Dr. Anita Brinckmann-Voss and Hydroid Research at Race Rocks

anitaDr. Anita Brinckmann-Voss  passed away in December of 2017.

From 1986, to 2005,  Dr. Brinckmann-Voss of Sooke, BC assisted the students and faculty of Lester Pearson College with her understanding of marine invertebrate ecology and her expertise in the taxonomy of hydroids.  These small colonial animals, the alternate stage of the life-cycle of jellyfish, occur in rich profusion underwater at the Race Rocks Marine Ecological Reserve.  When the original species list was done for the Race Rocks Ecological Reserve Proposal, in 1979, only 2 hydroids had been included on our species list. Now over 60 species have been identified by Anita and she continued to assist students with research projects while she furthered her research on specimens from the island until 2004. Anita has established long term research plots in a tidepool at the reserve and documents the distribution of hydroids underwater with the assistance of students and faculty in the Diving program at Lester B. Pearson College. Below: Anita accompanied Garry, Chris and Joe on a dive to Secretary Island, West of Race Rocks up the Strait of Juan de Fuca towards Sooke. The purpose was to collect samples for hydroid specimens.  

anitaandsvobodaDr. Armin Svoboda and his son Hanno visited Race Rocks with Chris Blondeau and Dr. Anita Brinckmann-Voss in August of 2004. His pictures taken on a dive there are linked here.

 

 

 See this link for the hydroids identified by Anita. https://www.racerocks.ca/tag/hydroid/ 

See all the posts on this website tagged with Dr. Anita Brinckmann-Voss

bellatitle-1Gallery of photomicrographs of Hydroids- photos by Dr. Anita Brinckmann-Voss

tubulariaVideo on the habitat of a rare Tubularia

 

 

 

 

 

westshorePhotos of  Intertidal Hydroid Habitat on West side of Race Rocks .

 

 

 

 

PUBLICATIONS of Dr. Voss from her Research at Race Rocks Ecological Reserve :

 1. Brinckmann-Voss, A. , Lickey, D.M. , and Mills, C.E. 1993 Rhysia fletcheri (Cnidaria, Hydrozoa, Rhysiidae), a new species of Colonial Hydroid from Vancouver Island British Columbia, Canada) and the San Juan Archipelago (Washington, USA) . Canadian Journal of Zoology 71: 401-406

Abstract: 

  • A new species of colonial athecate hydroid, Rhysia fletcheri , is described from Vancouver Island, British Columbia, Canada, and from Friday Harbour, Washington, U.S.A. It’s relationship to Rhysia autumnalis Brinckmann from the Mediterranean and Rhysia halecii (Hickson and Gravely) from the Antarctic and Japan is discussed. Rhysia fletcheri differs from Rhysia autumnalis and Rhysia halecii in the gastrozooid having distinctive cnidocyst clusters on its hypostome and few, thick tentacles.
  • hydrfemeMost of its female gonozooids have no tentacles. Colonies of R. fletcheri are without dactylozooids. The majority of R. fletcheri colonies are found growing on large barnacles or among the hydrorhiza of large thecate hydrozoans. 
  • Rhysia fletcheri occurs in relatively sheltered waters of the San Juan Islands and on the exposed coast of Southern Vancouver Island. Colored photos of Rhysia males. females and gastrozooids are included.

 2. Brinckmann-Voss, A. 1996. Seasonality of Hydroids (Hydrozoa, Cnidaria) from an intertidal pool and adjacent subtidal habitats at Race Rocks, off Vancouver Island,Canada, Scientia Marina Advances in Hydrozoan Biology , Vol 60 (1):89-97

Abstract:

  • An assemblage of 27 hydroid species was reported from a tide pool in the lower rocky intertidal zone, and compared with 42 hydroids of the adjacent subtidal region. Location of hydroids within the pool, seasonal occurrence, growth and sexual maturity were tabulated, and some systematic aspects discussed. Possible causes of hydroid species diversity were considered, including location of the tide pool in an area of tidal rapids, and shading by surf-grass and rock cliffs during low tide.

Substrate with Invertebrates at the Tidal Energy Site

Chris Blondeau and Juan Carlos do another video of the substrate at the site of the piling installation prior to the pile drilling operation for the Tidal Current Energy Project. They document some of the species of hydroid, colonial ascidian and sponges which grow on the giant barnacles in the area. March 29, 2006.

