Bailongia longicaudata: A new species of Artiopod from the Middle Cambrian Guanshan Biota of Yunnan Province, China.

The Middle Cambrian Guanshan Biota of Yunnan Province, China, preserves a wide range of soft-bodied fossils with fidelity similar to that seen in the slightly younger Burgess Shale. These fossils were originally discovered during construction work, and the sites which yielded the first known Guanshan Biota fossils have subsequently been lost, but recognition of the importance of these fossils led to a search for new localities, with several subsequently being discovered in Yiliang, Malong, Wuding, and Huize counties, as well as sites within the city prefecture of Kunming. Among these fossils are rare non-Trilobite Artiopods (the group which includes the Trilobites as well as a variety of less well known Palaeozoic Arthropod clades, most of which did not survive beyond the Cambrian), although the last specimen was described in 2008.

In a paper published in the Geological Magazine on 15 December 2021, De-Guang Jiao and Kun-Sheng Du of the Research Center of Paleobiology at Yuxi Normal University, Xi-Guang Zhang and Jie Yang of the Key Laboratory for Palaeobiology and Ministry for Education and China International Joint Laboratory for Palaeoenvironment at Yunnan University, and Daniel Eggink also of the Research Center of Paleobiology at Yuxi Normal University, describe a new species of non-Trilobite Artiopod from an outcrop producing Guanshan Biota fossils in Yiliang County in Yunnan Province, China.

The new species is named Bailongia longicaudata, where 'Bailongia' refers to the village of Bailong, which is close to the site where the specimen from which the species is described was found, and 'longicaudata' means 'long-tail'. The specimen is 5 mm in length, including the antennae and tailspine and 2.1 mm wide. It has a wide cephalon (head-segment), with eyes located close to the posterior corners, a tapering thorax with nine segments, and a long tailspine.

 

Completely articulated specimen of Bailongia longicaudata from the Cambrian Stage 4 Guanshan Biota. (a) RCP 0001b preserving the semielliptical cephalon with right genal spine, small antennae, possible scales on the right antenna (arrows), cephalic limbs, eyes, nine tapering tergites, lamellae of exopod and the long tailspine. (b) RCP 0001a preserved the semi-elliptical head shield, cephalic limbs, eyes, nine tapering tergites, a trunk endopod and the long tailspine. (c) Interpretive drawing of RCP 0001a. (d), (e) Close-up of cephalon, genal spine, antennae, possible scales on the right antenna (arrows), post-antennal cephalic limbs and eyes. (f) Details of the eyes, the only exposed trunk endopod. (g) Close-up of the lamellae of trunk exopod. (h) Details of the tergites two to six. (i) Close-up of tergites six to nine, photographed with fluorescent microscopy. Abbreviations: ant, antenna; en, endopod; ey, eye; gs, genal spine; hs, head shield; hy, hypostome; lam, lamellae; lim, limb; Tn, tergite n; ts, tailspine. Jiao et al. (2021).

Bailongia longicaudata has all the key features of the Artiopoda (first antenniform limbs, exopod with lamellae, and homonomous dorsal exoskeleton with expanded tergopleurae), but none of the diagnostic features needed to place it within one of the currently recognised Artiopod sub-groups. 

 

Bailongia longicaudata from the Guanshan Biota. (a) Fluorescent photograph of RCP 0001b. (b) Interpretive drawing of RCP 0001b showing the cephalon with genal spine, small antennae, possible scales on the right antenna (arrows), cephalic limbs, eyes, nine tapering tergites and the long tailspine. (c) Morphological reconstruction. Abbreviations as above Jiao et al. (2021).

A phylogenetic analysis carried out by Jiao et al. using the TNT software package suggests that Bailongia longicaudata is part of a clade which also includes two of the main Artiopod divisions, the Trilobites and Vicissicaudates, to the exclusion of the third, the Protosuturans. In this reconstruction, the Trilobites and Vicissicaudates are sister groups, with Bailongia longicaudata being the sister to this combined group.

 

Results of parsimony analyses. All trees depict a strict consensus. (a) Equal weight parsimony (two most-parsimonious trees (MPTs), 258 steps, consistency index (CI) = 0.415, retention index (RI) = 0.742). (b) Implied weight parsimony, k = 4, 5 (two MPTs, CI = 0.408, RI = 0.735). (c) Implied weight parsimony, k = 10 (one MPT, CI = 0.413, RI = 0.741). Bremer support values are shown in bold above each node in (a). Jack-knife resampling values greater than 50% are shown in bold and italics under each node. Bootstrap resampling values greater than 50% are shown under each node. Jiao et al. (2021).

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Brachiopod communities of the Early Cambrian Guanshan Lagerstätte of Yunnan Province, China, and their associated facies.

Discoveries of spectacular soft-bodied animal assemblages from Cambrian Konservat-Lagerstätten around the world have provided incredible insights into the anatomy, behaviour, ecology and early evolution of complex Metazoans. Early Cambrian Konservat-Lagerstätten from China, such as the Niutitang Fauna, Chengjiang Biota, Guanshan Biota, Shipai Biota, Balang Fauna, Kaili Biota and the newly discovered Qingjiang Biota, span a wide range of geological time and provide a unique opportunity to map changes in Early Cambrian ecological communities over time. The Guanshan Biota (Cambrian Series 2, Stage 4), one of the oldest Konservat-Lagerstätten from South China, occurs in the Wulongqing Formation in eastern Yunnan. Younger than the famous Chengjiang and Malong biotas (Cambrian Series 2, Stage 3), but older than the Kaili and Burgess Shale biotas (Miaolingian Series, Wuliuan Stage), the Guanshan Biota is a significant evolutionary bridge in our understanding of the chronology of the Cambrian radiation and its aftermath. Recent intensive, although preliminary, excavations reveal that the Guanshan Biota is composed of 14 major animal groups and various ichnotaxa. Uniquely, the Guanshan Biota is dominated by Brachiopods, which serves to distinguish it from all other Cambrian Konservat-Lagerstätten, which are dominated (in terms of diversity and relative abundance) by Euarthropod groups. Faunal overturn between the Chengjiang, Malong and Guanshan biotas suggests that the sessile benthic members of the assemblages are affected by the same factors that affect mobile Trilobites. Furthermore, the Wulongqing Formation is characterized by bioturbated, thinly bedded sandstones, siltstones and mudstones, which crop out widely in eastern Yunnan, South China and represent a transgressive systems tract directly after the Hongjingshao Formation. Previous, very generalised, sedimentological work on the Wulongqing Formation suggests a relative shallow (shoreface to offshore transitional) depositional environment, which is distinct from the generally deeper water (in some cases slope to basin) setting of most other early Cambrian deposits that preserve soft tissues.

Continuous exploration and research in the Guanshan Biota has led to the discovery of multiple new localities and increased systematic descriptions of the fossil taxa, including documentation of one of the oldest examples of kleptoparasitism in the fossil record. The Wulongqing Formation is generally poorly exposed at most sites and artificial cover by urban landscaping has obscured many of the classic flat-lying sites. There has been a dearth of even basic ecological analyses of the faunal assemblages from the Guanshan Biota, and the detailed sedimentology and lithology of the succession are very poorly resolved.

In a paper published in the Journal of the Geological Society on 18 September 2020, Feiyang Chen, Glenn Brock, and Zhiliang Zhang of the State Key Laboratory of Continental Dynamics, Shaanxi Key Laboratory of Early Life & Environments and Department of Geology at Northwest University, and the Department of Biological Sciences at Macquarie University, Brittany Laing, also of the Department of Biological Sciences at Macquarie University, and of the Department of Geological Sciences at the University of Saskatchewan, and Xinyi Ren and Zhifei Zhang, also of the State Key Laboratory of Continental Dynamics, Shaanxi Key Laboratory of Early Life & Environments and Department of Geology at Northwest University, aim to comprehensively document the lithofacies and sedimentology of the basal part of the Wulongqing Formation hosting soft-bodied fossils at the Shijiangjun section, the best-exposed succession in Wuding county, eastern Yunnan. Zhang et al. hope these data will help to decipher the relationships between microfacies, sedimentary events and faunal overturn after transgression and how fluctuations in depositional environments affect the faunal composition during the later stages of the Cambrian evolutionary radiation.

