WA Marine Science Strategy achieves unprecedented collaboration

Western Australia’s marine science, government, industry, conservation and community sectors met at the inaugural Blueprint for Marine Science Forum in Perth to begin building an Australian-first collaboration around marine science.

For more information, click the following link: http://www.marinescienceblueprint.org.au/latest-progress/wa-marine-science-strategy-achieves-unprecedented-collaboration

Karratha and Exmouth consulted on decommissioning

Adele found to host one of the more unique reef habitats on the planet

A geomorphological and geophysical investigation of Adele Island has revealed new insights into the long-term evolutionary history not only of Adele Reef but also of Australia’s North West Shelf.

The mid-shelf Adele platform reef sits between the atoll type Scott Reefs, which are located on the very edge of the North West Shelf, and the highly atypical inshore fringing reefs of the Bucaneer Archipelago.

This reef is of scientific interest because it provides an environmental link between the Kimberley’s oceanic and inshore reef systems.

 

The findings by Curtin University graduate students Tubagus Solihuddin and Giada Bufarale have been published in the Journal Geo-Marine Letters as part of the Western Australian Marine Science Kimberley Marine Research Program.

Geophysical surveys showed that the Adele reef structure did not form exclusively during the Holocene, which is the current period of geological time that started some 11,500 years ago when the glaciers began to retreat. It is in fact made up of layers of different aged reef packages that grew during previous sea level highstands (intervals where sea level lies above the continental shelf edge).

 

Rollolith habitat on the southern Adele Reef consisting of both coralline algae (rodoliths) and corals (coraliths)

 

By counting these packages back in time, researcher Giada Burfarale was able to calculate that coral growth at the site of Adele reef first began over 400,000 years ago. Interestingly this is also believed to be a time when coral growth first initiated on the Great Barrier Reef.

“Geophysical surveys also revealed a series of 90 metre deep channels around Adele reef that most likely represent ancient channels cut by the Fitzroy, Isdell or Prince Regent rivers which flowed across the continental shelf during sea level lowstands (times when sea levels were at their lowest),” Co-author Curtin University Dr Mick O’Leary said.

“Also, by comparing geophysical data with stratigraphic reef core data from Scott Reefs and the inner fringing reefs it was possible to calculate that the North West Shelf has subsided more that 30 metres over the last 100,000 years, making it one of the more tectonically mobile regions on the Australian continent,” Dr O’Leary said.

The modern Adele Reef is characterised by having one of the more unique reef habitats on the planet. Earlier investigations by the Western Australian Museum reported the discovery of a unique ‘rollolith’ habitat located along the SW side of the island. Rollolith is the common name given to benthic organisms that grow as unattached free-living spherical colonies enabling live tissue to cover the entire colony surface.

Percussion coring the Adele Island sand spit using an Atlas Copco post driver

 

Reef coring by Tubagus Solihuddin and the team found that this is a relatively recent habitat, forming only as the Adele reef platform reached present sea level, less than 1000 years ago. The resulting increase in surface currents are driven by seven metre tides and large waves which wash across the reef platforms at high tides.

“So what we have found is, rather than observing a style of reef geomorphology that gradually transitions between the atoll style oceanic Scott Reefs and the atypical high fringing reefs on the inner Kimberley, the mid-shelf Adele reef is characterised by its own unique structure, habitats and growth history,” Dr O’Leary said. “These findings provide yet more evidence of just how globally unique the Kimberley reefs are.”

 

Links:

Solihuddin, T.,  Bufarale, G., Blakeway, D., O’Leary, M.J., (2016) Geomorphology and Late Holocene Accretion History of Adele Reef: a Northwest Australian Mid-Shelf Platform Reef, Geo-Marine Letters, 2016, 1–15. DOI: 10.1007/s00367-016-0465-3

 

The $30 million Kimberley Marine Research Program is funded through major investment supported by $12 million from the Western Australian government’s Kimberley Science and Conservation Strategy co-invested by the WAMSI partners and supported by the Traditional Owners of the Kimberley.

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Kimberley Marine Research Program

Genomic insights into ecological connectivity in the Kimberley

WAMSI Kimberley Research Program scientists, Dr Oliver Berry (CSIRO), Dr Jim Underwood (AIMS) and Dr Kathryn McMahon (ECU) presented their findings at the Department of Parks and Wildlife on a study looking into the movements of animals and plants among Kimberley reefs.

