Columbus

Two species live in caves , a habitat to which they are excellently adapted due to their ability to squeeze into the smallest of cracks and which guarantees them constant living conditions. Since the decisive prerequisites for a cave life were probably already in place before the settlement of this habitat , one speaks of exaptation . Agriculture has apparently opened up new habitats for velvet worms; in any case, they can also be found in cocoa and banana plantations in Central America and the Caribbean .

Because the risk of dehydration is greatest during the day and in dry weather, it is not surprising that colobus are usually active at night and in rainy weather. In cold or dry environmental conditions, they seek out crevices in the ground where they put their bodies into a state of rest. They turn away from strong light sources and are therefore negative phototactic .

The largest population density measured so far is very low with around 10 individuals per square meter of soil; Poles are also very difficult to find in their habitats.

Locomotion

To get around, the animals use their legs to crawl forward; unlike the arthropods, they always move both legs of a pair at the same time. Contact of the stomach side with the substrate is avoided as far as possible, so the body is held above the ground by the stubby feet. The claws on the feet are only used on hard, rough ground where a firm grip is required; On soft substrates such as moss, the animals walk on the foot cushions at the base of their claws.

The actual locomotion occurs less through the use of the leg muscles, but rather through a local change in body length. This can be influenced by the animals through the use of the circular and longitudinal muscles: If the former is contracted, the body cross-section is reduced and the corresponding segment expands because its volume must remain constant due to the incompressible fluid contained in the hemocoeloma - this is the usual mode of action Hydroskeleton as it is used in various worms . As a result of the stretching, the legs of the affected part of the body lift and swing forward. Local contraction of the longitudinal muscles, on the other hand, shortens the corresponding segment and in this way moves the associated pair of legs, which are now in contact with the substrate, backwards; this part of the movement cycle is the effective kick, which is responsible for the actual movement. The individual muscle stretches and relaxations of the segments are coordinated by the nervous system in such a way that contraction waves run through the body, which cause one pair of legs to swing forwards after the other and then move backwards on the ground. The speeds achieved in this way vary between about one millimeter and a little more than one centimeter per second.

nutrition

Poles are predatory organisms that are able to prey on animals that are considerably larger than themselves. The range of prey includes woodlice (Isopoda), termites (Isoptera), real crickets (Gryllidae), dust lice (Psocoptera), cockroaches ( Blattodea), millipedes (Myriapoda), spiders (Araneae), various worms and even larger snails (Gastropoda). They are considered the ecological equivalent of the centipedes (Chilopoda).

They usually track down potential victims with the help of the antennas and then follow them down to the smallest cracks. While smaller prey is killed directly, in larger animals they use a white, glue-like and high- protein liquid that is produced by the two mucous glands to immobilize their victims. It is sprayed through the pores of the oral papillae over a distance of up to 30 centimeters and hardens very quickly in air, so that the prey gets caught in the sticky substance and ultimately becomes immobile. On the other hand, the substance does not stick to the water-repellent skin of the velvet worms themselves, so that the animals can safely approach their prey at the shortest possible distance. By injecting toxic saliva it is now killed and pre-digested; the sharp jaws then cut the prey into fine pieces that pass through the mouth into the digestive tract.

Predators and parasites

Reproduction and life cycle

Colobus reproduce sexually throughout . The only known exception is the species Epiperipatus inthurni , in which no males have been detected so far and which reproduces parthenogenetically .

In many cases, the species show a noticeable sexual dimorphism - the females are usually larger than the males and, if the number of legs within a species is variable, also have more legs. In many species, they are only inseminated once in a lifetime, which has led to the fact that mating sometimes takes place when the reproductive organs of the females are not yet mature, for example in Macroperipatus torquatus at the age of three months. In this case, the transferred sperm are stored in a special storage organ where they can remain fertile for longer periods of time.

In Stummelfüßern can be found both egg-laying ( oviparous ), eggs viviparous ( ovoviviparous ) and viviparous ( viviparous ) forms.