 

Localities of the Guanshan Biota and distribution of lower Cambrian outcrops in eastern Yunnan, South China. The Shijiangjun section in Wuding county is represented by locality 1. Chen et al. (2020).

The uppermost Hongjingshao and lower Wulongqing formations are exposed in the newsectionwith a very clear conformable stratigraphic contact. This provides an opportunity to document temporal changes in the faunal composition and sedimentary environments at the centimetre scale based on lithological, sedimentological, palaeontological and ichnological evidence. Chen et al.'s detailed study enables an interpretation of the depositional environment associated with the lower Wulongqing Formation and facilitates a better resolution of the process and drivers of faunal overturn that distinguish the Guanshan faunas from the Wuding, Malong and Kunming areas.

 

Stratigraphic column, sedimentology, facies, structures, bioturbation index and pie charts of relative faunal abundance in the lower Wulongqing Formation at the Shijiangjun section. The 41 rock samples taken for cutting and polishing are marked on the left-hand side of the column. The datum point (0 cm) is the boundary between the upper Hongjingshao and lower Wulongqing formations. Four facies (F1, F2, F3 and F4) were recognized. The bioturbation index for each polished rock samples was evaluated based on the extent to which bioturbation disrupted the primary bedding. The composition of the fossil assemblage is shown by pie charts at the phylum level and the brachiopod genus level. Abbreviations: Ass., assemblages; BI, bioturbation index; F., facies. HJS, Hongjingshao Formation; Sam., sample number; WLQ, Wulongqing Formation. Chen et al. (2020).

The Shijiangjun section was measured through the uppermost Hongjingshao and lower Wulongqing formations and large-scale sedimentary features were noted. A total of 2988 fossil specimens were collected in one four-week field season sequentially and independently from ten contiguous siltstone and mudstone layers varying in thickness from 6 to 110 cm. Whole fossils were identified and classified to the phylum level and, where applicable, Brachiopod genera were identified. Faunal relative abundances are based on all the well-preserved fossils, whereas trace fossils and fragmentary and unidentifiable specimens, as well as all shell concentrations, were excluded.

 

Field photographs of the lower Wulongqing Formation at the Shijiangjun section. Yellow upper case letters mark the layers yielding a fossil assemblage in accordance with Figure 2. (a) General view of the lower part of the section. The yellow line on the bottom of the section indicates the lithological contact between the Hongjingshao and Wulongqing formations. (b) Load casts at the bottom of the sandstone deposits. (c) Wavy bedding structure above layer C. (d) Normal graded bedding from fossil-yielding layer D, scale bar: 1 cm. (e) Gutter casts, lenticular bedding and wavy ripples at the Shijiangjun section. (f ) Plan view of gutter casts from fossil-yielding layer F. (g) The simplified palaeoenvironmental reconstruction for the Guanshan Biota from Wuding area. Abbreviations: HJS, Hongjingshao Formation; WLQ, Wulongqing Formation. Chen et al. (2020).

Lithological samples (41 in total) in oriented plaster jackets were collected at intervals from mudstone and sandstone layers through the section. All the samples collected for rock slabs and thin sections were cut and polished at the Shaanxi Key Laboratory of Early Life and Environments, China and revealed the vertical internal organization of the physical and biogenic sedimentary structures. Scanning of the polished slabs was achieved using an Epson V370 photo-scanner at Macquarie University, Australia. Adobe Photoshop was used to digitally improve the visibility (contrast) of the sedimentary and ichnological structures. Sedimentary characteristics, including grain size, lithology, sedimentary structures and vertical bioturbation intensity were recorded. The percentage bioturbation in each sample was evaluated using Adobe Photoshop. The bioturbation area was selected using the lasso tool and recorded through the measurement log in pixels. This was then divided by the total area in pixels to determine the percentage of bioturbation. These percentages were then used within a bioturbation index. All the rock samples and fossil specimens investigated are deposited in the Early Life Institute and the Department of Geology, Northwest University, Xi’an China.

The stratigraphic section is 8 m thick and composed of distinctive intercalated beds of thin to thick (5–60 cm), very fine to very coarse sandstone, siltstone and mudstone. Rare gravels and isolated pebbles occur in sandstone samples S2, S3, S4, S5, S6, S9 and S16, in addition to two layers of purple muddy medium to coarse sandstone (S15 and S16), which contained 3–5% oolite grains. Commonly developed primary sedimentary structures include massive bedding, normal graded bedding, lenticular bedding and wavy bedding. The contacts between the sandstones and mudstones are sharp. The most common local erosion structures include gutter casts, erosional scour and low ripple marks. The measured section has an overall low level of bioturbation, with some highly bioturbated beds occurring in the middle part of the section (3.3–5.3 m) accompanying the only identified trace fossil Teichichnus? isp. Based on lithological, sedimentary and ichnological features, the section is divided into four distinct facies that repeat and cycle throughout the section.

 

Polished slabs of the lower Wulongqing Formation at the Shijiangjun section, with facies classification and sample numbers in parentheses. (a), (b) Slabs of Facies 1 showing wavy laminations, graded lamination, lenticular lamination and erosive base. (c) Silty mudstone without sedimentary structures representing Facies 2. (d)–(g) Massive sandstone deposits representing Facies 3. (d), (e) Poorly sorted, angular to sub-angular clasts with few granules. (f), (g) Highly bioturbated sandstone with glauconite grains. (h) Mudstone without structures (Facies 4). Scale bars 5 mm. Chen et al. (2020).

Facies 1 consists of thinly bedded mudstone with thin to thick laminated siltstone and/or very fine sandstone. The silt and sand grains are medium to well-sorted, mainly angular to subrounded, low to high sphericity with increasing sphericity upsection. Fine to medium sandstone intercalations occur as lenticular and wavy bedding. Laterally discontinuous millimetre-scale (mainly 3–5 mm with some about 1 mm) silt laminations are common. Graded laminations (4–10 mm) manifest either as a sharp horizontal contact or an erosional base (sole marks). The contact between sand and mud is nearly always sharp. Bioturbation is generally indistinct and unidentifiable, with Teichichnus? isp. documented in two samples. The bioturbation index ranges from 0 to 3, with a predominant index of 0–1 (up to 4.89% disturbance). More heavily bioturbated beds exist locally (M5 and M20) with indexes of 2–3 recording up to 40% sedimentary fabric disturbance. The graded laminations and erosive bases suggest deposition from decelerating flows. The medium maturity of the sand/silt laminations probably indicates a certain degree of winnowing and transportation.

The interbedded mudstone and sandstone reflect an alternation of quiet water sediment fallout (low energy) combined with relatively high-energy flows.

 

Photomicrographs of thin sections from the lower Wulongqing Formation at the Shjiangjun section showing four lithofacies types. (a) Medium sorted irregular grains from Facies 1. (b) Graded laminations with an erosional base from Facies 1. (c) Mudstone with low content of well-sorted silt grains from Facies 2. (d) Poorly sorted grains with low sphericity from Facies 3. (e) Common glauconite grains within Facies 3; note the iron oxides within grains (black arrows). (f ) Highly bioturbated sandstone from Facies 3. (g) Poorly sorted sandstone from Facies 3, coarse grains are irregular with low sphericity. (h) Uniform mudstone of Facies 4. All photomicrographs were taken with parallel light except (d), which is under cross-polarized light. Scale bars 1 mm. Chen et al. (2020).

