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Bioluminescence

Oh they glow…

Kate collects the zooplankton off the ring net by rinsing it carefully with fresh sea water.
Kate collects the zooplankton off the ring net by rinsing it carefully with fresh sea water.Carlie Wiener/SOI

If you have not already become enamored by the beautiful and diverse marine zooplankton that we have been talking about over the past week, let me give you one more reason– they glow!

Well, some of them do at least, and one of the projects on this cruise has been to dig a bit deeper into discovering which types of zooplankton glow. This has been done through careful observation and documentation of glowing plankton, giving us some insight as to how and why these animals glow.

The essence of glow in the ocean

The zooplankton being examined on the R/V Falkor is just one subset of marine organisms that “glow.” The more that scientists study glowing life in the ocean, the more they learn about the diversity of marine species and how these animals use light to do things like attract mates, camouflage themselves, lure prey, and escape from predators.

Kate peers out from her homemade dark room to explore fluorescent zooplanton
Kate peers out from her homemade dark room to explore fluorescent zooplantonCarlie Wiener/SOI

Glow in the ocean falls into one of three categories: bioluminescence, phosphorescence and fluorescence. Bioluminescent organisms produce their own light generated by a chemical reaction, you might see this type of glow in a photo or video of certain deep-sea animals. Phosphorescence and fluorescence are distinct from bioluminescence in that these phenomena involve the transformation and re-emission of light, not the production of new light.  Phosphorescent and fluorescent molecules absorb light and then re-emit that light in a slightly different form (more specifically a different wavelength). Phosphorescent molecules and fluorescent molecules differ in the time-lag between when the light that excites the molecules is received and when the transformed light is re-emitted. The emission from phosphorescent molecules is slow – think of the glow-in-the-dark stars you may have had on the ceiling of your bedroom as a kid. These phosphorescent stickers have to be “charged up” with light and then they slowly emit a faint glow over an extended period of time.  Fluorescence differs from phosphorescence in that the transformed light is re-emitted almost instantaneously. Think about going “cosmic-glow” bowling and how your white socks glow under the black fluorescent light. To recap, bioluminescence is like running through the neighborhood at night with a glow stick, phosphorescence is the glowing stars on your bedroom ceiling and fluorescence is the glow of your socks at disco bowling.

Station ALOHA – A glowing review

At the microscope, the NightSea adapter kit allows us to employ the combination of a blue LED light and yellow barrier filter to examine fluorescent plankton in greater detail.
At the microscope, the NightSea adapter kit allows us to employ the combination of a blue LED light and yellow barrier filter to examine fluorescent plankton in greater detail.Kate Hanson

The process of finding these glowing organisms begins with a series of ring net tows, where a cone-shaped plankton net is used to sieve the water, concentrating the amount of zooplankton collected through the net. This net is specialized to gather these small aquatic creatures with mesh openings that are slightly smaller than the netting on a window screens in your home. The animals caught by the net are retained and removed at the end of the tow. For this project, it is important that the animals stay alive and in good condition after they come through the plankton net, so special care is used to handle the samples as gently as possible. We have to work quickly to dilute the concentrated samples of zooplankton by putting them into fresh seawater.

Fluorescent copepods photographed in a glass dish under white light (left) and under blue light with a yellow filter over the camera lens (right). Oh, they glow!
Fluorescent copepods photographed in a glass dish under white light (left) and under blue light with a yellow filter over the camera lens (right). Oh, they glow!Kate Hanson

The samples are distributed into buckets of seawater, and taken into the wet lab where we sort for glowing organisms. Luckily, we constructed a creative dark room on-board, so that we can scan for glowing organisms using a blue LED flash light. These lights have been designed for observing fluorescent organisms, and the blue light excites many of the fluorescent proteins and other fluorescent compounds found in marine organisms. Because the fluoresced light is much weaker than the blue light, we wear special yellow goggles that act as filters to block out the blue light, allowing us to see yellow, green, orange and red fluoresence. After a few hours of sorting, we concentrate the glowing organisms from the buckets into a few small containers. At the microscope, we use a similar combination of a blue light with a yellow filter to examine the collected glowing zooplankton in detail. Some of these animals are retained in small dishes of seawater to be imaged at the microscope, and the remainder are preserved for genetic analyses back at the lab.

It has been an exciting week of chasing the glow at sea. We have observed some interesting patterns of the glowing plankton across depths and various species within the plankton.  More work lies ahead, but for now this story of glowing plankton is more than just a flash in the pan, and who knows what  and we will discover next…..

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