• The former are only found in the family of the Peripatopsidae , often in regions with unsteady food supplies or changeable climates. The approximately 1.3 to 2 millimeters large, yolk-containing eggs are in this case covered by a protective eggshell made of chitin; maternal care is unknown.
• The majority of the species is viviparous: the medium-sized eggs, only covered by a membrane, remain in the "uterus", the uterus, but the embryos feed on the moderate amount of yolk contained in the eggs and are not separated from the mother supplied, they are therefore also called lecitotrophic ; they only hatch shortly before birth. Presumably this represents the original mode of reproduction of the velvet worms, that is, both oviparous and viviparous species have developed from the ovoviviparous forms.
• Genuine viviparous species can be found in both families, especially in tropical regions with a stable climate throughout the year and an even food supply. The embryos, which develop from the micrometer-sized eggs, are nourished in the uterus by their mother; they are therefore called matrotrophic . The supply takes place either through maternal secretion into the uterus or through a real tissue connection between the uterine epithelium and the growing embryo, a so-called placenta . The former occurs only outside of the American continent, the latter is found primarily in America and the Caribbean , less often in the ancient world. The gestation period, at the end of which the young are largely developed, can be up to 15 months. The embryos found in the uterus of a female do not necessarily have to be of the same age; It is quite possible that there are numerous differently developed animals that also descend from different males.

The number of offspring of a female varies between 1 and 23 per year; the development from the fertilized egg cell to the adult stage, which lasts between 6 and 17 months, basically takes place directly without the larval stage; this is probably also the original development mode. Poles can live up to 6 years.

Danger

It is difficult to assess the global endangerment of the colobus diversity; many species are only known from the type locality, i.e. the place from which the first described specimen came. Low population densities, the mostly nocturnal way of life of the animals, possibly as yet unrecognized seasonal influences and gender-specific differences make the collection of trustworthy information even more difficult.

So far, only eleven species have been examined in sufficient detail to be able to provide information about their frequency. The International Union for the Conservation of Nature and Natural Resources lists with the 2009 edition on the Red List as follows:

• three species as critically endangered, whereby one species is presumably already extinct,
• two species as endangered ("Endangered"),
• four species as endangered ("Vulnerable"),
• one species was classified as endangered and is now listed as having insufficient data ("data deficient");
• a Caribbean species classified as "Near Threatened".

The main cause of the threat is the loss and fragmentation of habitat due to increasing industrialization, the drainage of wetlands and slash and burn for agricultural purposes. Many species also have a naturally low population density and a geographically narrow distribution area, which means that even minor local disturbances of the ecosystems affected can lead to the extinction of entire populations and possibly species. Collecting animals for universities or research institutes also plays a regional role.

It has not yet been possible to breed columbus. Corresponding considerations exist not only with the ulterior motive of being able to provide populations for later reintroduction, but also to better educate the public concerned about the animals and the need to protect them. Due to the often bright colors and the great importance for the history of evolution, an attitude in “insect zoos” would be an option.

Tribal history

Modern forms

Among the present-day forms, the velvet worms are probably very closely related to the arthropods, a very extensive taxon that includes crustaceans (Crustacea), insects (Insecta) and arachnids (Arachnida). They share with them, among other things, the skinned exoskeleton made up of α-chitin and non-collagenous proteins, the gonads and excretory organs surrounded by real coelomic tissue, the open blood system with the tubular heart on the back, a body cavity divided into pericardial and perivisceral cavities, breathing through trachea and a similar embryonic development. In addition, there is segmentation with two body attachments per segment. Antennae, mandibles and oral papillae, on the other hand, are presumably not homologous to the corresponding body parts of the arthropods, that is, they have evolved independently of these.

Another closely related group are the relatively obscure tardigrades (tardigrada), which, however, due to their very small size, lack a number of features of the columbus and arthropods, such as blood circulation and separate respiratory structures. Colibuses, arthropods and tardigrades together form a monophyletic taxon, the Panarthropoda, which means that all three groups taken together include all descendants of their last common ancestor.