Facies 2 is represented by uniform mudstones with occasional millimetre-scale silt laminations (no more than 1 mm). The silt grains are moderately sorted, angular to subrounded (low content) and of low sphericity. Interestingly, the M10 layer contains a higher concentration of muscovite than any other layer. Fragmentary shelly fossils are often present and are preserved parallel or oblique to bedding, with a particularly high concentration of trilobite fragments documented in layer M25. Bioturbation is rare (BI = 0), with the percentage bioturbation never exceeding 1%.

The absence of rheological surfaces on the silty mudstone packages indicates a relatively low-energy hydrodynamic system. Abundant sub-parallel to oblique Brachiopod and/or Trilobite fragments within the mudstone indicate transportation by currents.

High rates of fallout or other unobservable environmental stressors (e.g. oxygen, salinity or temperature) may be responsible for the relative absence of bioturbation. As a result, the relatively structureless silty mudstone packages are interpreted as deposited from rapid fallout from suspension during quiet periods of fair weather conditions.

Facies 3 consists of very fine to very coarse sandstone with rare granule- to pebble-sized clasts. The granules and pebbles predominately occur in samples S2–S6, S9 and S16. The medium- to very coarse-grained sand beds from the lower and upper part of this section are characterized by very poorly to poorly sorted grains distributed within the intervals 0–2.1 m and 4.6–5.0 m. Coarse grains are mainly angular to subrounded and dominated by low to medium sphericity. Although the very fine- to medium-grained sand beds from interval 2.2–4.2 m are mainly moderately sorted, beds show medium to high sphericity. Two beds (S15 and S16) contain 1–5% elongate ooids. Most of the ooids are oval and few are rounded.

The sandstone beds are either characterised by a homogeneous uniform grain size or high bio-disturbance, which has destroyed the original sedimentary structures. Only levels S7 and S8 show weakly normal graded bedding. Sand beds S11–S15 show a relatively higher content of mud and a higher percentage of bio-disturbance (BI = 2–5). The bioturbation index and biodisturbance reach a peak of BI = 5 and 98.76% within S12, followed by S11 (80.88%) and S14 (76.16%). However, more than half of the sandstones below S11 show scarce or no bioturbation. 

The occurrence of syngenetic glauconite grains within the sandstones of Facies 3 is unique. These grains were identified based on their green colour, random microcrystalline internal texture and aggregate polarisation. They are, in some instances, coated and replaced by iron oxides (mostly hematite and goethite). These grains occur in every sandstone interbed at relatively low contents. The grains are usually medium sorted, subrounded to rounded and of medium sphericity. Although glauconite cannot be used as a specific environmental indicator, it is commonly associated with transgressive systems tracts. Different types of glauconite (i.e. autochthonous, parautochthonous and detrital) can be determined. The glauconite that usually occurs in detrital granular and sand facies lacks a diffuse green pigmentation, which often alternates between glauconite-rich and glauconite-free layers, and can be interpreted to indicate an allochthonous (e.g. parautochthonous or detrital) origin. By contrast, the low compositional and structural maturity of Facies 3, as well as a lack of glauconite in the older Hongjingshao Formation, implies a parautochthonous origin, in which the autochthonous glauconites have been transported a short distance from their original location by waves, storm currents and/or gravity flow processes.

Local observations of Facies 3 show that these sandstones have a low compositional and textural maturity, which suggests that the sediments were deposited with minimal traction and clast collisions from a proximal sediment source. Therefore the clasts retain their immature, angular texture. Storm deposits are generally understood to consist of well-sorted sand with a fining upwards sequence that reflects the waning storm waves. The storm flow usually converts to a turbidity current as the power of the storm flow weakens near the storm wave base, resulting in the suspended mud and gravel depositing together with fine suspended sediments during recessive periods.

The common occurrence of poor bedding and disordered accumulation indicate fairly rapid suspension fall out without winnowing, probably affected by gravity flow deposition in relatively deeper water. The sharp contacts at the lower and upper boundaries between the sandstones and mudstones show that each sandstone layer represents a single event. However, the changing grain size inside the thin sandstone units shows an unstable hydrodynamic environment. Facies 3 is interpreted to have been deposited within lower shoreface zone formed near the storm wave base and was affected by multiple pulses of gravity flows.

Facies 4 represents mudstones with occasional interbedded wisps of silt. The mud layers are considerably thicker (2.5–3 cm) than in other facies. The silt laminations are fairly thin (0.3–1 mm) with sharp erosive bases and a crudely micrograded lower part and structureless upper part. Shelly fossils preserved within Facies 4 are usually parallel to sub-parallel to the bedding plane. The bio-disturbance within Facies 4 is the lowest among the four facies, only up to 0.15%, resulting in a low bioturbation index (BI = 0).

These sedimentary features, along with the soft tissue preservation associated with Facies 4, suggest a mainly rapid deposition (obrution) of suspended muds settling from weak storm flows in a relatively low-energy environment.

Thousands of well-preserved fossils spanning six key animal groups (2988 specimens in total) were collected from the lower Wulongqing Formation at the Shijiangjun section during one four-week field season. The taxa include Brachiopods, Arthropods, Hyoliths, Priapulids, Vetulicolians and Anomalocaridiids in descending order of rank abundance. All these taxa are also found in the Wulongqing Formation from the Kunming and Malong areas. Brachiopods, arthropods and hyoliths form the three main components, with up to 98.9% of the total number of specimens. Even though the Anomalocaridiids, Vetulicolians and Priapulids are rare in this section, they are very important elements of Cambrian Burgess Shale-type Lagerstätten. Four genera of Organophosphatic Brachiopods, including Neobolus, Eoobolus, Westonia, Linnarssonia, and two calcareous taxa (Kutorgina and Nisusia) occur throughout the section. Neobolus is the most abundant genus (40.2%), followed by Eoobolus (28.9%) and Westonia (27.2%). However, Arthropods remain the most diverse group, composed of Trilobites, Bradoriids, Guangweicaris, Panlongia, Isoxys, Tuzoia and Leanchoilia. Among these, Trilobites are the most abundant taxon (82%).

 

Pie charts of relative abundance for the Malong Fauna and the Guanshan Biota. Note the rising relative abundance of Brachiopods in the Guanshan Biota. Chen et al. (2020).

Fossil data from every mudstone layer was obtained during four weeks of intensive fieldwork in 2018. The fossil composition within assemblages A and B is similar, consisting of five animal groups, while faunal diversity decreases in assemblages C–F. This is followed by an increased diversity associated with faunal assemblages G–J. Faunal assemblage I has the highest diversity, with almost all taxa known from the entire section concentrated in this assemblage. Assemblage F has the greatest abundance of fossils (748 specimens) accounting for 25% the total number of individuals, followed by assemblages C, B, G and J.

The relative abundance of individual specimens from ten sampling layers was obtained to gauge the baseline assemblage structure. Assemblages A and B are dominated by Arthropods, accounting for 63.6 and 59.8%, respectively. Brachiopods dominate all other assemblages from layers C–J, with some fluctuation of composition in the relative abundance between Brachiopod taxa. The abundance of brachiopods reaches a peak within assemblage F. Hyoliths, a common early Cambrian group, occur throughout the entire section, except for assemblage G. Anomalocaridiids, Vetulicolians and Priapulids are interspersed irregularly within the assemblages.

