery after Permian–Triassic boundary mass-extinction: the south Tibet record. Palaeogeography, Palaeoclimatology, Palaeoecology 308:160170.CrossRefGoogle Scholar
Forel, M.-B., Crasquin, S., Hips, K., Kershaw, S., Collin, P. Y., and Haas, J.. 2013a. Biodiversity evolution through the Permian–Triassic boundary event: ostracods from the Bukk Mountains, Hungary. Acta Palaeontologica Polonica 58:195219.Google Scholar
Forel, M.-B., Crasquin, S., Kershaw, S., and Collin, P. Y.. 2013b. In the aftermath of the end-Permian extinction: the microbialite refuge? Terra Nova 25:137143.CrossRefGoogle Scholar
Forel, M.-B., Crasquin, S., Chitnarin, A., Angiolini, L., Gaetani, M., and Wang, Y.. 2015. Precocious sexual dimorphism and the Lilliput effect in Neo-Tethyan Ostracoda (Crustacea) through the Permian–Triassic boundary. Palaeontology 58:409454.CrossRefGoogle Scholar
Foster, W. J., and Twitchett, R. J.. 2014. Functional diversity of marine ecosystems after the Late Permian mass extinction event. Nature Geoscience 7:233238.CrossRefGoogle Scholar
Foster, W. J., Lehrmann, D. J., Yu, M., Ji, L., and Martindale, R. C.. 2018. Persistent environmental stress delayed the recovery of marine communities in the aftermath of the latest Permian mass extinction. Paleoceanography and Paleoclimatology 33:338353.CrossRefGoogle Scholar
Foster, W. J., Lehrmann, D. J., Hirtz, J. A., White, M., Yu, M., Li, J., and Martindale, R. C.. 2019a. Early Triassic benthic invertebrates from the Great Bank of Guizhou, South China: systematic palaeontology and palaeobiology. Papers in Palaeontology 5:613656.CrossRefGoogle Scholar
Foster, W. J., Lehrmann, D. J., Yu, M., and Martindale, R. C.. 2019b. Facies selectivity of benthic invertebrates in a Permian/Triassic boundary microbialite succession: implications for the “microbialite refuge” hypothesis. Geobiology 17:523535.CrossRefGoogle Scholar
Foster, W. J., Heindel, K., Richoz, S., Gliwa, J., Lehrmann, D. J., Baud, A., Kolar-Jurkovsek, T., Aljinovic, D., Jurkovsek, B., Korn, D., Martindale, R. C., and Peckmann, J.. 2020. Suppressed competitive exclusion enabled the proliferation of Permian/Triassic boundary microbialites. Depositional Record 6:6274.CrossRefGoogle ScholarPubMed
Friesenbichler, E., Richoz, S., Baud, A., Krystyn, L., Sahakyan, L., Vardanyan, S., Peckmann, J., Reitner, J., and Heindel, K.. 2018. Sponge-microbial build-ups from the lowermost Triassic Chanakhchi section in southern Armenia: microfacies and stable carbon isotopes. Palaeogeography, Palaeoclimatology, Palaeoecology 490:653672.CrossRefGoogle Scholar
Gaetani, M., Angiolini, L., Ueno, K., Nicora, A., Stephenson, M. H., Sciunnach, D., Rettori, R., Price, G. D., and Sabouri, J.. 2009. Pennsylvanian–Early Triassic stratigraphy in the Alborz Mountains (Iran). Geological Society of London Special Publication 312:79128.CrossRefGoogle Scholar
Gall, J. C. 2001. Role of microbial mats. Palaeobiology 2:280284.CrossRefGoogle Scholar
Gingras, M., Hagadorn, J. W., Seilacher, A., Lalonde, S. V., Pecoits, E., Petrash, D., and Konhauser, K. O.. 2011. Possible evolution of mobile animals in association with microbial mats. Nature Geoscience 4:372375.CrossRefGoogle Scholar
Gliwa, J., Forel, M. B., Crasquin, S., Ghaderi, A., Korn, D., and Wang, Y.. 2020a. Ostracods from the end-Permian mass extinction in the Aras Valley section (north-west Iran). Papers in Palaeontology. doi: 10.1002/spp2.1330.CrossRefGoogle Scholar