Within the Panarthropoda, the stumpworms were usually grouped together to form a taxon Protoarthropoda due to a certain similarity in shape with the tardigrade. This designation was intended to express that both columbus and tardigrade have not yet reached the full developmental level of arthropods. Modern systematic theories reject such notions of “primitive” and “highly developed” forms of life and instead orientate themselves exclusively to the phylogenetic relationships of the taxa involved. These have not yet been fully clarified; However, it is considered to be relatively likely that the sister group of the stumpworts is formed by a taxon that includes both tardigrade and arthropod and is called the Tactopoda (but sometimes also Tritocerebra):

Onychophorans can be considered highly evolved annelids, adapted to terrestrial life, which announced prophetically the Arthropoda. They are a lateral branch which has endured from ancient times until today, without important modifications.

Onychophores can be viewed as highly developed annelids, adapted to rural life, which prophetically heralded the appearance of the arthropod. They are a side branch that has survived until today without any relevant changes.

Modern systematics endeavors to leave out criteria such as a “higher” or “lower” stage of development of the living beings under consideration, as well as distinctions between main and side branches - it only considers the relationships established on the basis of cladistic methodology to be real. From this point of view, the segmented body in all animal groups concerned, the presence of paired segment appendages, the paired arrangement of excretory organs in each segment and, above all, a rope ladder-like nervous system based on a ventrally located double nerve cord still speak in favor of the Articulata concept.

The representatives of an alternative and now mostly preferred concept, the so-called Ecdysozoa hypothesis, on the other hand, place annelid worms and panarthropoda in two very different large groups, the Lophotrochozoa on the one hand and the molting animals (Ecdysozoa) on the other. Since the concept was first drawn up, numerous additional data have been added to support it. Due to e.g. B. the similar expression of the Hox genes , the genes for the organization of the extremities and confirmed by a molecular family tree based on the mitochondrial DNA, there is hardly any doubt about the position of the stumpworms within the Ecdysozoa.

The aforementioned common features of annelids and columbus are either convergent or “primitive” features, so-called symplesiomorphies , which both affected groups have adopted unchanged from the common ancestors of Lophotrochozoa and molting animals. In the first case, the rope ladder system would have developed independently twice in the course of evolution, in the second it was a very old characteristic that cannot establish a particularly close relationship between annelid worms and Panarthropoda.

The ecdysozoan concept sees the extended family of the velvet worms in a Cycloneuralia called taxon to the one next thread (Nematoda) and string worms (Nematomorpha) three rather obscure groups kinorhyncha (Kinorhyncha) priapulida (Priapulida) and loricifera (Loricifera) counts.

Extinct forms

The stratigraphic range of the velvet worms includes fossils one of three different time periods, including the early periods of the Paleozoic Cambrian and Ordovician , the later Carboniferous and the Tertiary in the Cenozoic . The Cambrian and Ordovician forms, whose association with the stumpworts is disputed, all still lived in the sea, while the later species are already considered terrestrial.

Traditionally, all fossil forms are placed in a separate taxon Xenusia, while the modern ones are called Euonychophora. However, this classification says nothing about the actual phylogenetic relationships, which is why it is not accepted by cladist taxonomists.

Lobopods

The oldest almost completely preserved fossils come from the Lower Cambrian. The most noticeable features that these lobopods share with the modern columbus are the worm-like body shape and numerous stub legs. A special feature of many lobopods, on the other hand, are numerous armor plates, the sclerites , which often cover the back of the whole body including the head; since they end in long, pointed back spines, they most likely had a defensive function to protect against predators. Individual sclerites can be detected as part of the so-called “ Small Shelly Fauna ” (SSF) even before the onset of the Cambrian 543 million years ago - accordingly, the lobopods or their immediate ancestors developed and were already in the Ediacarian of the Proterozoic thus the first animals to walk on legs.

Lobopod fossils can now be found in North America, China and North or Northeast Europe. In the Cambrian, however, due to the continental drift , the sites were much further south in the tropical and temperate belt of the earth and at that time corresponded to flat lagoon waters.

The way of life of the lobopods is largely in the dark, some species apparently a carnivorous diet , i.e. ate other animals such as sponges (Porifera) or echinoderms (Holothuroidea) of the genus Eldonia . It has been proven that they shed their skin like modern velvet worms.