The relative abundance of six genera of Brachiopods throughout the section is very instructive. Assemblage A is composed, almost equally, of three genera (Neobolus, 36.4%; Eoobolus, 36.4%; and Linnarssonia, 27.2%), whereas assemblage B contains a higher proportion of Neobolus (51.1%), with the relative abundance of the remaining two taxa 26.1 and 22.8%, respectively. Westonia occurs as a small proportion of assemblage C, whereas Neobolus and Eoobolus together exceed 97%. Assemblages C and D are mainly composed of Eoobolus (20.5 and 62.8%, respectively) and Neobolus (77.3 and 26.7%, respectively) with minor Westonia. By contrast, Westonia reaches a higher relative abundance (26.2%) in assemblage F. Eoobolus dominates assemblages G and H (52.4 and 64.2%, respectively), where Westonia also reaches a higher proportion of the assemblage (44.7% in G). Assemblages I and J are both dominated by Westonia, with 61.5 and 88% relative abundance, respectively; Eoobolus (24 and 9.6%, respectively) ranks second in these assemblages. The rare calcareous Brachiopods Kutorgina and Nisusia are restricted to the upper part of the section in assemblages I and J.

 

Stratigraphic fluctuation in the relative abundance of the community at the (a) phylum level and (b) Brachiopod genus level from the Shijiangjun section. Chen et al. (2020).

The lower part of the Wulongqing Formation (0–6 m) at the Shijiangjun section also contains distinctive Brachiopod and Trilobite fossil concentrations. The concentrations preserved in coarser sandy deposits are highly fragmented (although also fragile and thin) and moderately wellsorted, which indicates a relatively high level of energy and transportation. Some well-preserved shell concentrations are also preserved within thin mud beds (e.g. Facies 1 and 4), occasionally restricted to single bedding planes, and in a relative sense these thin shells are characterised by low levels of fragmentation, poor sorting, low to medium disarticulation, and occur sub-parallel to bedding planes with a high ratio (over 50%) of conjoined Brachiopod shells with more or less soft tissue preservation. These taphonomic proxies indicate a relatively rapid obrution deposit and minimal transportation. The shell concentrations from the Shijiangjun section are either monospecific or paucispecific, dominated by Brachiopods or Trilobites. These concentrations are nearly always restricted to specific layers. For example, abundant Palaeolenus are exclusively found within layer M6 in assemblage B, whereas a concentration of Linnarssonia shells is known within layer M3 in assemblage A. The Brachiopod concentrations from assemblage F are most abundant and mainly composed of monospecific layers of Neobolus or Westonia, respectively. The Eoobolus and Westonia shell concentrations extend to the upper part of the section. Throughout the section, Brachiopod concentrations are completely restricted to Facies 1 and 2, whereas trilobite concentrations are mainly associated with Facies 4, which is restricted to assemblage B.

 

Exquisitely preserved soft-bodied fossils from the lower Wulongqing Formation at the Shijiangjun section. (a) Brachiopod Linnarssonia concentration from assemblage A (ELI-SJJ-001). (b) Trilobite Palaeolenus concentration from assemblage B (ELI-SJJ-002). (c), (d) Brachiopods Neobolus and Westonia concentrations from assemblage F (ELI-SJJ-003, ELI-SJJ-003-2). (e) Brachiopod Neobolus with well-preserved parasitic Tubeworms, indicated by arrows (assemblage B, ELI-SJJ-004). (f ) Brachiopod Westonia preserved with mantle canals (assemblage F, ELI-SJJ-005). (g) Rare Brachiopod Nisusia sp. (assemblage J, ELI-SJJ-006). (h) Well-preserved coiled Palaeoscolecidan (assemblage F, ELI-SJJ-007). (i) Posterior part of an indeterminate vetulicolian (assemblage A, ELI-SJJ-008). ( j) Trilobite Palaeolenus preserved with the rare digestive system (assemblage B, ELI-SJJ-009). Scale bars: (a), (e)–(h) and (j) 2 mm; (b)–(d), (i) 1 cm. Chen et al. (2020).

Remarkable soft tissue preservation occurs in all assemblages except D and E, demonstrating the high preservation potential within facies at the Shijiangjun section of the Wulongqing Formation in the Wuding area. Tube-dwelling organisms encrusting to Neobolus shells (with exceptionally preserved setae and soft viscera) are fairly common within the lower part of the section within mudstone beds (layers A, B, C and F). Abundant specimens of Westonia display high-quality soft tissue preservation from assemblage F, including setal fringes and mantle canals. Palaeoscolecidan Worms, as an important component of lower Paleozoic soft-bodied assemblages, were found throughout the section, except for assemblage C. Relatively rare Vetulicolians occur at the base and in the upper part of the section (assemblages A, B, I and J). Anomalocaridiids are the rarest element in the section, only preserved as isolated frontal appendages in assemblages I and J. The rare oldest known digestive system of Trilobites have also been preserved in the Wuding area, but only in assemblage B.

Heterolithic successions consisting of sandstone beds interbedded with mudstones are usually deposited below the fair weather wave base and above the storm wave base. These beds are commonly described as tabular and often show abundant erosive gutter casts. The alternation of mudstone (Facies 1, 2 and 4) and sandstone (Facies 3) layers, in addition to graded lamination/bedding, wavy bedding, ripple marks and gutter casts from the Shijiangjun section, suggests a depositional environment close to the storm wave base, which underwent multiple depositional events and episodic cycles.

Previous studies have interpreted the sedimentary environment associated with the Guanshan Biota as mainly offshore transition with common storm events, which is comparable with the Cambrian Stage 4 Emu Bay Shale from Australia. However, typical storm-generated structures such as hummocky cross-stratification, an indicator of oscillatory combined flows reflecting deposition under high-energy storm conditions are absent in the Wuding succession.

The occurrence of erosive bases, ripple marks, wavy bedding, fine-graded bedding, gutter casts and multiple massive fine to coarse deposits indicates a complex hydrodynamic environment, with less frequent waves and distal storms. Periodic subaqueous gravity flows resulted in the deposition of distinctive centimetre-scale sandstone interbeds (Facies 3) at the Shijiangjun section. Hence the sedimentary environment of the lower Wulongqing Formation in the Wuding area is largely the result of fluctuating wave energy, distal storms and gravity flows.

The centimetre-scale conglomerates characterised by high sphericity reported from the Wulongqing Formation at Malong and Kunming represent high-energy channels, probably proximal to the shoreface. The absence of basal conglomerates and the occurrence of medium to very coarse sandstones with few granules at the base of the Wulongqing Formation in the Wuding area suggest a relatively deeper and low-energy clastic sedimentary environment than that in the Malong and Kunming areas, although this remains to be tested because detailed continuous successions of the Wulongqing Formation have not been studied sedimentologically. Overall, the depositional environment here is interpreted as offshore to lower shoreface and the offshore zone, which slightly extends below the storm wave base.

The baseline time series of the fossil data recovered from the lower Wulongqing Formation at the Shijiangjun section reveals a unique transition in the structure of the benthic community over time. The relative abundance of six key Animal groups, including six Brachiopod genera, from ten sampled layers demonstrates gradual replacement, overturn and fluctuation in the faunal composition. Although Arthropods dominate the base (0–1.1 m) of the section (assemblages A and B), the proportion of Brachiopods gradually increases, replacing Arthropods as the dominant fauna in assemblages C–J, reaching peak abundance (97.99%) within assemblage F. Although there is a fluctuation in the relative abundance of Brachiopods through assemblages G–J (c. 60–80%), Arthropods maintain a relatively low, but stable, percentage.