Note: The video pauses on each clump in order to have a better view.

 

Invertebrate Scenes from the video:

Phyllospadix scouleri: surf grass– Race Rocks taxonomy


Domain: Eukarya
Kingdom: Plantae
Clade: Tracheophytes
Clade: Angiosperms
Clade: Monocots
Order: Alismatales
Family: Zosteraceae
Genus: Phyllospadix
Species: P. scouleri
Binomial name
Phyllospadix scouleri

Genus/species Phyllospadix scouleri (Hooker)

 

Description: This flowering plant is most characteristic of the open rocky shores of the coast that are exposed to the full force of the waves, as on the west coast of Vancouver Island.  There it forms bright emerald-green beds on the rocks near extreme low-tide level.  The plants are relatively short, usually not more than a metre in length, and the leaves are 20-32 mm. wide.  Short basal flowering stems are produced, which are 5-8 cm. long.

Habitat:  On rocks in the lower intertidal and upper subtidal zones.

Pacific Coast Distribution:  Alaska to Mexico.

Robert Scagel, 1972

 
taxonomyiconReturn to the Race Rocks Taxonomy
and Image File
pearsonlogo2_f2The Race Rocks taxonomy is a collaborative venture originally started with the Biology and Environmental Systems students of Lester Pearson College UWC. It now also has contributions added by Faculty, Staff, Volunteers and Observers on the remote control webcams. March 8 2009- Ryan Murphy

Substrate analysis for the Tidal Energy Project

Chris Blondeau and Juan Carlos video the substrate at the site of the tidal energy piling installation. This is prior to the pile drilling operation for the Pearson College-ENCANA_Clean Current Demonstration Tidal Current Energy Project. They find bedrock in the area 30 cm under the surface at a depth of 24 meters of water.


See other archived video with Pearson College Divers

Invertebrate Scenes from the video:

metrid2

Metridium anemone with hydrocoral

hydroid

Hydroids

cribrinopsis

Cribrinopsis anemone and brooding anemones

bloodstar

Blood star and yellow sponge

generatorsLink to the Integrated Energy Project at Race Rocks

Hydroid photomicrography by Dr. Anita Brinckmann-Voss

Find the individual file on these species photographed by Dr.Brinckmann- Voss in the Race Rocks taxonomyo

See this link for all the hydroid entries:  https://www.racerocks.ca/tag/hydroid/

These images were scanned from 35 mm.slides taken by photomicrography of samples collected on permit at Race Rocks by Dr. Anita Brinckmann-Voss* with the assistance of students and faculty of Lester B. Pearson College. Scanning and preparation for html was done by Garry Fletcher.

Copyrighted 1999–All Images on this page are the property of:
Dr. Anita Brinckmann- Voss They can not be used or modified without her written permission.

* All hydroid species shown on this website have been reported in

:Brinckmann-Voss, A. 1996.- Seasonality of hydroids (Hydrozoa, Cnidaria)

from an intertidal pool and adjacent subtidal habitats at Race Rocks,

off Vancouver Island, Canada. Scientia Marina

60 (1):89-97.

Return to the file on Dr. Anita Brinckmann-Voss

Blue water Diving — Pearson College Divers

Henry Steinberg, Julia Clarke and Laura Verhegge do their first tether dive with Chris off the shores of Race Rocks in Race Passage. The apparatus for the dive was constructed by Henry Steinberg, a Pearson College diver, as part of a project in his PADI Divemasters course. This type of diving is useful for research purposes when one wants to sample jellyfish, salps or other macro-planktonic life forms which may otherwise be damaged if collected in a towed plankton net. It is also necessary as a safety measure for drift diving when the bottom is beyond safety limits, and there are currents involved such as here in the Strait of Juan de Fuca.

Photography of Dr. Armin Svoboda

anitaandsvoboda
Dr. Armin Svoboda, Prof. Em., Ruhr Universität Bochum, Biology, Systematic Zoology. visited Race Rocks with Chris Blondeau and Dr. Anita Brinckmann-Voss in August of 2004.

