Late Ediacaran organic microfossils from Finland

Abstract Here we present a detailed accounting of organic microfossils from late Ediacaran sediments of Finland, from the island of Hailuoto (northwest Finnish coast), and the Saarijärvi meteorite impact structure (~170 km northeast of Hailuoto, mainland Finland). Fossils were recovered from fine-grained thermally immature mudstones and siltstones and are preserved in exquisite detail. The majority of recovered forms are sourced from filamentous prokaryotic and protistan-grade organisms forming interwoven microbial mats. Flattened Nostoc-ball-like masses of bundled Siphonophycus filaments are abundant, alongside Rugosoopsis and Palaeolyngbya of probable cyanobacterial origin. Acritarchs include Chuaria, Leiosphaeridia, Symplassosphaeridium and Synsphaeridium. Significantly, rare spine-shaped sclerites of bilaterian origin were recovered, providing new evidence for a nascent bilaterian fauna in the terminal Ediacaran. These findings offer a direct body-fossil insight into Ediacaran mat-forming microbial communities, and demonstrate that alongside trace fossils, detection of a bilaterian fauna prior to the Cambrian might also be sought among the emerging record of small carbonaceous fossils (SCFs).


Introduction
The latest part of the Ediacaran System harbours signatures for some of the most important changes in the history of the biosphere. Multiple lines of fossil evidence indicate that many of the foundations of animal-dominated Phanerozoic-style ecosystems were assembled at this time, and include structurally complex Ediacaran macrofossils (e.g. Ivantsov et al. 2019a), animal-derived biomarkers (Bobrovskiy et al. 2018a), possible metazoan reefs (Grotzinger et al. 2005;Penny et al. 2014) and the advent of macroscopic biomineralization (e.g. Cloudina (Grant, 1990)). Perhaps most significantly, a trace fossil record of complex horizontal burrows and trails appears from~560 Ma, likely documenting the emergence of a bilaterian benthos (Martin et al. 2000;Jensen, 2003;Chen et al. 2013Chen et al. , 2019Budd, 2015;Budd & Jensen, 2017). These simple trace fossils are consistently found in association with bedding planes exhibiting microbial mat textures, and have been interpreted as representing a variety of mat-exploiting behaviours (Buatois et al. 2014;Meyer et al. 2014;Tarhan et al. 2017;Ivantsov et al. 2019b). Together, these lines of evidence point to a characteristic Ediacaran matground ecology which appears to have persisted into the early Cambrian Fortunian (Buatois et al. 2014;Laing et al. 2019). Despite the importance of these environments as cradles of early animal evolution (Budd & Jensen, 2017), there is currently little direct accounting of body fossils either from the biomat-forming organisms, or from the nascent bilaterian fauna themselves.
Organic walled microfossils (OWMs) are one source of direct body-fossil data that can be retrieved from siliciclastic rocks. Most studies of OWMs from the Ediacaran to date have focused on acritarchs (e.g. Moczydłowska, 2005;Willman et al. 2006). In studies of comparable OWM-bearing deposits from the Cambrian, there has recently been an increased awareness that a larger size class of organically preserved remains is accessible if a gentler processing procedure is applied. These larger, more delicate forms have been dubbed small carbonaceous fossils (SCFs), and encompass a polyphyletic mix of organic remains sourced from various organisms, including the fragmentary remains of metazoans (Butterfield & Harvey, 2012). Recently, several SCF biotas have been recovered from early Cambrian sediments in the Baltic region (Slater et al. 2017;Guilbaud et al. 2018;Kesidis et al. 2019;Slater & Willman, 2019), including from earliest Cambrian strata (Slater et al. 2018a). Extending this record into the Ediacaran is crucial for capturing SCF diversity contemporaneous with the earliest stages of bilaterian evolution.
Finland is one region of Baltica that has been relatively under-explored in terms of its Ediacaran fossil record. Nevertheless, several localities preserving sediments of Ediacaran age are found in Finland, and crucially the thermal immaturity of these sediments makes them ideally suited for SCF preservation (Slater & Willman, 2019). Here we report a rich record of organic microfossils from a late Ediacaran sequence in Finland, from Hailuoto Island and the Saarijärvi meteorite impact crater (Fig. 1).