There is no doubt that Trilobites dominated early Cambrian benthic communities in terms of diversity and abundance, which is demonstrated well in the older Chengjiang Lagerstätte and the Malong Fauna. The latter is characterized by extremely abundant and diverse Trilobites yielding from the underlying Hongjingshao Formation. However, detailed fossil data from the Guanshan Biota in Wuding and Malong areas reveals a community structure that is unique for early Cambrian Konservat-Lagerstätten, with Brachiopods dominating the benthic community in abundance, if not diversity, and often forming distinctive concentrations of shell beds in the lower Cambrian Stage 4 of the Wulongqing Formation. The ecological transition from Trilobite to Brachiopod-dominated communities occurs widely across shallow marine clastic environments across the South China Platform, coinciding with well-documented transgression events during Cambrian Age 4. Thus Organophosphatic Brachiopods diversify and become superabundant across the broad ‘shallow’ shelf of the Yangtze Platform during the final stage of the Cambrian Explosion. The rise of Organophosphatic Brachiopods as the numerically dominant element in the lower Cambrian Stage 4 Wulongqing Formation is the oldest Brachiopod-dominated soft substrate community known in the fossil record and represents a precursor to more complex community tiering and Brachiopod-dominant benthic communities during the Great Ordovician Biodiversification Event.

The Brachiopods recovered from the section include Lingulides (Eoobolus, Neobolus and Westonia), an Acrotretide (Linnarssonia) and calcareous Kutorginides (Kutorgina and Nisusia). Lingulides occur in high abundance and also form many shell concentrations within several assemblages. The number of Brachiopod concentrations (at least ten thin mud beds) far exceeds those produced by Trilobites (only one mud bed). The composition of |Brachiopod taxa within each assemblage shows a rapid transition through time. Neobolus is predominant in the lower part of the section (assemblages A–C, E and F), with Eoobolus (Lingulides) and Acrotretides common, but subordinate. The relative abundance of the Acrotheloid Brachiopods, earlier referred to as ‘Westonia’ gubaiensis, increases gradually up-section, replacing, in part, the Lingulides (Eoobolus and Neobolus) and Acrotretides. This is partly attributed to the fact that the Brachiopods of Eoobolus and Linnarssonia had a much smaller shell (about 2–5 mm in maximum length) than Westonia. In addition, Westonia has a very wide and circular shell in outline, which is potentially adapted to the shallowing seawater environment. In general, the Linguliform (e.g. Lingulides and Acrotretides) Brachiopods show a strong control on assemblage dominance, whereas calcareous forms (Kutorginides) remain rare.

Fossil concentrations, although common throughout geological time, are rarely reported from Burgess Shale-type Lagerstätten. The dominance of Brachiopods within the Guanshan Biota, compared with other Cambrian Lagerstätten, is unique. The in situ preserved Brachiopod concentrations in the Wuding area also occur in the Malong and Kunming areas, which indicates a wide geographical distribution (about 6000 km²) after the rapid transgression at the base of the Wulongqing Formation.

Overall, the fossil data show that Brachiopods quickly replaced Arthropods as the dominant fauna following a transgression that led to the deposition of the Wulongqing Formation at Wuding. Different brachiopod genera dominated different assemblages and, in places, formed distinctive shell concentrations.

The Guanshan Biota is an exceptionally preserved Konservat-Lagerstätte, uniquely characterised by brachiopod-dominated early Cambrian communities, substantially different from the Arthropod-dominated Konservat-Lagerstätten such as the Chengjiang and Burgess Shale biotas. Although the preservation of soft tissues within biomineralised and sclerotised exoskeletons is common, which is at least partly attributable to the high number of Brachiopods, Trilobites and Hyoliths, completely soft-bodied organisms (e.g. Ctenophores) are absent in the Shijiangjun section, which is similar to the Ordovician Fezouata Biota. This phenomenon is possibly related to preservation bias because the Brachiopods, Trilobites and Hyoliths are more resistant to decay and much more readily preserved within this Konservat-Lagerstätte, which might lead to an underestimation of the diversity of the Guanshan Biota in the Wuding area. The lack of completely soft-bodied taxa may be due to the lack of an exaerobic preservational trap that typifies the Burgess Shale-type deposits.

The relatively shallow sedimentary environment (lower offshore or offshore) of the Guanshan Biota also separates it from most other Cambrian Lagerstätten worldwide except, perhaps, for the early Cambrian Emu Bay Shale from Australia, which is interpreted to have been deposited in a nearshore micro-basin setting adjacent to an active tectonic margin that generated continual syndepositional faulting and slumping. The Guanshan Biota is also comparable with the Ordovician Fezouata Biota, both in terms of depositional environment and shelly faunal composition. The latter was deposited mainly in an offshore to lower shoreface setting.

Gravity, traction and turbiditic flows are responsible for the transitions from Arthropod- to Brachiopod-dominated assemblages from the lower part of the Wulongqing Formation at the Shijiangjun section. The depositional environment between the fair weather wave base and the storm wave base is usually affected by frequent event flows, such as oscillatory and gravity flows, which helps to mix oxygen-enriched surface water with stagnant bottom water, providing favourable nutrient-rich conditions for the development of the benthic community. Transportation from a nearby source, rapid fall out from suspension and the resuspension of seston provides a high nutrient load for suspension feeders such as Brachiopods to flourish.

The limited amount of bioturbation throughout most of the section seems to indicate conditions unfavourable for burrowing, resulting from high turbidity, high or low salinity, or the relatively low oxygen content, perhaps explaining the dominance of relatively small, physiological simple filter-feeding Brachiopods. The increase in the bioturbation index in the middle part of the section (3–6 m above the basal contact) is coincident with assemblages G–I, indicating more favourable conditions, probably a result of the relatively shallower depositional environment or fluctuating oxic conditions. The frequent overturn of fossil assemblages, especially Brachiopods, may be attributed to frequent environmental fluctuations and the episodic input of coarser sediments, which probably periodically interrupt the benthic suspension assemblages.

Detailed analysis of the sedimentology, lithology and structures facilitates the identification of distinct lithofacies associated with transgressive systems tracts that directly affected the composition, diversity and relative abundance of faunal assemblages in the transition from the Hongjingshao to the Wulongqing deposits. Microfacies analysis, the degree of bioturbation and the faunal composition at the lower part of the Wulongqing Formation provide a new understanding of how fluctuations in the depositional environment influenced the faunal overturn in the Guanshan Biota across the Yangtze Platform in eastern Yunnan.

This is the first detailed report of the lithofacies, depositional environments and associated relative faunal abundance in the Cambrian Age 4 Guanshan Biota. The new Shijiangjun section through the basal part of the Wulongqing Formation in the Wuding area, eastern Yunnan reveals fossil assemblages composed of six Bilaterian groups (Brachiopoda, Arthropoda, Hyolitha, Priapulida, Vetulicola and Anomalocaridiids). Detailed sedimentological, lithological and ichnological characteristics of the section indicate that: (1) hydrodynamic conditions are fluctuating, with episodic changes in energy and current regimes producing periodically coarse sand beds (Facies 3); (2) the sediments are derived from a relatively nearby source and accumulated rapidly; (3) the environment is affected by multi-period hydrodynamic events, such as storm and gravity flows forming obrution deposits; and (4) the overall sedimentary environment in the Wuding area represents a deeper offshore to lower shoreface than the Wulongqing Formation outcropping in the Malong and Kunming areas.

The community transitioned from Arthropod- to Brachiopod-dominated for the first time at the base of the Wulongqing Formation in the Shijiangjun section. Within the Brachiopod communities, a lingulate-dominated assemblage transitioned to an Acrotheloid-dominated assemblage with the new occurrence of calcareous Kutorginides up-section. The detailed study and documentation of this transition provides a better understanding of the differences in faunal composition and overturn between the Malong Fauna and Guanshan Biota. The unstable sedimentary environment with periodically sandy depositional inputs and muddy obrution deposits is probably closely associated with the observed succession of community assemblages. Brachiopods from the Guanshan Biota generally show a preference for such a fluctuating environment and adapt well to this environmental setting during the final stage of Cambrian evolutionary radiation.

