Author Archives: Floyd A. Reed

Mosquito Busters!

This weekend I teamed up with Matt Medeiros to collect mosquitoes. We were looking for adult Culex and Aedes. Culex larvae are easy to find in large numbers but the adults are difficult to locate.  We did find a lot of Aedes albopictus and brought them back to the lab for dissection and DNA isolation.


Matt had a backpack vacuum to catch the adults. In the image above we are looking for mosquitoes resting on the walls in a tunnel system under Honolulu (the image is fuzzy because of the low light levels and being hand held). It is impossible to resist Ghostbusters coming to mind.

gbposterIn other, not unrelated, news we seem to have been too heavy handed with the tetracycline to clear Wolbachia from the mosquitoes. Most of the mosquitoes in the tetracycline cage died (presumably from the toxic effects of the antibiotic) and we did not recover any eggs.  We are trying again with a shorter term dose.

Wolbachia PCR and Sequencing

We need a source of Wolbachia for injection into the mosquitoes. Using primers from Simōes et al. (2011) Áki and Maria were able to get these PCR products.


The gel is shown sideways with shorter fragments to the left. Our white[1] stock of Drosophila melanogaster is positive for Wolbachia infection. The Oregon-R stock appears to be uninfected. The Culex mosquitoes collected locally here on Oʻahu also appear to be infected and give a double band. We submitted them for sequencing and the Culex sequence came back very messy---consistent with possible super infection of multiple strains. However, the Drosophila w[1] sequence was clear enough to get a basepair sequence.


Here is the full sequence we recovered.


This appears to be a Group A Wolbachia and is consistent with wMel.

Simōes, P. M., Mialdea, G., Reiss, D., Sagot, M. F., & Charlat, S. (2011). Wolbachia detection: an assessment of standard PCR protocols. Molecular Ecology Resources, 11(3), 567–572.

SEM sponge imaging

Michael Wallstrom and Áki Láruson made some scanning electron microscope images of a new species of marine sponge we are working on (it is associated with invasive algal mats here in Hawai'i). I can't resist sharing a few of them here but I am saving the best for the publication we are working on.


Above is the surface of the sponge. If you look closely you can see the tiny ostia pores in the surface.


A closeup on the ostia, one is in cross section to the interior of the sponge.


Above, you can see two types of cells inside the sponge. The choanocytes use flagella (the threads) to move water through the sponge and filter food particles out of the seawater; amoebocytes crawl around and transport nutrients to other cells (among other functions).


In the above image, at the highest magnification for these images, you can see bacteria that are living in the sponge. The spiral objects are spirochaetes; some of these cause diseases in humans like Lyme disease, syphilis, relapsing fever, and leptospirosis.

New fly head phenotype


An undergrad, Angelina Holcomb, is working on a telomere-aging genetics project in the lab. While setting up crosses she noticed an odd eye phenotype. The two flies at the top of the image have smaller eyes and disrupted head development, along with some other more subtle phenotypes, compared to their sibling controls at the bottom of the image.

EM Algorithm Haikus

In a graduate "Ecology & Evolution" class I am co-teaching this semester I, on a lark, asked the students to write a Haiku on the Expectation-Maximization (EM) algorithm.

I introduced it in class to talk about finding maximum-likelihood answers to some complex problems using a simple approach. Earlier I gave them some homework problems to find answers to by writing EM algorithms in R. We had a midterm exam coming up and there is not enough time in-class for the students to program a new algorithm in R for an exam question. Rather, I asked them to write a Haiku about it to see what they would write and if this gave me any insight into their understanding of the method. I like the results so much I am posting them here.

Data and a guess
Update guess with each cycle
Find the true value.

Hey, start with a guess
then plug it in again and again
and again and again, yay!

Just a few short steps
Almost silly how simple
We find the answer

Find Expectation:
Calculate the Maximum.

Looping, elegant
Throw your guess into the loop
And see what comes out

We must use a guess
As the change becomes smaller
We approach the truth

What is the best approach to address avian malaria in Hawai'i right now?