Gliwa, J., Ghaderi, A., Leda, L., Schobben, M., Tomás, S., Foster, W. J., Forel, M.-B., Tabrizi, N. Ghanizadeh, Grasby, S. E., Struck, U., Ashouri, A. R., and Korn, D.. 2020b. Aras Valley (northwest Iran): high-resolution stratigraphy of a continuous central Tethyan Permian–Triassic boundary section. Fossil Record 23:3369.CrossRefGoogle Scholar
Golonka, J. 2002. Plate-tectonic maps of the Phanerozoic. In Kiessling, W., Flügel, E., and Golonka, J., eds. Phanerozoic reef patterns. Society for Sedimentary Geology Special Publication 72:2175.CrossRefGoogle Scholar
Gower, J. C. 1975. Generalized Procrustes analysis. Psychometrika 40:3351.CrossRefGoogle Scholar
Guillerme, T. 2018. dispRity: a modular R package for measuring disparity. Methods in Ecology and Evolution 9:17551763.CrossRefGoogle Scholar
Hautmann, M., Bucher, H., Brühwiler, T., Goudemand, N., Kaim, A., and Nützel, A.. 2011. An unusually diverse mollusc fauna from the earliest Triassic of South China and its implications for benthic recovery after the end-Permian biotic crisis. Geobios 44:7185.CrossRefGoogle Scholar
Hautmann, M., Bagherpour, B., Brosse, M., Frisk, Å., Hofmann, R., Baud, A., Nützel, A., Goudemand, N., and Bucher, H.. 2015. Competition in slow motion: the unusual case of benthic marine communities in the wake of the end-Permian mass extinction. Palaeontology 58:871901.CrossRefGoogle Scholar
Heindel, K., Foster, W. J., Richoz, S., Birgel, D., Roden, V. J., Baud, A., Brandner, R., Krystyn, L., Mohtat, T., and Koşun, E.. 2018. The formation of microbial-metazoan bioherms and biostromes following the latest Permian mass extinction. Gondwana Research 61:187202.CrossRefGoogle Scholar
Hips, K., and Haas, J.. 2006. Calcimicrobial stromatolites at the Permian–Triassic boundary in a western Tethyan section, Bukk Mountains, Hungary. Sedimentary Geology 185:239253.CrossRefGoogle Scholar
Hofmann, R., Buatois, L. A., MacNaughton, R. B., and Mángano, M. G.. 2015. Loss of the sedimentary mixed layer as a result of the end-Permian extinction. Palaeogeography, Palaeoclimatology, Palaeoecology 428:111.CrossRefGoogle Scholar
Holland, S. M., and Patzkowsky, M. E.. 2015. The stratigraphy of mass extinction. Palaeontology 58:903924.CrossRefGoogle Scholar
Horne, D. J., Brandão, S. N., and Slipper, I. J.. 2011. The platycopid signal deciphered: responses of ostracod taxa to environmental change during the Cenomanian–Turonian boundary event (Late Cretaceous) in SE England. Palaeogeography, Palaeoclimatology, Palaeoecology 308:304312.CrossRefGoogle Scholar
Hu, S., Zhu, M., Steiner, M., Luo, H., Zhao, F., and Liu, Q.. 2010. Biodiversity and taphonomy of the Early Cambrian Guanshan biota, eastern Yunnan. Science China Earth Sciences 53:17651773.CrossRefGoogle Scholar
Jiang, H. S., Lai, X. L., Sun, Y. D., Wignall, P. B., Liu, J. B., and Yan, C. B.. 2014. Permian–Triassic conodonts from Dajiang (Guizhou, South China) and their implication for the age of microbialite deposition in the aftermath of the End-Permian mass extinction. Journal of Earth Science 25:413430.CrossRefGoogle Scholar
Jin, Y. G., Wang, Y., Wang, W., Shang, Q. H., Cao, C. Q., and Erwin, D. H.. 2000. Pattern of marine mass extinction near the Permian–Triassic boundary in South China. Science 289:432436.CrossRefGoogle ScholarPubMed