Geological setting
An extended episode of erosion during the early-to mid-Neoproterozoic era left Baltica as a peneplained continent of exceptionally low relief (Lidmar-Bergström, 1993, 1995. Subsequent transgressions during the late Neoproterozoic and early Phanerozoic flooded large regions of this topographically flat landscape, resulting in extensive shallow marine deposition (Nielsen & Schovsbo, 2011). Siliciclastic sediments deposited in these epeiric seaways extend over large regions of the Bothnian Sea and the Baltic states. Based on the thickening trend of these sediments toward the Finnish coastline, equivalent deposits are thought to have once covered much of Finland (Puura et al. 1996;Kohonen & Rämö, 2005;Bogdanova et al. 2008;Klein et al. 2015;Slater & Willman, 2019). In Finland, even more than elsewhere in Baltica, the vast majority of these sediments have subsequently been eroded and now remain only as relatively small and geographically scattered outliers.
One region where a substantial portion of late Neoproterozoic sediments has survived in Finland is the island of Hailuoto (Fig. 1). Hailuoto is situated in the Bothnian Bay off the northwest coast of the Finnish mainland, west of the coastal city of Oulu (Fig. 1). Beneath a covering of Quaternary sediments lies the subsurface Hailuoto Formation (known entirely from drillcore), a package of sandstones, mudstones, siltstones, clays and conglomerates which varies in thickness across the island, reaching a maximum thickness of~560 m (Solismaa, 2008;Klein et al. 2015). The upper 55-65 m of the formation consists of greenish-grey fine-grained sandstones, shales and siltstones. Below this are deposited redcoloured arkosic sandstones and shales, which rest unconformably on the crystalline basement or on sediments of the Mesoproterozoic-Neoproterozoic Muhos Formation which underlies much of the Bothnian Bay and outcrops adjacent to Hailuoto on the Finnish mainland (Fig. 1). The Muhos Formation consists of red-green-grey siltstones and shales (Kohonen & Rämö, 2005), similar in lithology to the Hailuoto Formation (Tynni & Siivola, 1966;Tynni & Donner, 1980;Kohonen & Rämö, 2005;Solismaa, 2008;Klein et al. 2015).
Based on correlation with adjacent strata and its microfossil contents, the Hailuoto Formation is considered to be late Neoproterozoic in age, with estimates in the range of 600-570 Ma (Veltheim, 1969;Tynni & Donner, 1980;Paulamäki & Kuivamäki, 2006;Klein et al. 2015;Luukas et al. 2017). This would place the deposition of the Hailuoto Formation in approximately the middle of the Ediacaran Period. A microfossil analysis of sediments from the upper parts of the Hailuoto Formation by Tynni & Donner (1980) drew comparisons with the uppermost parts of the Visingsö Formation of Sweden. Detrital zircon U-Pb ages have subsequently constrained the Visingsö Formation to a maximum depositional age of ≤886 ± 9 Ma (Moczydłowska et al. 2017), and recent microfossil studies also suggest this formation was deposited during the Tonian (Loron & Moczydłowska, 2018). Klein et al. (2015), however, point out that many of the form-taxa reported from the Hailuoto Formation by Tynni & Donner (1980) are actually found in much younger sediments elsewhere in the Baltic region and East European Platform, for example, in late Ediacaran strata from the Kotlin Formation of Estonia (Mens & Pirrus, 1997;Meidla, 2017;Arvestål & Willman, 2020;Slater et al. 2020). A particularly close comparison can also be drawn with OWM assemblages from the late Ediacaran Redkino and Kotlin regional stages of the Lyamtsa, Verkhovka, Zimnie Gory and Yorga formations of the White Sea region in Russia (e.g. Leonov & Ragozina, 2007). These similarities to assemblages from comparatively well-constrained late Ediacaran strata (e.g. in the White Sea region) would suggest a substantially younger age for the Hailuoto Formation than suggested in previous studies, closer to the Ediacaran-Cambrian boundary. Indeed, U-Pb zircon dating of volcanic tuffs has indicated an age of 551-548 Ma for the lowermost Kotlin in the White Sea area of northern Russia (Grazhdankin et al. 2011). With this advancement in understanding of the local and regional stratigraphy we favour a younger, latest Ediacaran age for the upper part of the Hailuoto Formation here.
Another subsurface remnant of comparable Neoproterozoic sediments is preserved within the Saarijärvi impact structure in central Finland (Fig. 1). The Saarijärvi impact crater is situated 30 km south of Taivalkoski near the border between the Finnish regions of northern Ostrobothnia and Kainuu, and is largely covered by a lake (Saarijärvi) that has formed in the crater depression (to avoid confusion, it is worth noting that in Finnish 'Saarijärvi' is a very common lake namethere are at least 198