The research, part of a larger collaboration involving CSIRO, the Australian Institute of Marine Science, Department of Fisheries, Curtin University, Edith Cowan University and the WA Museum, investigated seven organisms that represent common species (two hard corals, two seagrasses, a mollusc and two fishes) to infer the routine distances of dispersal and patterns of connectivity among key populations within the Kimberley.

CSIRO researcher Dr Oliver Berry explained the team looked at fine scale and broad scale patterns, including movements between the Kimberley and other regions such as the Pilbara, using genomics to investigate connectivity.

“Many marine organisms are transported a long way by ocean currents when they are microscopic plankton,” Dr Berry said. “Their movements are hard to track and so we use genomics to measure the relatedness of organisms on different reefs, and from this we can indirectly estimate how far they have moved.”

From this research the team uncovered the location of barriers, important stepping stones and transitional zones for a number of the species investigated. The findings provide important information for the design of marine protected area networks in the Kimberley and the management of commercial fish stocks such as the Trochus.

“It has been very satisfying and exciting to work together as a team to synthesis our new knowledge on the genetic connectivity of marine organisms in the Kimberley,” co-researcher ECU’s Dr Kathyn McMahon said. “I look forward to seeing this information incorporated into future management and conservation of this special region.”

A copy of the presentation given by the team on 15 August 2016 and a project summary is available at http://www.wamsi.org.au/research-site/ecological-connectivity.

 

The $30 million Kimberley Marine Research Program is funded through major investment supported by $12 million from the Western Australian government’s Kimberley Science and Conservation Strategy co-invested by the WAMSI partners and supported by the Traditional Owners of the Kimberley.

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Kimberley Marine Research Program

Vale Steve Blake

It is with great sadness that we mourn the passing of the Western Australian Marine Science Institution’s (WAMSI) inaugural Chief Executive Officer, Dr Steve Blake.

Steve graduated with first class honors in Geology from the University of Edinburgh before moving to Australia in 1987. He undertook his PhD in marine geology at James Cook University, studying the Great Barrier Reef. Steve worked in various positions in Canberra before moving to Western Australia to join WAMSI as its first Chief Executive Officer.  

Steve joined WAMSI in 2006 and managed the organisation from its inception until 2012.  Steve particular enjoyed working with Indigenous groups in the northwest of WA and eventually left WAMSI to work with Ninti One to further build opportunities for people in Indigenous communities in remote Australia.

On behalf of all of us at WAMSI, we thank Steve for his enduring contribution to marine science and offer our sincere condolences to Janine and their three lovely daughters, of whom Steve was so proud.

New tool to forecast atmospheric and ocean conditions on the west coast

The Coastal Oceanography Group at The University of Western Australia has been developing a numerical system to provide atmospheric and ocean forecasts for five days in advance. 

The forecasts include five regions along the coast of Western Australia: west coast (North-west Cape to Cape Leeuwin), central coast, Shark Bay, south-west and Perth. Perth is on a higher resolution nested grid.  The dates are also in a drop down menu.

The URL is: http://anfog.ecm.uwa.edu.au/Model/model.php

The forecasts include Atmospheric (winds, air pressure, rainfall) and ocean (currents, sea surface temperature and salinity).

Project leader, Professor Charitha Pattiaratchi said the forecasts provide a very high resolution view of the ocean and atmospheric conditions – on a regional basis. 

“They add-value to the Bureau of Meteorology forecasts,” he said. “This will be a valuable source of information to people who use the local marine environment including recreational and professional fisherman, scientists planning field work.  The forecasts are also archived so we can go back in time and extract historic conditions.”

Hats off to sea turtles

By Kandy Curran

With sea turtles revered by cultures across the world, it was a privilege to have Yawuru Ranger Preston Manado open the Science on the Broome Coast presentation, Sea Turtles:  Iconic ambassadors linking marine habitats, cultures and regions in north-western Australia on June 8, 2016. 

Preston began by explaining the significance of the six Yawuru saltwater seasons – starting with the Laja and Man-gala seasons when the gurlibil (Flatback turtle – Natator depressus) lay their eggs on Broome’s beaches.  The eggs of the gurlibil will hatch approximately 55 days after nesting.

“Gurlibil is out to sea during the colder months of Barrgana, which we are having now. During Wirlburu, the warming up season when the westerly winds start to blow, Gurlibil start mating and shouldn’t be disturbed.” Preston Manado said.

The next presenter, Dr Scott Whiting, who is the Principal Research Scientist with Parks and Wildlife in Perth, focused on the biology of sea turtles, the threats that they are facing – particularly from climate change, and research underway on the Kimberley coast.