Karanovic, I., Lavtizar, V., and Djurakic, M.. 2017. A complete survey of normal pores on a smooth shell ostracod (Crustacea): landmark-based versus outline geometric morphometrics. Journal of Morphology 278:10911104.CrossRefGoogle ScholarPubMed
Kershaw, S., Crasquin, S., Li, Y., Collin, P. Y., Forel, M.-B., Mu, X., Baud, A., Wang, Y., Xie, S., Maurer, F., and Guo, L.. 2012. Microbialites and global environmental change across the Permian–Triassic boundary: a synthesis. Geobiology 10:2547.CrossRefGoogle ScholarPubMed
Kershaw, S., Tang, H., Li, Y., and Guo, L.. 2018. Oxygenation in carbonate microbialites and associated facies after the end-Permian mass extinction: problems and potential solutions. Journal of Palaeogeography 7:3247.CrossRefGoogle Scholar
Kiessling, W., Schobben, M., Ghaderi, A., Hairapetian, V., Leda, L., and Korn, D.. 2018. Pre–mass extinction decline of latest Permian ammonoids. Geology 46:283286.CrossRefGoogle Scholar
Korn, D., Ghaderi, A., Ghanizadeh Tabrizi, N., and Gliwa, J.. 2020. The morphospace of Late Permian coiled nautiloids. Lethaia 53:154165.CrossRefGoogle Scholar
Kornicker, L. S. 1959. Distribution of the ostracode suborder Cladocopa, and a new species from the Bahamas. Micropaleontology 5:6975.CrossRefGoogle Scholar
Lehrmann, D. J., Payne, J. L., Enos, P., Montgomery, P., Wei, J., Yu, Y., Xiao, J., and Orchard, M. J.. 2005. Field Excursion 2: Permian–Triassic boundary and a Lower–Middle Triassic boundary sequence on the Great Bank of Guizhou, Nanpanjiang basin, southern Guizhou Province. Albertiana 33:169186.Google Scholar
Lethiers, F., and Whatley, R.. 1994. The use of Ostracoda to reconstruct the oxygen levels of Late Palaeozoic oceans. Marine Micropaleontology 24:5769.CrossRefGoogle Scholar
Li, F., Yan, J., Chen, Z. Q., Ogg, J. G., Tian, L., Korngreen, D., Liu, K., Ma, Z., and Woods, A. D.. 2015. Global oolite deposits across the Permian–Triassic boundary: a synthesis and implications for palaeoceanography immediately after the end-Permian biocrisis. Earth-Science Reviews 149:163180.CrossRefGoogle Scholar
Li, F., Gong, Q., Burne, R. V., Tang, H., Su, C., Zeng, K., Zhang, Y., and Tan, X.. 2019. Ooid factories operating under hothouse conditions in the earliest Triassic of South China. Global and Planetary Change 172:336354.CrossRefGoogle Scholar
Marcoux, J., and Baud, A.. 1986. The Permo–Triassic boundary in the Antalya Nappes (Western Taurides, Turkey). Memorie della Società Geologica Italiana 34:243252.Google Scholar
Martindale, R. C., Foster, W. J., and Velledits, F.. 2019. The survival, recovery, and diversification of metazoan reef ecosystems following the end-Permian mass extinction event. Palaeogeography, Palaeoclimatology, Palaeoecology 513:100115.CrossRefGoogle Scholar
Martins, M. J. F., Puckett, T. M., Lockwood, R., Swaddle, J. P., and Hunt, G.. 2018. High male sexual investment as a driver of extinction in fossil ostracods. Nature 556:366369.CrossRefGoogle ScholarPubMed
McGowan, A. J. 2004. Ammonoid taxonomic and morphologic recovery patterns after the Permian–Triassic. Geology 32:665668.CrossRefGoogle Scholar
McGowan, A. J., and Smith, A. B.. 2007. Ammonoids across the Permian/Triassic boundary: a cladistic perspective. Palaeontology 50:573590.CrossRefGoogle Scholar
O'Neil, G. R., Tackett, L. S., and Meyer, M.. 2020. Petrographic evidence for Ediacaran microbial mat-targeted behaviors from the great basin, United States. Precambrian Research 345:105768.CrossRefGoogle Scholar