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Neobolus wulongqingensis: A Cambrian Brachiopod with encrusting kleptoparasites.

Parasitism is an enduring symbiotic relationship in which the parasite is nutritionally dependent upon the host for at least part of its life cycle, increasing its own fitness in the process and directly impinging upon the biological fitness of the host. Parasite–host interactions form a significant proportion of the biotic interactions in extant global ecosystems, influencing many characteristics of species networks including behavior, population structure, and ecological function. The antagonistic relationship between parasites and hosts has also been proposed as the primary mechanism leading to the evolution and maintenance of sexual reproduction, due to the negative frequency-dependent selection associated with parasitism. Despite its obvious importance, the origins and early evolution of Metazoan parasitism remains enigmatic. Molecular phylogenies predict the emergence of parasitic clades in the Cambrian and putative instances of shell damage, shell scarring and occasional bioclaustration from the early Cambrian represent circumstantial evidence that hint at possible parasitism, but the rarity of well-preserved specimens precludes decisive identification of parasite–host interactions in the earliest Phanerozoic. Possible examples of epibiontism, commensal infestation, and hitchhiking are also known from the early Cambrian, but none of these constitute definitive instances of parasitism with a clear negative biological effect on the host. This absence of clear evidence for parasitism in the earliest animal communities may, in part, be due to a lack of cross-sectional quantitative analyses on Cambrian material of the type that have been demonstrated as necessary to identify and discriminate instances of animal parasitism in deep time.

In a paper published in the journal Nature Communications on 2 June 2020, Zhifei Zhang and Luke Strotz of the State Key Laboratory of Continental Dynamics, Shaanxi Key Laboratory of Early Life & Environments and Department of Geology at Northwest University, Timothy Topper, also of the State Key Laboratory of Continental Dynamics, Shaanxi Key Laboratory of Early Life & Environments and Department of Geology at Northwest University, and of the Department of Palaeobiology at the Swedish Museum of Natural History, Feiyang Chen, again of the State Key Laboratory of Continental Dynamics, Shaanxi Key Laboratory of Early Life & Environments and Department of Geology at Northwest University, and of the Department of Biological Sciences at Macquarie University, Yanlong Chen and Yue Liang, again of the State Key Laboratory of Continental Dynamics, Shaanxi Key Laboratory of Early Life & Environments and Department of Geology at Northwest University, Zhiliang Zhang, also of the State Key Laboratory of Continental Dynamics, Shaanxi Key Laboratory of Early Life & Environments and Department of Geology at Northwest University, of the Department of Biological Sciences at Macquarie University, Christian Skovsted, also of the State Key Laboratory of Continental Dynamics, Shaanxi Key Laboratory of Early Life & Environments and Department of Geology at Northwest University, and Department of Palaeobiology at the Swedish Museum of Natural History, and Glenn Brock, once again of the State Key Laboratory of Continental Dynamics, Shaanxi Key Laboratory of Early Life & Environments and Department of Geology at Northwest University, of the Department of Biological Sciences at Macquarie University, describe a new species of Lingulid Brachiopod from the early Cambrian Guanshan Konservat-Lagerstätte, and the encrusting kleptoparasites which cover many specimens of this species.

The early Cambrian (Stage 4) Guanshan Konservat-Lagerstätte occurs mostly in the lower 40m of the Wulongqing Formation, which crops out over a geographically wide area in eastern Yunnan, located in southern China. The Guanshan Biota is unusual in being proportionately dominated by Brachiopods, and so, is strongly differentiated from other Cambrian Konservat-Lagertätten such as the Chengjiang, Sirius Passet, Emu Bay Shale and the Burgess Shale, which are Euarthropod-dominated assemblages. 

 

Locality map and stratigraphic position of the Guanshan Konservat-Lagerstätte in Yunnan Province. (a) Locality map for the Guanshan Konservat-Lagerstätte in Yunnan Province. All specimens of Neobolus wulongqingensis included in Zhang et al.'s study were sampled from the Gaoloufang section (Locality 3). (b) Cambrian stratigraphic scheme, both international and for China, showing the relative position of the Wulongqing Formation. Zhang et al. (2020).

The new species is placed in the genus Neobolus, and given the specific name wulongqingensis, meaning 'from Wulongqing', in reference to the Wulongqing Formation, from which the fossils were extracted. It is an Organophosphatic Linguliform Brachiopod with an adult shell subcircular, no visible pits or pustules on surface, peripherally ornamented with distinct growth lines; metamorphic shell, average of 2396 μm in width and 1907 μm in length (based upon 13 measured specimens); ventral pseudointerarea orthocline to apsacline with wide and triangular pedicle groove; ventral propareas vestigial or indistinguishable; dorsal pseudointerarea forming narrow, crescent-shaped rim; ventral visceral field short, slightly thickened and not extending beyond midvalve; dorsal interior with long median septum extending to or beyond ⅓ valve length. Short spirolophe lophophore present.

 

The Brachiopod Neobolus wulongqingensis, with associated obligate, encrusting kleptoparasitic tubes. (a) ELI GB-N-0301, densely aggregated valves of Neobolus wulongqingensis forming distinctive shell beds with their associated kleptoparasites. Scale bar 4 mm. (b), (c) Specimens of Neobolus wulongqingensis with varying numbers of encrusting kleptoparastic tubes; (b) ELI GB-N-0650, (c) ELI GB-N-0648-5. (d) ELI GB-N-0008, Neobolus wulongqingensis with baculate mantle canals preserved. (e) ELI GB-N-0261-18, Neobolus wulongqingensis with encrusting kleptoparastic tubes. (f) ELI GB-N-0255-6, internal view of a pair of conjoined valves with kleptoparasitic tubes encrusted to both valves. (g) ELI GB-N-0869-2-1. Neobolus wulongqingensis with encrusting kleptoparasitic tubes and Trilobite cranidium (exuviae) lacking attached tubes. Scale bars 2 mm, unless otherwise stated. Zhang et al. (2020).

Neobolus wulongqingensis is the most numerically abundant taxon in the Wulongqing Formation, with many thousands of specimens forming dense concentrations of monotypic, mostly conjoined shells, clustered closely on bedding plane surfaces. Remarkably, many of the Brachiopod shells are encrusted with elongate, tapering biomineralised tubes. Symbiotic relationships such as this are seldom directly observed in the fossil record because taphonomic biases generally impede the preservation of direct interaction between organisms. The high-fidelity preservation and great abundance of specimens in the Wulongqing Formation provides a rare opportunity to investigate this unique interaction between a Brachiopod host and their associated encrusting tube-dwelling organisms.

 

Additional examples of Neobolus wulongqingensis from the Guanshan Biota encrusted with varying numbers of obligate, kleptoparasitic tube-dwelling organisms. (a) ELI GB-N- 263A5-1. (b) ELI GB-N-254-1-1, Neobolus wulongqingensis with visceral region preserved (c) ELI GB-N-253-19- 1-D2, Neobolus wulongqingensis with tube outlines visible from the interior of the Brachiopod shell (d) ELI GB-N-290-8-1. (e) ELI GB-N-263A-2-3, Neobolus wulongqingensis with the outline of the kleptoparasitic tubes visible from the interior of the Brachiopod shell (f) ELI GB-N-0263B-3. (g) ELI GB-N-0253. (h) 284-3-1. i, ELI GB-N-0255-8. Zhang et al. (2020).