Dr Whiting had the audience ‘taking their hats off’ to sea turtles, with their biology and evolutionary history so amazing.

“Sea turtles, which can weigh from 30kg to 600kg, frequently dive to depths of 100m, with some species diving to as deep as 1000m.  The length of time they take to reach puberty (30 to 50 years) and their long breeding histories (over 30 years), is extraordinary too, as it means that conservation initiatives have to be considered in terms of decades and centuries.” Dr Whiting said. 

A wandering microphone allowed the large audience of 76 to ask a stream of great questions. For example, the question of how turtles mate, revealed that female sea turtles are promiscuous and can be mated by several males, resulting in several fathers of the egg clutch.  The next question – where are the most species of sea turtles found, delighted the Broome audience, with Roebuck Bay identified as an embayment visited by at least five species of sea turtles, with the Green turtle (Chelonia mydas) most dominant, and Flatback turtles the species nesting on Broome’s beaches.  We also learned that whilst turtles have small brains, they have evolved with special ‘homing’ abilities, which will see them return when they reach puberty, to precisely the same beach where they hatched from 30 to 50 years ago.

The big question however is, will sea turtles, which evolved 200 million years ago, adapt quickly enough to cope with a rapidly changing climate and a world that is overpopulating?

The next Science on the Broome Coast presentations are Corals, canaries and cockroaches: A natural history of coral reefs on June 29, followed by Lustre: The allure of mother of pearl crosses time and cultures on July 6 – both at the University of Notre Dame Multipurpose Hall in Broome.

This innovative Science on the Broome Coast series is sponsored by Inspiring Australia, The University of Notre Dame Broome, Yawuru Land and Sea Unit, Western Australia Marine Science Institution, Rangelands NRM through the Federal Government Landcare Program and the Department of Parks and Wildlife.

See the 2016 Science on Broome Coast program and posters for each presentation »

The $30 million Kimberley Marine Research Program is funded through major investment supported by $12 million from the Western Australian government’s Kimberley Science and Conservation Strategy co-invested by the WAMSI partners and supported by the Traditional Owners of the Kimberley.

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Kimberley Marine Research Program

Discovering the Tiny Creatures that Live in Marine Plants

BY Angela Rossen

If you go for a snorkel near the shore you will find meadows of gently swaying seagrasses and rocky reefs with brightly colored algae that are often called seaweeds. Among these swaying leaves and algal fronds live myriads of tiny creatures. Marine plants act as nurseries, providing shelter and food for almost all our marine species at some time in their lives. 

Finding the tiny sea ‘insects’, which are known as macro invertebrates is always exciting. These little creatures feed on the soft algae, and seagrass leaves and on the harder chalky coralline algae that grow on seagrass. They also eat plankton and occasionally they eat each other. In turn, they are delicious morsels for tiny fish and crustaceans that are then food for larger fish and shore birds.

The next time you come to the beach bring a small white bucket (to let in the light) and a magnifying glass. Make sure your bucket is clean with no residue of paint or cleaning chemicals. Fill it with fresh seawater. Find a wire-weed seagrass stem with a fringe of red brown algae and place it gently in your bucket without shaking and add a couple of branches of some leafy seaweed. If you wait for a moment you will notice lots of tiny creatures zipping around.
 

Geraldton Grammar students discovering macro invertebrates (A.Rossen)

You are likely to find amphipods, tiny prawn like animals and bristle worms, flatworms, and transparent or green shrimp. You may be lucky enough to find an anemone larvae or a sediment (sand) worm with waving tentacles and external gills that look like soft antlers. Some tiny invertebrates also make tunnels in seagrass leaves and live within those very narrow spaces. Also attached to seagrass leaves are minute spiral tube worms with delicate transparent feeding arms that comb through the water to catch floating bits of food. Try to get some good photos with your phone camera before you carefully return these treasures to the ocean.
 

Amphipod on seagrass (A. Rossen)

All these plants and creatures are perfectly adapted to their environment and are very sensitive to poisonous pollutants that enter the ocean. For example, road water drains are designed to divert stormwater into rivers and to the seashore. Unfortunately they also bring rubbish, fertilizers from gardens and other pollutants from the roads.  Remember these tiny creatures when you fertilize your garden and always dispose of liquid waste and rubbish correctly.

Angela Rossen is Artist in Residence with The Oceans Institute at The University of Western Australia

Related links:

If you want to find out more about the tiny creatures that live in the marine plants call Angela Rossen to talk about a Coastal Biodiversity Art Workshop with your community or school group visit www.angelarossen.com

Perth Science Festival

World Biotech Tour.