Payne, J. L., Lehrmann, D. J., Follett, D., Seibel, M., Kump, L. R., Riccardi, A., Altiner, D., Sano, H., and Wei, J.. 2007. Erosional truncation of uppermost Permian shallow-marine carbonates and implications for Permian–Triassic boundary events. Geological Society of America Bulletin 119:771784.CrossRefGoogle Scholar
Pruss, S. B., Bottjer, D. J., Corsetti, F. A., and Baud, A.. 2006. A global marine sedimentary response to the end-Permian mass extinction: examples from southern Turkey and the western United States. Earth-Science Reviews 78:193206.CrossRefGoogle Scholar
Qiu, X., Tian, L., Wu, K., Benton, M. J., Sun, D., Yang, H., and Tong, J.. 2019. Diverse earliest Triassic ostracod fauna of the non-microbialite-bearing shallow marine carbonates of the Yangou section, South China. Lethaia 52:583596.CrossRefGoogle Scholar
Ramos, L., Cusminsky, G., Schwalb, A., and Alperin, M.. 2016. Morphotypes of the lacustrine ostracod Limnocythere rionegroensis Cusminsky & Whatley from Patagonia, Argentina, shaped by aquatic environments. Hydrobiologia 786:137148.CrossRefGoogle Scholar
R Core Team. 2020. R: a language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria. https://www.r-project.org.Google Scholar
Richoz, S. 2006. Stratigraphie et variations isotopiques du carbone dans le Permien supérieur et le Trias inférieur de quelques localités de la Néotéthys (Turquie, Oman et Iran). Mémoires de Géologie (Lausanne) 46:1283.Google Scholar
Rohlf, F. J. 2015. The tps series of software. Hystrix-Italian Journal of Mammalogy 26:912.Google Scholar
Rohlf, F. J., and Slice, D.. 1990. Extensions of the Procrustes method for the optimal superimposition of landmarks. Systematic Biology 39:4059.Google Scholar
Ruta, M., Angielczyk, K. D., Frobisch, J., and Benton, M. J.. 2013. Decoupling of morphological disparity and taxic diversity during the adaptive radiation of anomodont therapsids. Proceedings of the Royal Society of London B 280:20131071.Google ScholarPubMed
Schobben, M., Stebbins, A., Ghaderi, A., Strauss, H., Korn, D., and Korte, C.. 2016. Eutrophication, microbial-sulfate reduction and mass extinctions. Communicative and Integrative Biology 9:e1115162.CrossRefGoogle ScholarPubMed
Smithwick, F. M., and Stubbs, T. L.. 2018. Phanerozoic survivors: actinopterygian evolution through the Permo–Triassic and Triassic–Jurassic mass extinction events. Evolution 72:348362.CrossRefGoogle ScholarPubMed
Song, H., Wignall, P. B., Tong, J., and Yin, H.. 2013. Two pulses of extinction during the Permian–Triassic crisis. Nature Geoscience 6:5256.CrossRefGoogle Scholar
Song, H., Wignall, P. B., and Dunhill, A. M.. 2018. Decoupled taxonomic and ecological recoveries from the Permo–Triassic extinction. Science Advances 4:eaat5091.CrossRefGoogle ScholarPubMed
Stanley, S. M. 2016. Estimates of the magnitudes of major marine mass extinctions in earth history. Proceedings of the National Academy of Sciences USA 113:E6325E6334.CrossRefGoogle ScholarPubMed
Stubbs, T. L., and Benton, M. J.. 2016. Ecomorphological diversifications of Mesozoic marine reptiles: the roles of ecological opportunity and extinction. Paleobiology 42:547573.CrossRefGoogle Scholar
Suarez-Gonzalez, P., Benito, M. I., Quijada, I. E., Mas, R., and Campos-Soto, S.. 2019. “Trapping and binding”: a review of the factors controlling the development of fossil agglutinated microbialites and their distribution in space and time. Earth-Science Reviews 194:182215.CrossRefGoogle Scholar
