Tag Archives: artsprosjekt

Meeting a famous gelatinous neighbour: Bathykorus bouilloni

Every now and then, a hydrozoan species will make the headlines because of the problems it creates for humans in a particular location. Hydrozoan jellyfish may bloom unexpectedly, transforming the water into a gelatinous soup, stinging people and fish in the process, while some hydroids have a tendency togrow  massively in places where they are not wanted. There are others that end up in the news because they produce some unusual protein, or have a peculiar life cycle that could lead to important findings in the fields of medicine or ecology.

Then there is Bathykorus bouilloni, a hydrozoan jelly that has gotten some media attention due to its resemblance to an extremely famous movie character.

This is the original photograph by of a live specimen included in the description of the species, next to a pic of its look-alike. Photo of the jelly: Kevin Raskoff

This is the original photograph of a live specimen included in the description of the species, next to a pic of its look-alike. Photo of the jelly: Kevin Raskoff

This jellyfish was described in 2010 by Dr. Kevin Raskoff, who gave it its appropriate name. Bathykorus is a combination of Bathy (from bathus, meaning depth or deep in Greek) and korus (also from Greek, meaning helmet), and it refers to the deep-sea habitat of the species, as well as to the helmet-like shape of the bell (like that of an intergalactic villain). The word bouilloni in the name of this critter is a tribute to Dr. Jean Bouillon (1926-2009), one of the most prolific authors in Hydrozoan biology in the 20th century.

The species has been known to science only for some years, and indeed very few people may have seen it alive, but this does not necessarily mean that it is an uncommon animal: in fact, it may be extremely abundant in some places and is perhaps one of the most common species living at certain depths in the Central Arctic Ocean.

Caption: the peach-coloured spots in this medusa are most likely the remnants of its last meal. Photo: Aino Hosia

The peach-coloured spots in this medusa are most likely the remnants of its last meal. Photo: Aino Hosia

The wide circular mouth of this animal (a characteristic shared with many other jellyfish in the Order Narcomedusae) is best seen from above. Photo: Aino Hosia

The wide circular mouth of this animal (a characteristic shared with many other jellyfish in the Order Narcomedusae) is best seen from above. Photo: Aino Hosia

We at the HYPNO project are happy to have found this charismatic species off Svalbard, and even more so when it was possible to barcode it through NorBOL!

-Luis


References

Antsulevich, A. E. (2015). Biogeographic and faunistic division of the Eurasian Polar Ocean based on distributions of Hydrozoa (Cnidaria). Journal of the Marine Biological Association of the United Kingdom 95(08): 1533-1539.

Raskoff, K. A. (2010). Bathykorus bouilloni: a new genus and species of deep-sea jellyfish from the Arctic Ocean (Hydrozoa, Narcomedusae, Aeginidae). Zootaxa 2361(1): 57-67.

Sognefjorden cruise May 2017

After our week with SponGES on R/V Bonnevie, Luis and I had a night back in Bergen before we headed out on our second spring adventure: a four day cruise (still onboard Bonnevie) of Sognefjorden, the longest (205 km) and (deepest 1308 m) fjord in Norway.

The cruise, led by Prof. Henrik Glenner from the Institute of Biology, UoB,  was a multi-purpose one, with the majority of the projects being linked to the Norwegian Taxonomy Initiative (Artsprosjekt):

We collected material for the ongoing project that is investigating and mapping the barnacle fauna (Crustacea: Cirripedia) in Norway, which a special focus on the strange, parasitic barnacle Anelasma squalicola that is found on the shark Etmopterus spinax (velvet bellied lantern shark/svarthå).

The material we collected will also serve as an addendum to the project on Species inventory and nature type mapping of Sognefjorden, which was recently concluded.

As for the University Museum, Luis was onboard collecting pelagic and benthic Hydrozoa for the HYPNO-project, whilst I was on the hunt for more species for DNA-barcoding through NorBOL (the Norwegian Barcode of Life). We have also re-sampled some polychaete type localities from the 1970’s, and attempted to retrieve more material from stations where we have found new species in more recent material (we need more specimens before we can formally describe them).

In addition, we had two Danish researchers onboard that were studying the bioluminescence and eye development of the starfish family Brisingidae. The story told in images:

We should maybe also add "one of the most gorgeous" to the description of the fjord

We should maybe also add “one of the most gorgeous” to the description of the fjord

Velvet belly lanternshark, Etmopterus spinax

Velvet belly lanternshark, Etmopterus spinax

Henrik and Christoph sorting a shrimp trawl catch on deck

Henrik and Christoph sorting a shrimp trawl catch on deck

Eager pickings in the trawl catch

Eager pickings in the trawl catch

Not all trawl samples go according to plan... this one, taken in the open sea, ended up sampling *a bit* deeper than intended, so we got a lot of benthic animals - and mud. So. much. mud.