While they made up a considerable proportion of the biodiversity in the Cambrian, it was drastically reduced in the Ordovician; At the latest with the onset of the Silurian mountains , the lobopods are considered extinct in the narrower sense. The American paleontologist Stephen Jay Gould sees this as a symptom of a large-scale collapse of the species richness of the Cambrian, which heralded an end to the "experimental phase", but his theses are considered controversial.

Lobopods are traditionally associated with the velvet worms because of their very similar morphology; according to this view they were members of the lineage of this taxon:

Occasionally the scientific name Onychophora only designates the land-living forms, while the larger group, which also includes the various lobopods, is then referred to as the lobopodia.

An important alternative view assumes that the lobopods were instead members of the lineage of the Panarthropoda and Tactopoda:

The genus Aysheaia , which has a particularly large number of characteristics in common with the modern velvet worms, therefore forms the sister group of all other Panarthropoda, which is then divided into the velvet worms and all other forms. The remaining Lobopod genera are now considered to be representatives of the line of development that leads to the modern tardigrade and arthropod. From the cladistic analysis, a trend towards increased external segmentation and a coordination of the fine body and leg ringing with the position of the segment boundaries can be determined.

However, the result is difficult to reconcile with the Articulata hypothesis because it means that the pronounced segmentation of annelids and arthropods must have arisen independently of one another. For the velvet worms this would mean that the lack of clearly recognizable external segmentation is an original, "primitive" and not a secondary characteristic. The second hypothesis on the systematic position of the lobopods is therefore much more compatible with the Ecdysozoa concept mentioned above.

Rural forms

Four terrestrial forms of the velvet worms are known for which, in contrast to the lobopods, there is no great doubt about the systematic position.

From the Mesozoic only a fossil is known, the Cretaceous kind cretoperipatus burmiticus that in amber from Southeast Asia Myanmar has been found and is dated to 100 million years ago. It can even be assigned to one of the modern families, the Peripatidae .

The fourth fossil species is Tertiapatus dominicanus , known from amber from the Caribbean island of Hispaniola . It is possible, but not provable, that she already belonged to one of the two modern families, the Peripatidae. The species can be dated to an age of 17 to 20 million years.

The mucous glands can be clearly seen on both fossils of the Tertiary, which must have formed at this point in time at the latest, but probably much earlier. Formally, the two tertiary forms are combined in a taxon Tertiapatoidea, which is probably only one form taxon.

Systematics

The modern velvet worms form a so-called monophyletic group, i.e. they include all descendants of their common ancestor. Important common derived features ( synapomorphies ) are, for example, the jaw tools (mandibles) of the second and the oral papillae with associated mucous glands of the third body segment, ventral nerve cords with numerous cross connections per segment and the special shape of the trachea .

Up to 2004 about 155 modern species were described, assigned to 47 genera; however, the actual number of species is probably about twice as large. The best known is the type genus Peripatus , which was described as early as 1825 and which in English-speaking countries is also representative of all velvet worms.

All genera are assigned to one of two families , the distribution areas of which do not overlap, but are separated from each other by arid areas or seas.

swell

literature

• H. Ruhberg: Onychophora, velvet worms . in: W. Westheide, R. Rieger: Special Zoology. Part 1. Protozoa and invertebrates. Ulmer, Stuttgart 1974, Elsevier, Munich 2007, ISBN 3-8001-2429-7 , ISBN 3-8274-1575-6
• Edward E. Ruppert, RS Fox, RD Barnes: Invertebrate Zoology: A functional evolutionary approach . Chapter 15. Brooks / Cole, London 2004, p. 505, ISBN 0-03-025982-7
• RC Brusca, GJ Brusca: Invertebrates. Chapter 15. Sinauer Associates, Sunderland Mass 2003, p. 463, ISBN 0-87893-097-3