Zhang et al. assess differences in biomass between Brachiopod individuals of the species Neobolus wulongqingensis encrusted with tubes and those individuals lacking tubes, with biomass representing a proxy for the biological fitness of an individual. This analyses suggests that the tube-dwelling organisms reduced the biological fitness of the host and, when considered in combination with observations of the preferred growth orientation of the encrusting tubes, these results suggest the interaction between the tube-dwelling organisms and their host Brachiopod represents kleptoparasitism. This instance in a Cambrian epibenthic marine community likely represents the oldest known parasite–host relationship in the fossil record and reveals that parasite–host interactions emerged in conjunction with the rise of the earliest Animal communities during the Cambrian radiation.

 

Exceptionally preserved examples of Neobolus wulongqingensis from the Guanshan biota with chaetae preserved together with morphological details of encrusting biomineralised tubes. (a), (b) exceptionally preserved specimens of Neobolus wulongqingensis with chaetae preserved: (a) ELI GB-N 632-1. (b) 648-6-1-GLF. (c) ELI GB-N 561-2-1, close up of kleptoparsitic tube extending into the chaetal fringe of a Neobolus wulongqingensis individual. (d), (e) ELI GB-N 258-1-1. d, twisted dorsal and ventral valves with encrusting kleptoparasitic tubes. (e) enlarged view of boxed area in (d). (f) 258 -1-2 –GLF, Close up of biomineralised tubes showing clear surface annulations. (g), (h) 250 -1 -1-2- GLF. Detail and micro X-ray fluorescence elemental mapping of biomineralised tubes detached from Brachiopod valve. (g) Light photo. (h) Micro X-ray fluorescence elemental mapping of potassium. (i) Micro X-ray fluorescence elemental mapping of silicon. (j) Micro X-ray fluorescence elemental mapping of iron. (k) Close up of the three biomineralised tubes. (l) Close up of kleptoparasitic tubes still attached to Neobolus wulongqingensis. Zhang et al. (2020).

The preservation of marginal chaetae, mantle canals, visceral areas, and, rarely, the lophophore in the Brachiopods indicates rapid burial and minimal transport by episodic obrution deposits. Despite this, the soft body of the tube-dwelling Animal is not well-preserved, and its biological affinities are not self-evident. The greyish-white tubes, normally flattened by post depositional compaction, are immediately apparent. The tubes, some with preserved accretionary growth increments, encrust the exterior of both dorsal and ventral valves of Neobolus wulongqingensis with the open apertures exclusively oriented toward the anterior commissure of host Brachiopods, indicating an intimate, life-long, in-vivo association. The tubes exclusively encrust the exterior of the host shell, which occasionally shows signs of minor damage or disruption of shell growth lines, but there is no evidence of boring into the interior of the brachiopod by the tube-dwelling organism. The tubes are not found attached to any other hosts or substrates, such as the Trilobite or Palaeoscolecid exuviae that occasionally occur in the shell beds. Consequently, Zhang et al. interpret this interaction as representing an obligate relationship, as there is no evidence to suggest that the tube-dwelling organisms can adopt a free-living lifestyle in the absence of their Brachiopod host.

 

The basibiont Neobolid (Lingulata) Brachiopod Neobolus wulongqingensis from the Guanshan biota (Cambrian Stage 4) of eastern Yunnan. (a) Holotype, ELI GB-N-0377-1, a composite mould with dorsal and ventral valves strongly compressed. Note the fringe of chaetae and proximal pedicle. (b) ELI GB-N-0297-4, a 3- dimensional ventral valve with a preserved elongated pedicle attached to an exoskeleton of a Trilobite. (c) ELI GB-N-0625, compressed dorsal and ventral valves, showing the dorsal and ventral chaetae cross to form a fine sieve or mesh. (d), (e) ELI GB-N-0385: (d) View of dense anterior marginal chaetae; (e) Magnified view of boxed area in Fig. (d). (f), (h) ELI GB-N-SJJ-1308, shell interior, showing paired spiral lophophore: (f) light photograph; (g) enlarged view of boxed area in (f); (h) Micro X-ray fluorescence elemental mapping of aluminium, slilicon and iron shows paired spiral lophophore in high contrast. Zhang et al. (2020).

Bayesian estimation analysis (a widely used technique for estimating the probability density function of random variables with unknown parameters) demonstrates that a credible difference in biomass exists between Brachiopods with encrusting tubes (205 specimens) compared to those without (224 specimens). There is no overlap in the 95% highest density interval of the posterior distribution for the means of the two groups and the highest density interval for effect size does not overlap with zero. Mean biomass for individuals with encrusting tubes is thus credibly lower than for those without tubes. A null hypothesis significance testing approach also identified a significant difference between encrusted and non-encrusted individuals with a small effect size. Zhang et al. therefore contend that individual Brachiopods encrusted with tubes have reduced fitness when compared with their non-encrusted counterparts. On the basis of the difference in the values for mean biomass between the two groupings, encrustation results in a 26.08% reduction in overall fitness across the entire measured cohort.

 

Results of analyses demonstrating encrusted tubes were parasitic. (a) Posterior distribution of mean biomass derived from Bayesian estimation for Brachiopods without attached tubes (μ1; left) versus those brachiopods with encrusted tubes (μ2; right). Highest density interval denotes highest density interval and represents credible values for mean biomass for each grouping. (b) Posterior distribution of effect size for μ1 versus μ2 derived from Bayesian estimation. Highest density interval exceeds 0, indicating that a credible difference exists between the mean values for Brachiopods with encrusted tubes versus those Brachiopods without tubes. (c) Plot of Attachment Distance versus Biomass. Attachment distance from the posterior margin of Neobolus wulongqingensis represents a proxy for the duration of the symbiotic relationship between an individual Brachiopod and its associated encrusted tubes. Correlation between these two variables therefore indicates that those Brachiopods with enduring symbiotic relationships are reduced in biomass in comparison to those where time of attachment has been short. Zhang et al. (2020).

Although Zhang et al.'s analyses indicate that Brachiopods with encrusting tubes are reduced in biomass compared to those without, there is no clear relationship between the biomass of host individuals and increasing numbers of encrusted tubes per individual. In some symbiotic relationships, the impact on the host is amplified depending on the number of parasites present, but this relationship can be highly variable. For Zhang et al.'s dataset, the biomass of the Brachiopod host decreases when a single tube is encrusted to the shell surface, but no further decline is associated with an increasing number of tubes. Both proxies for increasing total parasite load also show no correlation with biomass. This suggests the tube-dwelling organism did not directly inhibit the feeding capability of the host, as larger numbers of parasites do not result in decreased fitness. However, a significant relationship exists between the attachment point of the encrusting tubes and the biomass of the brachiopod host, indicating encrustation earlier in ontogeny results in greater reduced biomass relative to hosts that have been infected at later ontogenetic stages, regardless of the number of symbionts present. In living Brachiopods, smaller individuals generally display an increased growth rate compared to larger individuals. It would therefore be expected that the impact on fitness would be greater for host individuals that are settled by parasites during earlier ontogenetic stages. The increase in median attachment distance for larger numbers of symbionts and the larger size of specimens with greater than four tubes establishes that higher infection rates can only occur when Brachiopod hosts have already managed to grow to larger adult sizes and there is sufficient Brachiopod shell surface area to accommodate a larger number of encrusting tubes.This also indicates that the tube-dwelling organisms do not preferentially encrust smaller Brachiopod individuals, as Brachiopods are clearly encrusted in large numbers later in their ontogeny, when they have reached larger sizes.

 

Supplementary plots exploring relationship between Brachiopod biomass and characteristics of attached tubes. (a) Box and whisker plot of number of attached tubes versus Brachiopod biomass. Whilst 1-3 attached tubes results in lower median biomass compared to individuals without tubes, individuals with 4+ tubes are indistinguishable from those with no attached tubes. (b) Plot of total tube width versus biomass. Total tube width for each individual is calculated as the sum total width of all tubes present on the relevant individual. (c) Plot of total tube area versus biomass. Total tube area for each individual is calculated as the sum total area of the shell surface covered by the attached tubes for the relevant individual. (d) Box and whisker plot of number of attached tubes versus attachment distance. Increasing the number of tubes per individual results in an increase in attachment distance. With attachment distance representing a proxy for time of attachment, this result suggests that large numbers of parasites are present for shorter durations and are only possible on larger, older shells. Number of biologically independent specimens used for each plot: (a) 429; (b) 408; (c) 383; (d) 167. Zhang et al. (2020).