Not all trawl samples go according to plan… this one, taken in the open sea, ended up sampling *a bit* deeper than intended, so we got a lot of benthic animals – and mud. So. much. mud.

Most novel sampling gear yet? Collecting velvet belly lanternshark by monkfish!

Most novel sampling gear yet? Collecting velvet belly lanternshark by monkfish! (caught in the “benthic” trawl)

The brisinga sea stars are very fragile - and live deep down.

The brisinga sea stars are very fragile – and live deep down.

We amanged to get some not-too-damaged specimens with a small trawl

We manged to get some not-too-damaged specimens with a small trawl

The plankton net going our for collecting

The plankton net going our for collecting

Luis an Marie studying a plankton sample

Luis an Marie studying a plankton sample

Plankton

Plankton

For some reason, my samples seems to involve inordinate amounts of mud - good thing I had good helpers to work through it all!

For some reason, my samples seems to involve inordinate amounts of mud – good thing I had good helpers to work through it all!

Cruising in a postcard!

Cruising in a postcard!

Sadly, plastic pollution was prevalent in Sognefjorden as well - here's a soda bottle from a sample taken at 911 m depth

Sadly, plastic pollution was prevalent in Sognefjorden as well – here’s a soda bottle from a sample taken at 911 m depth

And here are som eof the plastic that we ended up with from our sampling, most of it from over 1000 meters depth.

Here is some of the plastic that we ended up with from our sampling, most of it recovered from over 1000 meters depth.

Our final night of the cruise was spent in the mud and the sunset - it's starting to become a recurring theme!

Our final night of the cruise was spent in the mud and the sunset – it’s starting to become a recurring theme!

Once again, thank you so much to the crew on Bonnevie for all their help!

Once again, thank you so much to the crew on Bonnevie for all their help!

-Katrine

Door # 6: Stuffed Syllid

Todays calendar critter is a Trypanosyllis sp. – a undescribed species from the genera Trypanosyllis in the family Syllidae. It most closely resembles a species described from the Mediterranean Sea. The Norwegian species is common in coral rubble, and has been assumed to be the same species as the one described from the Mediterranean. Genetic work reveals that these two are in fact separate species, and thus the Norwegian one is a new species awaiting formal description and naming. (If you read Norwegian, you can learn more about how species are described and named here: Slik gir vi navn til nye arter).

A new species of Trypanosyllis, collected in Sletvik, Norway. Photo by Arne Nygren. CC-by-sa

A new species of Trypanosyllis, collected in Sletvik, Norway. Photo by Arne Nygren. CC-by-sa

This specimen was collected, identified and photographed by Arne Nygren during our field work in Sletvik as part of his work on cryptic polychate species in Norway.

Syllids have opted for a rather fascinating way of ensuring high fertilization rates; something called epitoky: they asexually produce a special individual – the epitokous individual – from their bodies, and release this to go swimming in search of a mate. In the photo you can see that the female reproductive body (epitoke) is filled with orange eggs and has its own set of eyes, close to the middle of the animal. This section will break away from the mother animal and swim away in search of a male reproductive body to reproduce with. The mother animal will then grow a new female reproductive body.

-Arne & Katrine

Thursday Amphipod — Norwegian Marine Amphipoda

Amphipoda is an order of mainly small crustaceans living in the ocean, in lakes and rivers, in caves and in moist soil. They can be found worldwide, and the last count in the marine speciesdatabase WoRMS gives about 9 800 valid species. Most of the amphipod species are marine, with again most species connected to the sea-floor (benthic) – even if one of the suborders entirely lives in the watercolumn (pelagic).

The Norwegian Species-name List includes 561 amphipods in Norway, and the most recent listing of amphipods in the North-East Atlantic includes 850 species (Vader, 2007). How many amphipod species that do live in Norwegian waters is probably somewhere between these two numbers.

A collection of Norwegian Amphipoda. Photo: Katrine Kongshavn

A collection of Norwegian Amphipoda. Photo: Katrine Kongshavn

The Norwegian Species Initiative funded project “Norwegian Marine Amphipoda” (NorAmph) starting these days at the Universitymuseum has as one of its objectives to produce a better overview of what species are present in Norwegian marine waters. Utilising material from large projects such as MAREANO and GeoBio, from field-cruises with UNIS and not least the wonderful wealth of the Natural History Collections of the Universitymuseum of Bergen we hope to be able to give an answer to the question.