Scientific literature

• GE Budd: The morphology of Opabinia regalis and the reconstruction of the arthropod stem group in: Lethaia. Taylor & Francis, Oslo 29.1996, p. 1. ISSN  0024-1164
• J. Eriksson: Evolution and Development of the Onychophoran Head and Nervous System. in: Comprehensive summaries of Uppsala dissertations from the Faculty of Science and Technology. Upsala 833, 2003. ISSN  1104-232X
• X. Hou, J. Bergström: Cambrian lobopodians - ancestors of extant onychophorans. in: Zoological Journal of the Linnean Society. Blackwell, Oxford 114.1995, p. 3. ISSN  0024-4082
• J. Monge-Najera: Phylogeny, biogeography and reproductive trends in the onychophora. in: Zoological Journal of the Linnean Society. Blackwell, Oxford 114.1995, p. 21. ISSN  0024-4082
• TR New: Onychophora in invertebrate conservation: priorities, practice and prospects. in: Zoological Journal of the Linnean Society. Blackwell, Oxford 114.1995, p. 77. ISSN  0024-4082
• G. Poinar: Fossil onychophorans from Dominican and Baltic Amber: Tertiapatus dominicanus ng, n.sp. (Tertiapatidae n. Fam.) And Succinipatopsis balticus ng, n. Sp. (Succinipatopsidae n. Fam.) With a proposed classification of the subphylum Onychophora. in: Invertebrate Biology. Blackwell, Malden Mass 119.2000, p. 104. ISSN  1077-8306
• G. Poinar: Fossil Velvet Worms in Baltic and Dominican Amber: Onchychophoran Evolution and Biogeography. in: Science . Moses King, Cambridge Mass 273.1996, p. 1370. ISSN  0096-3771
• CJ Wedeen, RG Kostriken, D. Leach, P. Whitington: Segmentally iterated expression of an engrailed-class gene in the embryo of an Australian onychophoran. in: Development Genes and Evolution. Springer, Heidelberg 207.1997,4, p. 282. ISSN  0949-944X

Individual evidence

1. ↑ Georg Mayer & Steffen Hartzsch (2007): Immunolocalization of serotonin in Onychophora argues against segmental ganglia being an ancestral feature of arthropods. BMC Evolutionary Biology 7: 118 doi : 10.1186 / 1471-2148-7-118 http://www.biomedcentral.com/1471-2148/7/118
2. ^ Georg Mayer, Paul M. Whitington, Paul Sunnucks, Hans-Joachim Pflüger (2010): A revision of brain composition in Onychophora (velvet worms) suggests that the tritocerebrum evolved in arthropods. BMC Evolutionary Biology 10: 255. http://www.biomedcentral.com/1471-2148/10/255
3. ^ Georg Mayer (2006): Structure and development of onychophoran eyes: What is the ancestral visual organ in arthropods? Arthropod Structure & Development Volume 35, Issue 4: 231–245. doi : 10.1016 / j.asd.2006.06.003
4. ↑ J. Monge-Najera, Phylogeny, biogeography and reproductive trends in the onychophora, Zoological Journal of the Linnean Society, 114, 1995, p. 21
5. ↑ Jennifer K. Grenier, Theodore L. Garber, Robert Warren, Paul M. Whitington, Sean Carroll (1997): Evolution of the entire arthropod Hox gene set predated the origin and radiation of the onychophoran / arthropod clade. Current Biology 7: 547-553. doi : 10.1016 / S0960-9822 (06) 00253-3
6. ↑ Janssen, R., Eriksson, BJ, Budd, GE, Akam, M., Prpic, N.-M. (2010): Gene expression patterns in an onychophoran reveal that regionalization predates limb segmentation in panarthropods. Evolution & Development 12: 363-372. doi : 10.1111 / j.1525-142X.2010.00423.x
7. ↑ Lars Podsiadlowski, Anke Braband, Georg Mayer (2008): The complete mitochondrial genome of the Onychophoran Epiperipatus biolleyi reveals a unique transfer RNA set and provides further support for the Ecdysozoa hypothesis. Molecular Biology and Evolution 25 (1): 42-51. doi : 10.1093 / molbev / msm223

Web links

Commons : Colibus  - Collection of images, videos and audio files

• Onychophora website , with information from scientific sources (English)

This version was added to the list of excellent articles on June 3, 2005 .