Kimberichnus

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Kimberichnus
Temporal range: Same time range as its maker, 558–555  Ma
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Kimberella trace.jpg
Trace fossil classification Red Pencil Icon.png
Ichnogenus: Kimberichnus
Ivantsov, 2013
Type ichnospecies
Kimberichnus terruzi

Kimberichnus is an ichnofossil associated with the early bilaterian Kimberella . [1] [2] It is known mostly from shallow marine Ediacaran sediments, often occurring alongside its producer. [3] Kimberichnus often occurs in Russia and South Australia, where it is most abundant in the shape of multiple arcuate sets of ridges with fan-shaped arrangements. [2] [4]

Contents

Description

Artists interpretation of Kimberella and Kimberichnus. The multiple rows of proposed teeth that scratched the mat underneath the organism can be seen at the top of the image. Kimberella quadrata 001B.jpg
Artists interpretation of Kimberella and Kimberichnus. The multiple rows of proposed teeth that scratched the mat underneath the organism can be seen at the top of the image.

Kimberichnus traces often occur alongside the death masks of Kimberella ; the traces represent possibly the oldest known evidence of trace fossils that are associated with a bilaterian maker. [4] [5] The traces occur in the Ediacaran sediments of the Russian White Sea and in South Australia, Kimberichnus was described from Russia. [2] They most often occur as simple arcuate ridges arranged in sets, with an arrangement similar to that of fans; it is thought that these traces came from Kimberella rasping the microbial mat underneath it with its teethed Proboscis [3]

The feeding patterns that are seen in these traces exclude any Arthropodal origin, they instead point to a creator that was most likely systematically excavating nutrients/food off of the microbial mats. [4] Even though organisms at the time would move over the traces and slightly disturb them, it would not disturb them to the point that they will get deformed; this is because of the multiple layers of Microbes that made up the mats . The occurrence of both the traces maker and the trace itself in the Ediacaran period supports claims that bilaterians were already globally distributed and were able to make traces of grazing. [4]

Theoretical importance

A sudden event around starting around 543  million years ago had a huge influx of animal diversity in body plans that was named the Cambrian explosion. The rapid event finished before 518  million years ago. [6] Some mid-19th century scientists already knew about some Early Cambrian fossils, Charles Darwin noticed this sudden diversification of body plans and proposed that it could be a counter-argument against his theory of evolution. [7]

Kimberichnus seems to indicate an important step in this revolution of animals. Kimberella apparently grazed on the mats underneath its proboscis, and would often leave the Kimberichnus trace; it is also sometimes similar to Radulichnus from other Geological periods. [8] It seems that, because Kimberichnus is the trace produced by a Radula or teeth, Kimberella may have been an early (or relative of) Mollusc. [8] It is important to note that Radulae very rarely get preserved.

See also

Related Research Articles

The cloudinids, an early metazoan family containing the genera Acuticocloudina, Cloudina and Conotubus, lived in the late Ediacaran period about 550 million years ago. and became extinct at the base of the Cambrian. They formed millimetre-scale conical fossils consisting of calcareous cones nested within one another; the appearance of the organism itself remains unknown. The name Cloudina honors the 20th-century geologist and paleontologist Preston Cloud.

<span class="mw-page-title-main">Exoskeleton</span> External skeleton of an organism

An exoskeleton is an external skeleton that supports and protects an animal's body, in contrast to an internal skeleton (endoskeleton) in for example, a human. Some large exoskeletons are known as "shells". Examples of exoskeletons within animals include the arthropod exoskeleton shared by chelicerates, myriapods, crustaceans, and insects, as well as the shell of certain sponges and the mollusc shell shared by snails, clams, tusk shells, chitons, and nautilus. Some animals, such as the turtle, have both an endoskeleton and an exoskeleton.

<i>Dickinsonia</i> Extinct genus of early animals

Dickinsonia is an extinct genus of basal animal that lived during the late Ediacaran period in what is now Australia, China, Russia and Ukraine. The individual Dickinsonia typically resembles a bilaterally symmetrical ribbed oval. Its affinities are presently unknown; its mode of growth is consistent with a stem-group bilaterian affinity, though some have suggested that it belongs to the fungi, or even an "extinct kingdom". The discovery of cholesterol molecules in fossils of Dickinsonia lends support to the idea that Dickinsonia was an animal.