When a new species of any animal is described, it is mostly done on the basis of its morphology (how it looks). Lately we also add information about a small and species-specific part of the DNA, but for most species this is informations we don´t have yet. The project Barcode of Life aims to map this small part of every species´ DNA  as a tool for later identification – like the barcodes that are used in shops. Norway is participating in this project through the national node NorBOL – and another of the objectives of the NorAmph project is to try to DNA-barcode as many of the norwegian marine amphipod-species as possible. You can read more about the NorBOL work at our invertebrate lab here at her museum here.

One very important part of the NorAmph project is to present the amphipods to all you not working on this fascinating group. Maybe you played with sandhoppers during a beach-holiday, or hunted for sideswimmers under the cobbles on a rocky shore? You might even have been flyfishing with a “Gammarus”-fly? Follow our “TangloppeTorsdag” (in Norwegian) or ThursdayAmphipod (in English) tag. Everything we post under this project will be collected under the category “NorAmph”.

Anne Helene

Literature:
Vader, W. 2007 A checklist of the Marine Amphipoda of the North-East Atlantic and Norwegian Arctic. Published on Tromsø Amphipod Webpage

Door #11: Just a white blob?

Colobocephalus costellatus repainted from M. Sars (T.R. Oskars)

Colobocephalus costellatus repainted from M. Sars (T.R. Oskars)

When researching small, obscure sea slugs you are bound to run into surprises. Partly because it often takes a long time between discovery and identification, and also because a lot of the really interesting stuff is first revealed when new methods become widely available.

In 2011 a team of researchers from the Invertebrates collection were sampling specimens in Aurlandsfjorden for the Invertebrate collections and range data for the Norwegian Biodiversity Information Centre (Artsdatabanken). Among other interesting critters they found a 2 mm long white blob. While not initially impressive this small blob turned out to be the enigmatic cephalaspidean sea slug Colobocephalus costellatus (Cephalaspidea: Heterobranchia) described by Michael Sars from Drøbak in 1870. At the time of its re-discovery it was thought that this species, which is unique for Norway, had not been seen or collected since M. Sars first laid hands on it 145 years ago (more (in Norwegian) here). However, you continuously discover more information in the course of scientific work. During their work on the enigmatic slug Lena Ohnheiser and Manuel Malaquias found in the literature that the species had in fact been discovered a couple of times since 1870, first by Georg Ossian Sars in Haugesund some years after his father, and more recently by Tore Høisæter of Bio UIB in Korsfjorden outside Bergen.

Still, no in-depth analyses have been done on this species since M. Sars until Nils Hjalmar Odhner of the Swedish Natural History Museum drew the animal from the side showing some of the organs of the mantle cavity.

Most authors have had real difficulties to place this slug within the cephalaspids, and M. Sars even thought is possible that the slug might not be an opisthobranch. Some placed it within Diaphanidae based only on the globular shell, a family that has been poorly defined and often used as a “dump taxon” for species that hare hard to place. Yet others thought it might even be the same as the equally enigmatic Colpodaspis pusilla, which has been suggested to be a philinid sea slug (flat slugs digging around in mud and sand).

What was unique about the most recent find was that this was the first time it was collected alive and photographed with high magnification. The material was also so fresh that Lena and Manuel could dissect the animal and study its internal organs. In their 2014 paper “The family Diaphanidae (Gastropoda: Heterobranchia: Cephalaspidea) in Europe, with a redescription of the enigmatic species Colobocephalus costellatus M. Sars, 1870” they tried to resolve the relationships between these globe shelled slugs. What they found was that Diaphanidae was likely not a real grouping of species, containing at least three distinct groups, where one group was Colobocephalus and Colpodaspis, which were closely related to each other, but also quite distinct.

Colobocephalus costellatus M. Sars, 1870. Photo Lena Ohnheiser, CC-BY-SA. Also featured on http://www.artsdatabanken.no/File/1292

Colobocephalus costellatus M. Sars, 1870. Photo: Lena Ohnheiser, CC-BY-SA. Also featured on http://www.artsdatabanken.no/File/1292

Another new development with the sampling in Aurlandsfjorden was that the slugs were preserved in alcohol rather than formalin. Formalin is good for preserving the morphology of animals, but it destroys DNA. On the other hand, alcohol is perfect for preserving DNA. This lead to C. costellatus to be included in a 2015 DNA based phylogenetic analysis of cephalaspidean sea slugs.

Modified Tree from Oskars et al. (2015)

Modified Tree from Oskars et al. (2015)

This resulted in that the slug was found to be indeed an Opisthobranchia, and as Lena and Manuel thought, Colobocephalus and Colpodaspis were placed in their own family, Colpodaspididae. Whereas the traditional “Diaphanidae” was split apart. Even weirder was the sea slugs that were shown to be the closest relatives of Colpodaspididae, which were neither the philinids or the diaphanids. The closest relatives turned out to be slugs that are equally as weird and unique as Colpodaspididae, namely the swimming and brightly colored Gastropteridae (sometimes called Flapping dingbats) and the Philinoglossidae, which are tiny wormlike slugs that live in between sand grains.