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S Willman and BJ Slater lakes named Saarijärvi in Finland). The local geology has largely been reconstructed based on drillcore material. As with many impact structures, the precise geological history has been problematic to disentangle. Up to 156 m thickness of sediments is preserved within the~1.5 km diameter crater. These packages of sediment are difficult to correlate even between closely spaced cores, likely as a result of separate cores intersecting different coherent megablocks of sediment arranged in a chaotic way (Hyyppä & Pekkala, 1987;Öhman & Preeden, 2013). The signatures of impact-disruption are evident throughout the cores: Sediments display significant changes in dip direction and angle over relatively short intervals of core depth. Further, fractured angular clasts of basement rock (granite) are found within the sediments at several depths in different cores. Another notable feature is that even among soft lithologies the core material tends to break along shiny, polished surfaces which cut across the bedding; such features may represent subsequent fracturing of the sediments related to tectonism (Öhman & Preeden, 2013). Precise dating of the impact event has been difficult, and there are competing scenarios between a Proterozoic and an early Cambrian age impact hypothesis (see Öhman & Preeden, 2013). Shales and siltstones in the upper parts of the Saarijärvi impact structure are reminiscent of those in the Hailuoto Formation, and have produced comparable OWM assemblages both in terms of taxonomic composition and preservation (Tynni & Donner, 1980;Tynni & Uutela, 1984, 1985Paulamäki & Kuivamäki, 2006), suggesting that sediments of the Hailuoto Formation originally extended north and east to cover a substantial portion of central Finland.

Materials and methods
Sampling targeted three cores intersecting the Neoproterozoic sediments of Hailuoto  . These samples were also selected from green-grey mudrocks, which at Saarijärvi are distributed chaotically even among closely spaced cores, due to the displacement of megablocks associated with crater formation (see Öhman & Preeden, 2013). Processing followed the techniques outlined in Butterfield & Harvey (2012). Cores are housed at the Geological Survey of Finland national drillcore archive in Loppi. All imaged fossil material is deposited in the Palaeontological collections of the Museum of Evolution (PMU), Uppsala University, Sweden.

Organic-walled fossils
Of the 64 processed samples, all were productive for microfossils, although with significant variation in contents and abundance. A particularly productive section was identified in mudstones of the M52-Hail-04-004 drillcore, spanning~71-73 m depth. The majority of recovered fossils fall into the broad form-taxonomic distinctions of acritarchs (vesicular organic-walled microfossils of unknown biological affinity; Evitt, 1963) or filamentous forms. Specimens of metazoan origin were also recovered from Hailuoto. Assemblages from Hailuoto and Saarijärvi contained the same acritarchs and filamentous form taxa, supporting previous hypotheses that these strata are remnants of once widespread late Ediacaran deposits in Finland (Tynni & Donner, 1980;Tynni & Uutela, 1985;Paulamäki & Kuivamäki 2006).