<span class="mw-page-title-main">Trace fossil</span> Geological record of biological activity

A trace fossil, also known as an ichnofossil, is a fossil record of biological activity but not the preserved remains of the plant or animal itself. Trace fossils contrast with body fossils, which are the fossilized remains of parts of organisms' bodies, usually altered by later chemical activity or mineralization. The study of such trace fossils is ichnology and is the work of ichnologists.

<i>Kimberella</i> Primitive Mollusc-like organism

Kimberella is an extinct genus of bilaterian known only from rocks of the Ediacaran period. The slug-like organism fed by scratching the microbial surface on which it dwelt in a manner similar to the gastropods, although its affinity with this group is contentious.

<span class="mw-page-title-main">Evolution of molluscs</span> The origin and diversification of molluscs through geologic time

The evolution of the molluscs is the way in which the Mollusca, one of the largest groups of invertebrate animals, evolved. This phylum includes gastropods, bivalves, scaphopods, cephalopods, and several other groups. The fossil record of mollusks is relatively complete, and they are well represented in most fossil-bearing marine strata. Very early organisms which have dubiously been compared to molluscs include Kimberella and Odontogriphus.

<i>Odontogriphus</i> Genus of soft-bodied animals from middle Cambrian

Odontogriphus is a genus of soft-bodied animals known from middle Cambrian Lagerstätte. Reaching as much as 12.5 centimetres (4.9 in) in length, Odontogriphus is a flat, oval bilaterian which apparently had a single muscular foot and a "shell" on its back that was moderately rigid but of a material unsuited to fossilization.

<span class="mw-page-title-main">Ediacaran biota</span> All organisms of the Ediacaran Period (c. 635–538.8 million years ago)

The Ediacaranbiota is a taxonomic period classification that consists of all life forms that were present on Earth during the Ediacaran Period. These were enigmatic tubular and frond-shaped, mostly sessile, organisms. Trace fossils of these organisms have been found worldwide, and represent the earliest known complex multicellular organisms. The term "Ediacara biota" has received criticism from some scientists due to its alleged inconsistency, arbitrary exclusion of certain fossils, and inability to be precisely defined.

<span class="mw-page-title-main">Marine invertebrates</span> Marine animals without a vertebrate column

Marine invertebrates are the invertebrates that live in marine habitats. Invertebrate is a blanket term that includes all animals apart from the vertebrate members of the chordate phylum. Invertebrates lack a vertebral column, and some have evolved a shell or a hard exoskeleton. As on land and in the air, marine invertebrates have a large variety of body plans, and have been categorised into over 30 phyla. They make up most of the macroscopic life in the oceans.

<span class="mw-page-title-main">Cambrian substrate revolution</span> Diversification of animal burrowing

The "Cambrian substrate revolution" or "Agronomic revolution", evidenced in trace fossils, is a sudden diversification of animal burrowing during the early Cambrian period.

The end-Ediacaran extinction is a mass extinction believed to have occurred near the end of the Ediacaran period, the final period of the Proterozoic eon. Evidence suggesting that such a mass extinction occurred includes a massive reduction in diversity of acritarchs, the sudden disappearance of the Ediacara biota and calcifying organisms, and the time gap before Cambrian organisms "replaced" them. Some lines of evidence suggests that there may have been two distinct pulses of the extinction event, one occurring 550 million years ago and the other 539 million years ago.

<span class="mw-page-title-main">Microbial mat</span> Multi-layered sheet of microorganisms

A microbial mat is a multi-layered sheet of microorganisms, mainly bacteria and archaea, or bacteria alone. Microbial mats grow at interfaces between different types of material, mostly on submerged or moist surfaces, but a few survive in deserts. A few are found as endosymbionts of animals.

The small shelly fauna, small shelly fossils (SSF), or early skeletal fossils (ESF) are mineralized fossils, many only a few millimetres long, with a nearly continuous record from the latest stages of the Ediacaran to the end of the Early Cambrian Period. They are very diverse, and there is no formal definition of "small shelly fauna" or "small shelly fossils". Almost all are from earlier rocks than more familiar fossils such as trilobites. Since most SSFs were preserved by being covered quickly with phosphate and this method of preservation is mainly limited to the late Ediacaran and early Cambrian periods, the animals that made them may actually have arisen earlier and persisted after this time span.

The Cambrian explosion, Cambrian radiation,Cambrian diversification, or the Biological Big Bang refers to an interval of time approximately 538.8 million years ago in the Cambrian Period when practically all major animal phyla started appearing in the fossil record. It lasted for about 13 – 25 million years and resulted in the divergence of most modern metazoan phyla. The event was accompanied by major diversification in other groups of organisms as well.

