How to stop invasive algae from taking everything you love

By: Emily Ryznar

Hello everyone! My name is Emily, and I am a Ph.D. candidate in the Ecology and Evolutionary Biology Department at UC Los Angeles and a 2018 Graduate Fellow at the Wrigley Institute for Environmental Studies. I am interested in all things conservation, but particularly focused on the marine environment.

If you’re reading this, you and I hopefully share some interest in the ocean. Perhaps, like me, you enjoy spending more of your time below water than above it. Have you ever explored a giant kelp forest (see photo below) and met all of the colorful organisms that call it home? It is quite a transformative experience, and one of my favorites.


Sunlight peeking through a kelp forest canopy close to Wrigley Marine Science Center.

However, many ecosystems, including these beautiful kelp forests, are threatened by an alien invader - Sargassum horneri. S. horneri is a brown alga native to Japan and Korea that was transported (likely via human activity) from its native range to Long Beach Harbor, where it arrived in 2003. Since its arrival, S. horneri has rapidly spread up the coast towards Point Conception, throughout the Channel Islands, and south into Baja California. Where it is able to establish, S. horneri is capable of forming dense monocultures that are hypothesized to be outcompeting native algae for space and light, including the lovely giant kelp, triggering a cascade of negative impacts for organisms that call kelp forests home.

Recent attempts at eradicating already established populations of S. horneri have found that the invader actually bounced back with even more fervor post-removal, meaning that widespread eradication of populations that have existed for multiple generations is likely not feasible. However, removals may be more effective in recently invaded areas. Thus, these vulnerable communities should be targets for monitoring and control. Which leads me to my research!

Recruit Sargassum horneri (center) surrounded by other algae.

Recruit Sargassum horneri (center) surrounded by other algae.

One aspect of my dissertation is seeking to investigate factors that make communities more vulnerable or resistant to invasion. Previous research using long-term data from UC Santa Barbara found that communities that had a diverse algal community or had dense urchin populations were able to inhibit S. horneri from successfully invading due to intense competition or herbivory, respectively. Thus, my research is testing these conclusions in the field, as well as trying to figure out whether the same factors are at play on Catalina Island, where S. horneri has rapidly and widely established.

I currently have several study sites that vary in the important factors aforementioned to test the hypotheses that sites with strong competition (via algal diversity) and/or dense urchin populations (via herbivory) will be most resistant to the S. horneri invasion, while sites lacking those features will be the most vulnerable. I have deployed growth experiments with S. horneri at each site, with half of the experimental units in cages specially designed to prevent urchin herbivory while allowing other types of herbivory to occur.

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Photos of my experimental units, with uncaged S. horneri (left) and caged S. horneri (right) with some curious garibaldi.

Comparing growth inside and outside these cages will help me determine the strength of urchin herbivory at each site as well as the influence of competition. I expect S. horneri will grow the most at the most vulnerable sites, and the least at the most resistant sites, and I am excited to see the results!

I spend a good amount of my time in/on the water to conduct this research, sometimes completing up to 8-9 scuba dives per day. Many times, these dives are short, often to clean the cages of any fouling with a nifty scrub brush and make sure the algae are happy. While not super exciting at times, I wouldn’t trade it for anything. I hope my research will provide insight into factors controlling or facilitating the success of the S. horneri invasion and inform management as to which types of vulnerable communities to monitor so S. horneri doesn’t proceed to take over the world, or at least the rocky reefs of Southern California!

Special thanks to the Wrigley Institute for giving me the incredible opportunity to conduct this research, and all the dive/waterfront/lab/advising help I’ve received for this project. Feel free to contact me at with any questions. Stay soggy!


Me, almost always soggy. Photo credit: Dena Decker.

Summer = Sunshine = Solar Energy for Microbes!

By: Babak Hassanzadeh

Hi everyone! My name is Babak and I’m a third year PhD student at USC’s Marine Biology and Biological Oceanography program. As you may have already guessed from the title of my blog, I study antennae that microbes use to capture solar energy. Another word for these antennae is pigments.

Pigments are embedded in cells’ photosystems and allow them to convert sunlight into biologically useful energy. You may have heard of chlorophyll a (chl a), the pigment that makes most terrestrial plants green. It allows them to make sugars from CO2 and creates oxygen for other organisms to breathe (photosynthesis). This same pigment, chl a, is responsible for photosynthesis in the open ocean which is primarily carried out by single cell organisms (bacteria and phytoplankton). Interestingly, about half of the oxygen that exists in our atmosphere comes from these microscopic organisms in the ocean!


Another pigment that I study for my research is actually more abundant than chlorophyll in marine bacteria! It is called Proteorhodopsin (PR, figure 1) and was unknown of in marine systems until the year 2000! Over 80% of all bacteria have the gene for PR and they can use it to capture light from the sun and make ATP for their cellular needs. PR is a much less studied pigment compared to chlorophyll and one of the main goals of our lab and my PhD dissertation is to quantify the abundance of this pigment in different marine regimes and investigate the environmental factors that control its distribution.


My goal this summer was to study day-night (diel) cycles of pigment concentrations offshore Catalina Island. This is important since no such data exists for Proteorhodopsin and we don’t know whether the pigment persists through the night or “sleeps”. I am grateful to be awarded the Wrigley fellowship this year through the Wrigley Marine Science Center (WMSC) which allowed me to conduct research on Catalina Island, where there ocean and lab space coexist. For my fieldwork, I sampled seawater through diel cycles once in the spring (June 1-3) and once in the summer (July 31- Aug 2). The seawater was sampled off the dock at WMSC every 4 hours for a 60-hour interval (Figure 2).


After collecting the microbial biomass, I used a new analytical method developed in our lab at USC’s main campus to extract and quantify the PR pigment using ‘liquid chromatography tandem mass spectrometry’. The results show that surprisingly PR is detected through both day and night sampling time-points. Additionally, variations of pigment concentrations between the two sampling seasons are more significant than within a diel cycle of a given sampling period. These results suggest that the composition of the microbial community (diversity and absolute abundances of microorganisms) may be the more important factor in shaping pigment concentrations.

My results provide insights into the role of factors such as sunlight, synthesis, and degradation in controlling pigment abundances and distributions. Stay tuned for more fieldwork and analyses of my research!