Zhang et al.'s analyses demonstrate that the tube-dwelling organism directly impinges upon the biological fitness of the host, supporting the assertion that the encrusting tube-dwelling organisms are parasitic, rather than being either mutualistic or commensal with the Brachiopod host. A reduction in host biomass or growth rate has been directly attributed to the presence of a parasite in a variety of extant symbiotic relationships. Parasites typically increase the energetic requirements of infected organisms, as the host must generate sufficient energy to not only maintain its own requirements but also the needs of the parasite. This commonly leads to hosts with decreased biomass when compared with uninfected individuals. This result represents the first definitive and statistically supported instance of parasitism from the Cambrian and indicates that parasite–host systems were well established by Cambrian Stage 4, suggesting this type of interaction probably emerged even earlier during the main pulse of the Cambrian radiation.

Variations in biomass between individuals and assemblages of the same species have also been previously attributed to regional variation in environmental stressors. All specimens of Neobolus wulongqingensis included in this analysis occur in dense aggregations (estimated 60 000 individuals per m²) from the same geographic locality and stratigraphic package with similar sedimentological features subject to similar environmental and depositional conditions. Consequently, the reduced biomass of tube-encrusted Neobolus wulongqingensis individuals cannot be attributed to environmental factors and a parasitic affect is the most strongly supported probable cause.

 

Aggregations of Neobolus wulongqingensis with associated attached obligate kletoparasitic tube-dwelling organisms, showing the density of individuals per unit area. Each square equals 1 cm² and each black dot equals one individual Brachiopod. (a) ELI GB-N-N-0300. (b) ELI GB-N-N-0301. Zhang et al. (2020).

In all instances, the apertures of tubes are orientated toward the Brachiopod commissure, spanning an arc (plan view) of about 150°. No tubes have been observed orientated toward the hinge line of the Brachiopod. Tubes consistently grow beyond the commissural margin of Neobolus wulongqingensis into, and slightly above but rarely beyond, the Brachiopod chaetal fringe. Critically, the dominant growth direction of the tubes aligns tightly along a vector between 40° and 70° either side of the median plane of symmetry of the Brachiopod; this alignment is most pronounced in shells with a single encrusting tube but the same orientation pattern occurs in shells with all numbers of tubes, strongly supporting a preferential growth direction in the tubes toward the antero-lateral margin of the Brachiopod shell.

 

Evidence demonstrating the associated encrusted tube-dwelling organisms were kleptoparasitic. (a) Shell interior of specimen ELI GB-N-0595A of Neobolus wulongqingensis from Wuding showing the presence of a paired spirolophe lophophore (as indicated by white arrows). Scale bar is 1 mm. (b) Micro X-ray fluorescence elemental mapping of iron for ELI GB-N-SJJ-0595A provides a high contrast image of the spirolophe lophophore (as indicated by white arrows). (c), (d) Rose diagrams of attached tube orientation for: (c) All measured individuals of Neobolus wulongqingensis (146 specimens) and; (d) Neobolus wulongqingensis individuals with only one attached tube (31 specimens). Each division represents a 10° interval. Intervals coloured in orange are those that correspond to the inhalant laminar currents generated by Neobolus wulongqingensis. For all numbers of attached tubes, orientations that align with inhalant laminar currents are preferred but for individuals with only one attached tube, where the symbiont has all available orientations still available, orientations that align with the inhalant laminar currents are strongly preferred. Zhang et al. (2020).

Five specimens of Neobolus wulongqingensis from Wuding Quarry preserve a partial spirolophe lophophore. A spirolophe lophophore produces two separate inhalant laminar feeding currents at the antero-lateral edge of the shell margin that match the preferred orientation and growth position of the encrusting tubes on shells of Neobolus wulongqingensis. The preferred orientation of growth demonstrates that the tube-dwelling organisms were not purely utilising the Brachiopod as a hard substrate on which to construct their tubes. This data when combined with the demonstrated empirical cost to the host in the form of reduced biomass, strongly supports kleptoparasitic behavior. Kleptoparasitism is a form of competition, where food that is either already in the possession of the host or which the host has expended energy on obtaining and capture is imminent, is stolen by the parasite. In Zhang et al.'s scenario, this involves the tube-dwelling organisms acting as intercept feeders, stealing a portion of the Brachiopod feeding stream before it reached the chaetal fringe. Erika Iyengar recognised six distinct morphological, behavioral and physiological criteria that characterise living sedentary/sessile kleptoparasitic interactions in a 2002 study of such relationships. At least five of these criteria can be directly applied to the relationship between the encrusting tube-dwelling organism and Neobolus wulongqingensis further reinforcing a kleptoparasitic relationship.

 

Additional rose diagrams of attached tube orientation for all values of attached tubes. Each division represents a 10º interval. Intervals coloured in orange are those that correspond to the inhalant laminar currents generated by Neobolus wulongqingensis. The radii of each sector is equal to the square root of the relative frequencies of observations for each group. (a) Individuals with 2 attached tubes. (b) Individuals with 3 attached tubes. (c) Individuals with 4 attached tubes. (d) Individuals with 5 attached tubes. (e) Individuals with 6 attached tubes. (f) Individuals with 7+ attached tubes. Zhang et al. (2020).

Kleptoparasitism is rarely identified in the fossil record, and no instances of kleptoparasitism, as far as Zhang et al. are aware, have been proposed for Cambrian communities. Detailed empirical investigations of the energetic and nutritional cost of kleptoparasitism to the host, even for extant systems, are few. For this reason, it is currently difficult to assess if the reduction in host fitness (about 26%) Zhang et al. detect for Neobolus wulongqingensis is typical of sessile kleptoparasitic relationships. Brachiopods are particularly vulnerable to exploitation by kleptoparasites, since active filter feeding represents the greatest energy expenditure in the life of Brachiopods, and the time lag between collection and ingestion of nutritionally beneficial particles also provides potential for other organisms to exploit this resource. Combined with the fact that the biotic interaction  Zhang et al. document is interpreted as obligate for the parasite, this suggests that the effect observed is likely greater than would be the case in facultative kleptoparasitic associations. Intriguingly, obligate kleptoparasitism is exceedingly rare in modern marine systems, which might suggest that this novel ecological relationship is always rare in benthic communities or has been secondarily lost some time during the Phanerozoic.

 

Artist’s reconstruction of the Wulongqing Formation benthic community, showing the dense aggregations of monotypic Neobolus wulongqingensis forming benthic ‘meadows’ on the soft sediment with their associated obligate encrusting kleptoparasitic tube-dwelling organisms. Rebecca Gelernter/Near Bird Studios in Zhang et al. (2020).

Verification of this kleptoparasitic relationship reveals that the heritage of parasite–host interactions can be traced back more than half a billion years to the rise of Bilaterian Animal communities during the Cambrian and further establishes the importance of the early Cambrian as a primary source of ecological novelty. Antagonistic biotic interactions have also been proposed as the drivers of widespread evolutionary phenomena such as the maintenance of sexual reproduction and genetic polymorphism at disease loci. Both of these phenomena are known drivers of biodiversity increase, suggesting that the already established presence of parasitic relationships in Cambrian communities potentially had a fundamental role in the upsurge in evolutionary innovation associated with the Cambrian Radiation.

See also...

Online courses in Palaeontology. 

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