The urbilaterian is the hypothetical last common ancestor of the bilaterian clade, i.e., all animals having a bilateral symmetry.

Ediacaran type preservation relates to the dominant preservational mode in the Ediacaran period, where Ediacaran organisms were preserved as casts on the surface of microbial mats.

The fossils of the Burgess Shale, like the Burgess Shale itself, formed around 505 million years ago in the Mid Cambrian period. They were discovered in Canada in 1886, and Charles Doolittle Walcott collected over 65,000 specimens in a series of field trips up to the alpine site from 1909 to 1924. After a period of neglect from the 1930s to the early 1960s, new excavations and re-examinations of Walcott's collection continue to reveal new species, and statistical analysis suggests that additional discoveries will continue for the foreseeable future. Stephen Jay Gould's book Wonderful Life describes the history of discovery up to the early 1980s, although his analysis of the implications for evolution has been contested.

<span class="mw-page-title-main">Nephrozoa</span> Clade of animals

Nephrozoa is a major clade of bilaterians, divided into the protostomes and the deuterostomes, containing almost all animal phyla and over a million extant species. Its sister clade is the Xenacoelomorpha. The Ambulacraria are occasionally thought to be sister to the Xenacoelomorpha, forming the Xenambulacraria as basal Deuterostomia, or basal Bilateria invalidating Nephrozoa and Deuterostomia in multiple studies. The coelom, the digestive tract and excretory organs (nephridia), and nerve cords developed in the Nephrozoa. It has been argued that, because protonephridia are only found in protostomes, they cannot be considered a synapomorphy of this group. This would make Nephrozoa an improper name, leaving Eubilateria as this clade's name.

<i>Hallidaya</i> Extinct species of simple animal

The Ediacaran fossil Hallidaya, a close relative of Skinnera lived in Belomorian of the Late Ediacaran period prior to the Cambrian explosion and thrived in the marine strata on the ocean floor of what is now considered Australia. These fossils were disk-shaped organisms that were slightly dome shaped with tri-radial symmetry. These Ediacaran organisms thrived by living in low-energy inner shelf, in the wave- and current-agitated shoreface, and in the high-energy distributary systems.

<i>Ikaria wariootia</i> Early bilaterian organism fossil species

Ikaria wariootia is an early example of a wormlike, 2–7 mm-long (0.1–0.3 in) bilaterian organism. Its fossils are found in rocks of the Ediacara Member of South Australia that are estimated to be between 560 and 555 million years old. A representative of the Ediacaran biota, Ikaria lived during the Ediacaran period, roughly 15 million years before the Cambrian, when the Cambrian explosion occurred and where widespread fossil evidence of modern bilaterian taxa appear in the fossil record.

References

  1. Chemostratigraphy Across Major Chronological Boundaries. John Wiley & Sons. 18 December 2018. ISBN   978-1-119-38248-5.
  2. 1 2 3 The Invertebrate Tree of Life. Princeton University Press. 3 March 2020. ISBN   978-0-691-17025-1.
  3. 1 2 The Trace-Fossil Record of Major Evolutionary Events: Volume 1: Precambrian and Paleozoic. Springer. 17 November 2016. ISBN   978-94-017-9600-2.
  4. 1 2 3 4 Gehling, James G.; Runnegar, Bruce N.; Droser, Mary L. (2014). "Scratch Traces of Large Ediacara Bilaterian Animals". Journal of Paleontology. 88 (2): 284–298. doi:10.1666/13-054. S2CID   140559034.
  5. Annelida Basal Groups and Pleistoannelida, Sedentaria I. Walter de Gruyter GmbH & Co KG. 18 March 2019. ISBN   978-3-11-038178-8.
  6. Cowen, R. (2000). History of Life (3rd ed.). Blackwell Science. p. 63. ISBN   0-632-04444-6.
  7. Darwin, C (1859). On the Origin of Species by Natural Selection. Murray, London, United Kingdom. pp. 315–316.
  8. 1 2 Fedonkin, M.A.; Simonetta, A; Ivantsov, A.Y. (2007), "New data on Kimberella, the Vendian mollusc-like organism (White sea region, Russia): palaeoecological and evolutionary implications", in Vickers-Rich, Patricia; Komarower, Patricia (eds.), The Rise and Fall of the Ediacaran Biota, Special publications, vol. 286, London: Geological Society, pp. 157–179, doi:10.1144/SP286.12, ISBN   978-1-86239-233-5, OCLC   156823511