He has provided us with a number of photos taken underwater on his dive. They are included within the pictures of the Race Rocks Taxonomy. His photos are shown below, linked to their location in the Taxonomy. Dr.Svoboda retains the copyright on all of his photos, please contact him directly if you wish to use one of his photos.

E-mail: Dr.Armin Svoboda :armin.svoboda (use the at sign) ruhr-uni-bochum.de
Dr. Svoboda was head and professor at the Institute for “Spezielle Zoology” at the “ Ruhr University” , Bochum, Germany.
He is now retired, but goes on working. Dr. Voss considers him to be one of the best scientific photographers of invertebrates. He frequently dives with his wife Dorothea and son Hanno.

Permission to use any of these photos must be obtained from Dr.A.Svoboda: see above.
The following pictures are from some of those he took while diving at Race Rocks.

The text of each picture is linked to a page in the taxonomy of that species.

In Situ Measurement of Benthic Community Trophic Dynamics at Race Rocks

Research of GITAI YAHEL

In March, 2004, Dr.Gitai Yahel, a Post Doctorate researcher from the Biology Department at the University of Victoria, joined us for two dives at Race Rocks to check out the possibility of doing research there. He is interested in suspension feeders’ nutritional ecology and the role of dissolved substance as a food source for marine organisms. Currently he is trying to establish a field survey of the dissolved and picoplanktonic diet composition of active suspension feeders such as sponge, mussels and tunicates.

Sponges, bivalves and tunicates play an important role in the trophic dynamics of many benthic communities. However, direct in situ measurements of their diet composition, filtration and excretion rates are lacking. Our knowledge of these rates is based mostly on indirect, in vitro measurements. Recently we have developed an in situ, non-intrusive technique to directly measure the rate and efficiency by which an active suspension feeder removes (or discharges) substances from (to) the water it filters. The technique, termed “InEx”, is based on the simultaneous, pair-wise collection of the water Inhaled and Exhaled by the animal. The difference in the concentrations of a substance among a pair of samples provides a measure of the retention (or excretion) of the substance by the animal. Calculations of feeding (or excretion) rates are obtained by multiplying the concentration difference by pumping rate. The latter is concurrently measured by recording the movement of a dye front in a transparent tube positioned within the ex-current jet. An important quality of the InEx technique is the lack of any manipulation of the studied organisms thus allowing realistic estimates of the organism’s performance under natural conditions. Former work in tropical water had revealed novel aspects of suspension feeders’ nutritional ecology including the major role dissolved organic substances play in the diet of some reef sponges (Yahel et al. 2003, Limnology and Oceanography, 48, 141).
For the proposed work at Race Rocks we can foresee two phases:

I. Identifying target suspension feeding taxa
We will execute a field survey of common suspension feeders at Race Rocks. Targets groups include bivalves, ascidians, and sponges. SCUBA divers will sample the water inhaled and exhaled by the surveyed organisms to compare concentration changes of CDOM, DOC, bacteria, phytoplankton, other organic particles, plant nutrients, silica, and sediment grains. Sampling methods will include an Inherent Optical Properties sensor (IOP, providing both CDOM spectra, concentration and optical characterization of the particulate field), Laser In Situ Scattering instrument (LISST, providing measurements of particles concentration and size distribution), and discrete water samples (InEx). The discrete water samples will be analyzed using a high temperature total carbon analyzer, flow injection nutrient analyzer, and a flow cytometer. This sampling scheme will provide ‘snapshot’ information on the performance of individual organisms.

II. Continuous monitoring of individual ‘model’ organisms.
Longer term (hours to days) monitoring of organisms will provide a record of feeding and metabolic performance with respect to environmental parameters (e.g., current, light, ambient particles concentration, etc.). Our knowledge of such processes in the field is limited. Nevertheless, the few existing studies suggest that suspension feeder activity may undergo considerable diel shifts. Moreover, environmental variables such as food and sediment concentration are known to affect suspension feeder filtration rates. Multi-day instrumentation of individual suspension feeders will provide a continuous record of the material fluxes mediated by the animals. Two 16 MHz ADVs’ (Acoustical Doppler Velocimeters) will provide high frequency (~2 Hz) current and acoustical backscatter data. One ADV will sample the exhalant jet of the study animal while the other will sample the inhalant (ambient) water. Similarly, paired measurements of optical water properties will be obtained by slowly pumping small amounts waters through a 4 sensor array mounted on a nearby frame. The instrument array will include: LISST-100, IOP sensors (WetLabs ac-9, and Eco-VSF,) CTD, and a Seabird oxygen sensor. The latter will allow us to estimate respiration rate and to correlate it to measured material fluxes mediated by the studied organisms. An online video camera equipped with an infra-red light source will be used to monitor the immediate vicinity of the exhalant aperture to allow better interpretation of behavior related signals (e.g. the presence of predators or sediment resuspension events).