4.a. Metazoan remains
An individual triangular structure of~800 μm length and~450 μm width at the base was recovered from a particularly fossil-rich sample at 72.7 m depth in the M52-Hail-04-004 drillcore. This spine-shaped fossil possesses a thin-walled flared basal region exhibiting rhombus-shaped surficial scaly ornamentation, which tapers to a darkened, presumably sclerotized tip (Fig. 3a). The same sample also produced a broadly blade-shaped sclerotized element edged with crenate serrations that are densely encrusted with pyrite euhedra (Fig. 3b). Close comparisons can be drawn between the spine-shaped element (Fig. 3a)  This spine is perhaps the most unexpected find from the Hailuoto assemblage, and appears to derive from a metazoan. Several Ediacaran metazoans (e.g. Dickinsonia, Yorgia and Kimberella) are known to have produced dorsal integumentary shields that were covered with various tubercles and spines (see Ivantsov et al. 2019a, figs 2, 3). The fine-scale structures of these integuments are unclear however, since they are known solely from preservation as casts and moulds. Cnidarians can possess a chitinous exoskeleton (Mendoza-Becerril et al. 2016), which conceivably could produce sclerite-like elements preservable as carbonaceous fossil remains. Fossil examples of early cnidarians with a chitinous exoskeleton include early Cambrian (Fortunian) coronate scyphozoans such as Olivooides (Dong et al. 2013), Quadrapyrgites (Y  and Qinscyphus (Liu et al. 2017), as well as possible Ediacaran cnidarians such as the tubular Corumbella (Warren et al. 2012). None of these, nor any other cnidarians we are aware of, produce spine-like sclerites, however, and we deem it likely the sclerite from Hailuoto is sourced from a bilaterian-grade animal. Among the bilateria, protoconodonts and scalidophorans both have fossil records extending to almost the base of the Cambrian (Kouchinsky et al. 2012;Slater et al. 2018a). Some of the earliest Cambrian, and even latest Ediacaran, burrows may have been produced by scalidophoran or cycloneuralian worms (see Kesidis et al. 2019). Based on the simple set of characters, however, this spine cannot confidently be attributed to either a protoconodont, or a cuticular sclerite of a scalidophoran worm. Indeed, spines of this type could conceivably be sourced from a much broader array of bilaterians, including various ecdysozoans, gastrotrichs (Rieger & Rieger, 1977), gnathiferans (Marlétaz et al. 2019), as well as stem-protostomes or even stem-bilaterians.

4.b. Filamentous microfossils
Both the Hailuoto and Saarijärvi material produced a rich assortment of microfossils with a broadly filamentous construction, some of which may represent different life-cycle stages, or taphomorphs of the same organism. Structures such as simple multicellular filaments or coccoid cells have been repeatedly convergent in some clades over geological time (e.g. cyanobacteria: Dvořák et al. 2014;Butterfield, 2015b), meaning that assigning these fossils to a specific group is fraught with difficulty. To circumvent some of this phylogenetic ambiguity, we discuss these forms in terms of distinctive morphogroups and, where possible, use established form-taxonomic terminology, whilst drawing comparisons to useful fossil and extant analogues.

4.b.1. Siphonophycus 'donuts'
A ubiquitous constituent of fossiliferous samples is bundled filaments of the form-taxon Siphonophycus (Fig. 4). Siphonophycus are smooth-walled, unbranched, tubular filaments that lack septa or preserved cellular remains (Knoll et al. 1991). The Siphonophycus filaments from Finland are a few microns in thickness, and are often found bundled up into tight rings varying in size between 50 and 650 μm in maximum diameter, often with a central hollow (ranging between absent and up to~300 μm diameter). These structures likely represent flattened Nostoc-ball-like masses of interwoven filaments (see Butterfield et al. 1994;Mollenhauer et al. 1999;Guiry & Guiry, 2008). The 'donut-shaped' (Fig. 4ak, n, p, q) and more irregular agglomerations (Fig. 4l, m, o, s) possibly formed via the collapse of originally torus-shaped colonies, or alternatively the central hollow may represent the void left by a mucilage-filled interior space within an originally spherical colony. Though lacking an overall ring shape, bundled filaments described as Polytrichoides lineatus Hermann 1974 emend. (Hermann in Timofeev et al. 1976) exhibit similarities to the

4.b.2. Palaeolyngbya
The majority of samples produced smooth, strap-shaped filamentous sheaths, ranging between~50 and 110 μm in diameter, and of various lengths up to~3 mm (Fig. 5). In a subset of these filaments, the outer envelopes enclose optically darker, unbranched, uniseriate, multicellular trichomes, composed of shrunken and degraded cells ( Fig. 5m-p, x, ac, an). The trichome is c. 30-40 % of the outer envelope diameter in most specimens, though this may represent taphonomic shrinkage since a few specimens preserve much broader trichomes (e.g. Fig. 5x). The internal trichome may run the entire filament length (e.g. Fig. 5o); however, in some specimens it is fragmented or incomplete (e.g. Fig. 5p). The cells of the trichome are occasionally separated and displaced obliquely within the sheath, appearing as a series of discoidal cells (e.g. . These filaments are distinguishable from other fossil multicellular trichomes such as Oscillatoriopsis from the manner in which specimens break (across pseudosepta vs between true cells in Oscillatoriopsis). Occasional specimens display a pseudoseptate sheath comparable to some Tortunema (e.g. fig. 7.5 of Sergeev et al. 2016), likely reflecting taphomorphic and/or ontogenetic variation.