*Cousin Meeting*  - "You sure we are related?"  - "Well, the scientists seem to think so. I see no reason to waste a good party!"

*Cousin Meeting*
– “You sure we are related?”
– “Well, the scientists seem to think so. I see no reason to waste a good party!”

So it took 145 years from its discovery before Colobocephalus became properly studied and its family ties revealed, but it is still mysterious as we do not know much about their ecology or diet.

Suggested reading:

Colobocephalus costellatus: http://www.biodiversity.no/Pages/149747

Colpodaspis pusilla: http://www.biodiversity.no/Pages/149766

Philinoglossa helgolandica: http://www.biodiversity.no/Pages/149915

Høisæter, T. (2009). Distribution of marine, benthic, shell bearing gastropods along the Norwegian coast. Fauna norvegica, 28.

Gosliner, T. M. (1989). Revision of the Gastropteridae (Opisthobranchia: Cephalaspidea) with descriptions of a new genus and six new species. The Veliger, 32(4), 333-381.

Odhner, N.H. (1939) Opisthobranchiate Mollusca from the western and northern coasts of Norway. Kongelige Norske Videnskabers Selskabs Skrifter, 1939, 1–92.

Ohnheiser, L. T., & Malaquias, M. A. E. (2014). The family Diaphanidae (Gastropoda: Heterobranchia: Cephalaspidea) in Europe, with a redescription of the enigmatic species Colobocephalus costellatus M. Sars, 1870. Zootaxa, 3774(6), 501-522.

Oskars, T. R., Bouchet, P., & Malaquias, M. A. E. (2015). A new phylogeny of the Cephalaspidea (Gastropoda: Heterobranchia) based on expanded taxon sampling and gene markers. Molecular phylogenetics and evolution, 89, 130-150.

Sars, M. (1870) Bidrag til Kundskab om Christianiafjordens fauna. II. Nyt Magazin for Naturvidenkaberne, 172–225.

-Trond

Door #3: Prepare to be HYPNOtized

One of this year’s new projects at the Invertebrate collections is HYPNO – Hydrozoan pelagic diversity in Norway, funded by the Norwegian Taxonomy Initiative.

A selection of photos depicting some of the species encountered so far in the project

A selection of photos depicting some of the species encountered so far in the project

Hydrozoa are a class of cnidarians, the pelagic representatives of which include hydromedusae as well as colonial siphonophores and porpitids. They are thus “cousins” to the more familiar larger scyphozoan jellyfish such as the moon jelly or the lion’s mane jelly. The size of pelagic hydrozoans ranges from small medusae of less than 1 mm to siphonophore colonies reaching several meters in length. They are mostly predators that use their tentacles and stinging cells to catch other zooplankton or even fish larvae. Most of the time they go largely unnoticed by the public, but at times they can form blooms and deplete zooplankton as well as cause problems for aquaculture and fisheries or sting bathers.

The aim of HYPNO is to chart, document and DNA-barcode the diversity of hydromedusae and siphonophores occurring in Norway. Gelatinous zooplankton, including hydrozoans, has been generally less studied than their crustacean counterparts, and we know less about their diversity. This is due to several challenges in studying them. First of all, many pelagic hydrozoans, particularly the colonial siphonophores, are very fragile and often damaged during sampling with standard plankton nets. This can make it difficult to identify them. Secondly, preserving hydromedusae and siphonophores for later work is problematic. For morphological studies, they are best preserved in formalin, since most other fixatives used for zooplankton -including ethanol- cause distortion and shrinkage of their gelatinous bodies, rendering the animals impossible to identify. Formalin fixation, however, hinders further genetic work.

To overcome these practical problems, HYPNO uses gentle collection methods to obtain specimens in good condition. Collected samples are immediately examined for hydrozoans, and the live animals are identified and documented with photos before they are fixed in ethanol for DNA barcoding of CO1 and 16S sequences.

So far, HYPNO has participated on two cruises by the Institute of Marine Research: to the North Sea and Skagerrak on RV Johan Hjort 24 Apr – 4 May 2015 and to the Arctic Ocean and Fram Strait on RV Helmer Hanssen 17 Aug – 7 Sep 2015. So far, 34 species have been photographed and sampled for DNA. Here is a selection of pictures depicting some of the species encountered during these surveys.

You can read more about HYPNO at http://data.artsdatabanken.no/Pages/168312.

-Aino