Target organisms will be carefully selected based on the results of the survey in phase I. A priori, plausible candidates for these experiments are sponges and large bivalves (e.g. Mytilus californicus). These animals possess a large ex-current aperture that allows easy instrumentation and previous studies suggest that they may be capable of removing large quantities of DOC from the water.

Note that the proposed work in absolutely non destructive and the studied animals will not be manipulated by any means.

 

SEE ALSO https://www.racerocks.ca/journey-middle-school-students-visit-race-rocks/
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Sea pen: Ptilosarcus gurneyi-The Race Rocks Taxonomy

(Ed Note: The scientific name at the start of the video is not correct.) The sea pen, Ptilosarcus gurneyi, is a colonial cnidarian in the same class as the anemone, the anthozoa. One polyp has been modified to form the body,  while the fringes of the “feather” contain numerous small feeding polyps. Typically we find it living in a mud/sand substrate. It is rare around Race Rocks. The only population we have found is this one with a few individuals occurring at 15 metres on the North-West corner of Great Race Island. Note the small burrowing tubeworms in the mud around the organism. This specimen was videoed by Wynne Lawrence and Jean-Olivier Dalphond, both students at the Lester B. Pearson College.

General Description:

The sea pen, Ptilosarcus gurneyi, is a colonial cnidaria in the same class as the anemone, the anthozoa. One polyp has been modified to form the body while the fringes of the “feather” contain numerous small feeding polyps.

Habital:

Sea pens are marine organisms: typically they are found living in a mud/sand substrate at least 3 inches (7.6 cm) deep. It is rare around Race Rocks, with a few individuals occuring on the North-West corner of Great Race Island. Note the small burrowing tubeworms in the mud around the organism.

Feeding:

The polyps feed on detritus, zooplankton (baby artemia), and possibly (according to The Reef Aquarium Vol. Two) phytoplankton.You should offer your Sea Pen Artemia nauplii, Daphnia, pulverized flake food, and detritus stirred up from the bottom of the tank.

Predator:

Predators of the sea pen are two nudibranchs, one the very large 3 inches(7cm) nudibranch, Armina californica and the other Mediaster aequalis, Rose Star Crossaster papposus and the Leather Star Dermasterras imbriacata.

Reproduction:

We don’t know the reproduction of sea pens whether by sexual or asexual means.

References:
http://www.fishroom.com/library/seapen.html
http://www.lanecc.edu/science/zonation/seapen.htm

Kingdom: Animalia
Phylum: Cnidaria
Class: Anthozoa
Subclass: Octocorallia
Order: Pennatulacea Verrill, 1865
Suborder :Subsessiliflorae
Family :Pennatulidae Ehrenberg, 1834
Genus:Ptilosarcus
species:gurneyi
(Ptilosarcus gurneyi)
Common name: orange sea pen

Return to the Race Rocks Taxonomy and Image Gallery

Other Members of the Class Anthozoa at Race Rocks.

 

taxonomyiconReturn to the Race Rocks Taxonomy
and Image File
pearsonlogo2_f2The Race Rocks taxonomy is a collaborative venture originally started with the Biology and Environmental Systems students of Lester Pearson College UWC. It now also has contributions added by Faculty, Staff, Volunteers and Observers on the remote control webcams. 

Original: Dec 2002, Joshua Columbus ( Burma) year PC yr 29).  

additions by G.Fletcher 2018

 

Albinism in The California Sea Cucumber

 

The Sea Cucumber Parastichopus californicus is normally a reddish-orange to brown color, although there is also a beige color phase with dark brown spots.( leucistic).  In the past year, 2 of these white variants have shown up near Race Rocks