4.b.3. Rugosoopsis
Another common filament type found in most samples from Hailuoto and Saarijärvi consists of a bi-layered form with a dense, smooth-walled inner sheath (similar to Siphonophycus or Palaeolyngbya), enclosed by a thinner-walled outer sheath with a pronounced series of transverse ridges (or rugose ornamentation) on the surface (Figs 5a-l, r-w, y-ab, af-am, 6d). The broader outer sheath is often damaged or torn, but where intact it appears as a faint outline extending beyond the margins of the inner sheath ( Fig. v, y, z). Occasional atrophied cells (probable necridia) are visible within the inner sheath (e.g. Fig. 5i). These filaments are assignable to the form-taxon Rugosoopsis Timofeev and Hermann 1979, which has been recovered from Proterozoic shales (Pjatiletov, 1988;Jankauskas et al. 1989 Butterfield, 2001). In both the Hailuoto and Saarijärvi samples, these Rugosoopsis filaments co-occur with and may grade into other filament types, including Palaeolyngbya, Siphonophycus and occasional pseudoseptate Tortunema-like sheaths (Fig. 4q, ad, ae), underscoring the substantial taphomorphic and ontogenetic overlap among filamentous microfossils.

4.b.5. Matted filaments
The majority of samples produced abundant entangled mats of Siphonophycus, Palaeolyngbya and Rugosoopsis exhibiting a mesh-like growth habit (Figs 6, 7), where filaments are densely interwoven (Figs 6a-d, 7a). Frequently the density of overlapping filaments is such that they form a sheet-like layer that has been

S Willman and BJ Slater
compressed into a single carbonaceous film (see Martí Mus, 2014;Slater et al. 2020). Some of these mats are of mixed composition (e.g. Fig. 6a); however, others are composed entirely from a single filament morphology (e.g. Figs 6c,d,7a). In this latter category, the filaments are all of similar dimensions, suggesting that they are at the same ontogenetic stage (e.g. Fig. 7a). Within these mats, individual filamentous structures may be encrusted with pyrite euhedra (Figs 6a,b,7c,e). Pyrite also occurs as circular or more irregular patches within the sheet, possibly representing voids within the mat created by gas bubbles. Together, these agglomerations are reminiscent of various acid-isolated mat-forming filaments from Proterozoic shales (compare Fig. 6c with fig. 8.