I started this lab blog in the interest of transparency, so that the public could see what we were doing. To that end I am putting down my recent thoughts about what we should/could be doing in the near future to address avian malaria and native bird conservation.

I have been to several meetings about Hawaiian forest bird conservation since I arrived in Hawai'i five years ago. I have talked to people that have been going to these same types of meetings for 25 years or longer. There is a frustration that has been communicated to me and that I am also sensing that at each meeting the urgency of doing something is discussed but that it doesn't translate into sufficient action in the field. (However, positive things have occurred such as establishing reserves, reforesting, and bringing some species into captive breeding programs, but these alone are not sufficient.) The birds have been going extinct for over a century and are continuing to be lost. In the next five to ten years, unless something changes dramatically, we will loose several additional species.

At this last meeting a person (I am not sure if they want to be identified here) spoke with emotion about the po'ouli (Melamprosops phaeosoma) which was lost in 2004. Part of the problems were egos, infighting, political maneuvering, and personalities that stood in the way of action. By the time it was decided that they should be brought into captivity it was too late.

I have been thinking critically about what I can do that would be most effective and most likely to succeed and to try to step back and ask, if as much ego, self interest, politics, and personalities were removed from the equation as possible, what approach suggests itself. I came here to Hawai'i with the idea of porting underdominance that we had engineered in fruit flies to (non-native introduced) Culex mosquitoes in order to transform the wild population to not pass on the parasite that causes avian malaria. I am still interested in doing this, but several things are making me question if this is the best course of action in the short term. Laven first proposed using cytoplasmic incompatibility (due to Wolbachia) to suppress wild populations in the 1960's and there have been successful applications of this. Other labs are working on using Wolbachia in insect pest management approaches in various ways. Because of this I have purposely steered clear of cytoplasmic incompatibility and tried to develop my own approach: both to create a new option that could be used and to not interfere with, crowd the field, or compete with other efforts.

However, it is now five years later and no one has (in the lab) a Wolbachia based option in Hawai'i. I have been trying repeatedly to raise funding from NSF and NIH in addition to other sources to conduct our underdomiannce work (as well as develop new sterile insect techniques), and have been unsuccessful (which is extremely personally frustrating). Writing these grant applications takes time and at this point they have only wasted time. I also have been working on several scientific publications but combined with my teaching load and committee work this also slows down what I could be doing in the lab. At the end of the day underdominance is a genetic modification, which may slow down regulatory approval and inhibit public acceptance and it is (probably) more technically challenging to engineer then a Wolbachia approach. Importantly, since I am having to pay for this out of pocket, with my own personal funds, it is also (probably) much cheaper to develop a Wolbachia based approach.

We have established a colony of Culex mosquitoes in the lab from local populations of Culex here in Hawai'i and have optimized our rearing technique. We have in-lab microinjection instruments and a technique optimized for Culex mosquitoes and have our injection survival rate up to 13% now. We also have Drosophila melanogaster, Drosophila simulans, and access to Hawaiian Drosophila; all as sources of various strains of Wolbachia. We can raise our Culex with tetracycline to remove their endogenous Wolbachia. Isolate Wolbachia from these other insects and inject it into our Culex. (Or just inject new Wolbachia---do we really need to clear the old Wolbachia first?) Then set up some crosses and test if the cytoplasmic incompatibility between the two types works and they do not have viable offspring. This is not a genetic modification in the sense of inserting new DNA sequences into the Culex nuclear genome, which may aide regulatory approval and public acceptance.

This could all proceed very quickly; especially if I take a temporary break from writing new grant applications and publications and stop all new projects (which sounds dangerously close to career suicide but I have tenure now so I might as well use it to get something done). I could then provide the mosquitoes to other labs here in Hawai'i for additional testing (I know Carter Atkinson is already interested in this approach and I asked him if he minded if I went ahead a tried to do this; he agreed and gave me the go ahead, which is great that we are already not conflicting with each other!) and ultimately this could be an option to use either alone or in combination with other techniques: releasing males with a different type of Wolbachia to mate with wild female Culex, so that there are no offspring, to suppress the population of mosquitoes in the next generation.