Sudar, M., Perri, M. C., and Haas, J.. 2008. Conodonts across the Permian–Triassic boundary in the Bükk Mountains (NE Hungary). Geologica Carpathica 59:491502.Google Scholar
Sun, Y., Joachimski, M. M., Wignall, P. B., Yan, C., Chen, Y., Jiang, H., Wang, L., and Lai, X.. 2012. Lethally hot temperatures during the Early Triassic greenhouse. Science 338:366–70.CrossRefGoogle ScholarPubMed
Tang, H., Kershaw, S., Liu, H., Tan, X., Li, F., Hu, G., Huang, C., Wang, L., Lian, C., and Li, L.. 2017. Permian–Triassic boundary microbialites (PTBMs) in southwest China: implications for paleoenvironment reconstruction. Facies 63:2.CrossRefGoogle Scholar
Tarhan, L. G., Planavsky, N. J., Laumer, C. E., Stolz, J. F., and Reid, R. P.. 2013. Microbial mat controls on infaunal abundance and diversity in modern marine microbialites. Geobiology 11:485497.CrossRefGoogle ScholarPubMed
Twitchett, R. J., Krystyn, L., Baud, A., Wheeley, J. R., and Richoz, S.. 2004. Rapid marine recovery after the end-Permian mass-extinction event in the absence of marine anoxia. Geology 32:805808.CrossRefGoogle Scholar
Wan, J., Yuan, A., Crasquin, S., Jiang, H., Yang, H., and Hu, X.. 2019. High-resolution variation in ostracod assemblages from microbialites near the Permian–Triassic boundary at Zuodeng, Guangxi region, South China. Palaeogeography, Palaeoclimatology, Palaeoecology 535:109349.CrossRefGoogle Scholar
Wang, W. Q., Garbelli, C., Zhang, F. F., Zheng, Q. F., Zhang, Y. C., Yuan, D. X., Shi, Y. K., Chen, B., and Shen, S. Z.. 2020. A high–resolution Middle to Late Permian paleotemperature curve reconstructed using oxygen isotopes of well–preserved brachiopod shells. Earth and Planetary Science Letters 540:116245.CrossRefGoogle Scholar
Wang, Y., Sadler, P. M., Shen, S. Z., Erwin, D. H., Zhang, Y. C., Wang, X. D., Wang, W., Crowley, J. L., and Henderson, C. M.. 2014. Quantifying the process and abruptness of the end-Permian mass extinction. Paleobiology 40:113129.CrossRefGoogle Scholar
Wrozyna, C., Neubauer, T. A., Meyer, J., and Piller, W. E.. 2016. Shape variation in neotropical Cytheridella (Ostracoda) using semilandmarks-based geometric morphometrics: a methodological approach and possible biogeographical implications. PLoS ONE 11:e0168438.CrossRefGoogle ScholarPubMed
Wrozyna, C., Meyer, J., Gross, M., Ramos, M. I. F., and Piller, W. E.. 2018. Definition of regional ostracod (Cytheridella) morphotypes by use of landmark-based morphometrics. Freshwater Science 37:573592.CrossRefGoogle Scholar
Yang, H., Chen, Z. Q., and Ou, W. Q.. 2015. Microconchids from microbialites near the Permian–Triassic boundary in the Zuodeng Section, Baise Area, Guangxi Zhuang Autonomous Region, South China and their paleoenvironmental implications. Journal of Earth Science 26:157165.CrossRefGoogle Scholar
Yang, S., Hao, W., and Wang, X.. 1999. Conodont evolutionary lineages, zonation, and PT boundary beds in Guangxi, China. Biotic and geological developments in the Paleo-Tethys in China. Peking University Press, Beijing, pp. 8195.Google Scholar
Yin, H., Zhang, K., Tong, J., Yang, Z., and Wu, S.. 2001. The global stratotype section and point (GSSP) of the Permian–Triassic boundary. Episodes 24:102114.Google Scholar
Yin, H., Jiang, H., Xia, W., Feng, Q., Zhang, N., and Shen, J.. 2014. The end-Permian regression in South China and its implication on mass extinction. Earth-Science Reviews 137:1933.CrossRefGoogle Scholar
Figure 0