4.c. Acritarchs
The majority of samples from both Hailuoto and Saarijärvi produced irregular, aggregate clusters of spheroids (Fig. 9m, n). Comparable sheet-forming clusters of spheroids are frequently assigned to the form-taxon Ostiana (e.g. fig. 5J of Samuelsson & Butterfield, 2001); however, the more irregular aggregates recovered here are more appropriately assigned to the form-taxon Synsphaeridium Eisenack 1965 (Fig. 9m, n; cf. fig. 13 of . The individual spheroids range between 15 and 25 μm in diameter, and form clusters up to~350 μm in maximum dimension, consisting of up to~100 individual spheroids. More tightly bound and regular-shaped clusters of spheroids (e.g. Fig. 9j-l), where the vesicles are often deformed by compression, are assigned to Symplassosphaeridium Timofeev 1959, ;1966(cf. fig. 18.6 of Hofmann & Jackson, 1994. Occasionally, similar forms have been ascribed to Squamosphaera colonialica Jankauskas 1979, but Squamosphaera do not possess true vesicles, displaying only hemispherical protrusions from the vesicle wall (see fig. 17 of . Larger cell-aggregates with denser walls were found in most samples, but were particularly abundant in samples from Hailuoto ( Fig. 9e-h). Fragmentary forms of identical morphology to these acritarchs were described by Tynni & Donner (1980) from the same sediments on Hailuoto, which they ascribed to the extant prasinophycean alga genera Cymatiosphaera as a new species, Cymatiosphaera precambrica (a holotype was not formally designated in that paper, but was rectified in Tynni & Donner, 1982). Tynni & Donner (1980) extrapolated the size of the fragmentary remains to be derived from a spherical body c. 250 μm in diameter when complete; this falls towards the lower end of the size range of forms recovered in this study (~300-700 μm), perhaps reflecting the differing processing techniques. Assignment of fossil material to the extant genus Cymatiosphaera is not unknown (e.g. Cymatiosphaera are reported from the Early Devonian Rhynie Chert; Dotzler et al. 2007). However, the surface sculpture of specimens recovered by Tynni & Donner (1980) was originally interpreted as reticulate, as in extant Cymatiosphaera. Our recovery of intact specimens here nevertheless demonstrates that the apparently polygonal surface texture actually results from the intersection of compacted adjacent spheroids, which clearly protrude at the flattened cluster margins (Fig. 9e-h). In light of this, these densely clustered cell aggregates are instead more appropriately compared to cell colonies found within organic cysts such as those reported in some Chuaria (see fig. 3 of Tang et al. 2017).
Acritarchs assigned to Chuaria were found to co-occur with these large cell-aggregate forms ( Fig. 9a-b). Feasibly, the large cell aggregates represent the vegetative stage of co-occurring empty Chuaria cysts. Tang et al. (2017) suggest that although these cell aggregates could be described under a distinct form-taxonomic name, they likely represent different life-cycle stages of the same biological species, and therefore it may be suitable to expand the form taxonomy of Chuaria to encompass these aggregate forms (see also Chuaria as a subcomponent of a macroalgae, fig. 16 of Kumar, 2001; fig. 7 of Wang et al. 2017). Less optically dense forms could potentially fall under the definition of Leiosphaeridia jacutica (see Javaux & Knoll, 2017). Other hollow cyst-like acritarchs recovered include relatively large smooth-walled Leiosphaeridia (Fig. 9c) with prominent compaction folds encrusted in pyrite (compare with fig. 1 of .

5.a. Palaeoenvironment of Hailuoto/Saarijärvi OWM assemblage
As with most assemblages of acid-extracted organic-walled fossils, the Hailuoto and Saarijärvi material likely represents a combination of both benthic and planktonic organisms. Smaller vesicular acritarchs may be sourced from the water column, whereas the majority of the filamentous taxa appear to be benthic, based on their mat-forming interwoven habit. Indeed, OWM assemblages from mid-to late-Proterozoic siliciclastic sediments record a prevalence of mat-forming filaments in shallow-water assemblages, probably reflecting photic-zone colonization by cyanobacterial mats (Butterfield & Rainbird, 1998;figs 6, 7 of Butterfield & Chandler, 1992;Butterfield, 2015b). Filamentous bacterial mats can nevertheless form at a wide range of depths on modern seafloors; whilst shallow-water mats tend to be principally composed of cyanobacteria, deeper water mats are frequently dominated by filamentous sulphur-oxidizing bacteria (Williams & Reimers, 1983;Jannasch et al. 1989;Bernard & Fenchel, 1995). Despite the inherent difficulties of determining the phylogenetic affinities of simple fossil filaments, there is a case for viewing the filamentous mats at Hailuoto and Saarijärvi as largely cyanobacterial; matted sheaths of Palaeolyngbya and Rugosoopsis share a number of   features with the extant cyanobacteria Oscillatoria, Calothrix and Lyngbya; for example, lengths of Rugosoopsis are divided into a trichome and tend to break around shrivelled portions which potentially represent necridiafeatures associated with oscillatoriacean cyanobacteria (Lamont, 1969;Speziale & Dyck, 1992;Butterfield et al. 1994;Samuelsson & Butterfield, 2001). The cells of the trichome in Palaeolyngbya also occur as a series of stacked discs, and exhibit features resembling hormocyte cells (compare Fig. 5ac with fig. 2D of Curren & Leong, 2018) as in extant Oscillatoria and Lyngbya (Shukovsky & Halfen, 1976;Horodyski, 1977;Nagarkar, 2002;Rani et al. 2016). Cyanobacterial mats would support a shallow-water depositional environment for the sequences at Hailuoto/ Saarijärvi (Tynni & Donner, 1980;Kohonen & Rämö, 2005), although even within the photic zone such mats are likely to include a variety of other microbes (Grazhdankin & Gerdes, 2007;Davies et al. 2016