Figure 1. Global paleogeographic map of the Permian/Triassic boundary time interval showing locations of sample sites in this study, based on reconstruction by Golonka (2002). Hu: Bálvány-North, Hungary; Ir: Elikah River, north Iran; SC: Zuodeng and Dajiang, South China; Tk: Çürük Dağ, Turkey.

Figure 1

Figure 2. An example of the landmark configuration used to investigate changes in morphospace on the left valve outline, in right lateral view, shown using a specimen of Bairdiacypris ottomanensis Crasquin-Soleau et al., 2004 in Wan et al. (2019). Scale bar, 0.1 mm.

Figure 2

Figure 3. Principal component (PC) analysis results and thin-plate splines of morphological variances of ostracods from all five sections in this study. A, Percentages of the first 10 PC axes; B, scatter plots of PC 1 and PC 2 and PC 2 and PC 3; C, thin-plate splines of mean shape, hypothetical shapes (left), and sample shapes (right) at extreme scores.

Figure 3

Table 1. Results of the principal component (PC) analysis (scores of first three PC axes and shape changes on these three axes). DB, dorsal border; VB, ventral border; Hmax, maximum height; Lmax, maximum length.

Figure 4

Figure 4. Morphospace occupation from the pre-extinction interval (Pre-E.) to the extinction interval (Ext.). A, Dajiang; B, Bálvány-North; C, Elikah River. From left to right for each row, we show scatter plots of principal component (PC) 1 and PC 2, scatter plots of PC 2 and PC 3, volume of morphospace (VoM), sum of variances (SoV). n = number of species in each time bin.

Figure 5

Figure 5. Morphospace occupation from the pre-extinction interval (Pre-E.) to the postextinction interval (Post-E.). A, Zuodeng; B, Çürük Dağ; C, all five sections. From left to right for each row, we show scatter plots of principal component (PC) 1 and PC 2, scatter plots of PC 2 and PC 3, volume of morphospace (VoM), sum of variances (SoV). n = number of species in each time bin. Note that when all five sections are combined, the data at the postextinction interval are only available from Zuodeng and Çürük Dağ.

Figure 6

Figure 6. Decoupling of log-ratio changes between taxonomic diversity and morphological disparity during the extinction interval. Asterisk (*) marks changes during the postextinction interval.

Figure 7

Table 2. Log ratios of changes in taxonomic diversity and morphological disparity. VoM, volume of morphospace by PC1 to PC3; SoV, sum of variances. When all five sections are combined, an asterisk (*) indicates the data at the postextinction interval are only available from Zuodeng and Çürük Dağ. Green indicates a decrease; red indicates an increase.

Figure 8

Figure 7. Morphospace occupation between microbialites (MicroB.) and non-microbialite (Non-MicroB.) samples from the extinction interval. A, Zuodeng; B, Çürük Dağ. From left to right for each row, we show scatter plots of principal component (PC) 1 and PC 2, scatter plots of PC 2 and PC 3, volume of morphospace (VoM), sum of variances (SoV). n = number of species in each time bin.