5.b. Ediacaran microbial mats and bilaterians
Trace fossil assemblages in terminal Ediacaran (c. 555-541 Ma) sediments (globally) contain burrows that appear to have been produced by animals with a coelom/hydrostatic internal cavity and an anterior concentration of sensory systems (Budd & Jensen, 2000), meaning that at least stem-grade bilaterians were present in benthic communities by this time (e.g. Jensen et al. 2000Jensen et al. , 2006Jensen, 2003;Narbonne, 2005;Chen et al. 2013;Schiffbauer et al. 2016;Herringshaw et al. 2017;Laing et al. 2019;Davies et al. 2020). The cuticular fragments recovered at Hailuoto (Fig. 3) demonstrate that body-fossil remains of such bilateriangrade animals are preserved not only in the Phanerozoic but also in the Ediacaran SCF record. This raises the significance of these otherwise predominantly prokaryotic microbial mat-type fossil assemblages; given the central importance of bilaterians in shaping the nature of the Phanerozoic biosphere, the environment(s) and ecological backdrop of early bilaterian evolution are of intense palaeobiological interest (Budd & Jensen, 2017). A variety of macroscopic surface textures on Ediacaran bedding planes have been attributed to microbial mats, often termed microbially induced sedimentary structures or 'MISS' (see a review of such structures in Davies et al. 2016). Microbial mats have also been widely invoked in the preservation of Ediacaran mouldic macrofossils (e.g. Gehling, 1999;Gehling & Droser, 2009; but see Bobrovskiy et al. 2019 for an alternative view). In the latter part of the Ediacaran, bedding planes exhibiting MISS are frequently associated with simple horizontal burrows (e.g. Chen et al. 2013). This association has led to the hypothesis that Ediacaran bilaterians exploited such matgrounds as sources of nutrient concentration (Stanley, 1973;Seilacher 1999;Jensen et al. 2005;Seilacher et al. 2005;Buatois et al. 2011;Gingras et al. 2011;Meyer et al. 2014;Evans et al. 2019;Ivantsov et al. 2019b), or as oxygen-rich microenvironments if photosynthetic (Canfield & Des Marais, 1993;McIlroy & Logan 1999;Gingras et al. 2011;Ding et al. 2019). Current accounts of Ediacaran matground habitats are almost entirely based on records from MISS, castand-mould fossils and trace fossils. Steiner & Reitner (2001) reported carbonaceous compressions of macroscopic Ediacaran taxa from the White Sea region; associated with these fossils were bedding-plane visible 'elephant skin' and wrinkle structures attributed to microbial mat imparted textures. Acid treatment was shown to produce Siphonophycus and other filamentous sheaths comparable to those recovered from Hailuoto and Saarijärvi (compare Figs 6-7 with fig. 6 of Steiner & Reitner, 2001), including pyritized sheaths similar to those reported here (see fig. 7 of Steiner & Reitner, 2001). Our data from the late Ediacaran of Finland demonstrate that such preservation is widespread, even in the absence of carbonaceous macrofossil preservation. In this light, SCF-style processing and investigation of late Ediacaran sediments can be viewed as a largely untapped taphonomic window, offering new insights into the critical change from matground to mixground seafloor environments as the Proterozoic gave way to the Phanerozoic.

Conclusions
Late Ediacaran sedimentary rocks from subsurface deposits in central Finland contain well-preserved carbonaceous microfossils, including an abundance of filamentous prokaryotes (probable cyanobacteria), a variety of acritarchs, and significantly, fragments of metazoan cuticle derived from bilaterians. Based on the composition of the recovered fossil assemblage, we revise previous interpretations of an early-to mid-Ediacaran age to a late Ediacaran age for the upper part of the Hailuoto Formation.