Tag: Excited

All good journeys come full circle. After a week of preparation and cell harvesting, Dr. Masoudi and I moved on to setting up column chromatography with nickel resin – the first task we undertook together when I came into the lab last Tuesday. We made some slight modifications to the overall procedure, but it began just as it had before when we transferred incubated flasks with E. Coli cells to smaller centrifuge containers. After we spun our 12 liters of cell/media mix, Dr. Masoudi and I poured out the unnecessary liquid remains, combined the leftover cells, and added in a buffer solution to both maintain pH and limit biological activity. What’s interesting about E. Coli cells, and something I had not registered when we first did this two weeks ago, is that these “gram negative” bacterial cells have two layers of membrane. The first, outermost layer contains a periplasmic interior that carries our precious protein, Nb6B9, in addition to thousands of minuscule nutrients. The second, interior layer more closely mirrors the cell membranes of eukaryotes, outlining a cytoplasm which has a DNA-filled nucleus. In order to break the periplasmic layer (and not disrupt the cytoplasmic layer), we initiated an “osmotic shock” that fills the periplasm of each cell with enough water to burst the outermost membrane, expose the protein while keeping the cytoplasmic layer intact (… theoretically). The violent rupturing of the cells was followed by another centrifuge session, where bottles of the broken cells were spun at 14,000 rpm for about twenty minutes. The intense pressure delivered by the high speeds was able to segregate the intact cytoplasmic layers from the disrupted periplasmic contents, meaning we had to take the soluble fraction (the liquid fraction) of the bottles to properly retrieve Nb6B9. Unfortunately, our soluble fractions were viscous. The only macro-molecule capable of making the solution viscous, according to Dr. Masoudi, is DNA, indicating that we had ruptured the cytoplasmic layers of some of the cells and made the extraction process a whole lot harder.

The list of things I absolutely despise is quite short: spiders, Sauron, Dreamworks’ Minions. But the one thing that always tops the list, the one thing that punctures my soul and leaves me dangling on a mountain of turmoil, the thing that casts an infinite shadow over everything that’s good and innocent in this world, is bleach. The lab had run out of clean spin-bottles for the centrifuge, and Dr. Masoudi assigned me the task of washing out some used bottles under a specific protocol. As you may imagine, the risk of bio-hazards in the lab is really high, and therefore the risk of contamination between experiments is also pretty high. Cleaning ordinary, 250mL spin bottles is no “scrub-a-dub-dub” and your done. It requires determination, perseverance, and grit. You really have to grab the bottle by its sides and scrub it with the force of a thousand pounds of pressure. In other words, I rinsed the bottle three times, soaked the bottles and their caps in a bleach bath, and used deionized water to eliminate any chance of cross-contamination. However, the bleach’s horrible stench made my five-minute job seem like an infinitely long ordeal, but in hindsight, it wasn’t all that bad.

Just like yesterday, I helped Dr. Li Yin out by washing some of her flasks and pipetting exact amounts of protein into a gel electrophoresis machine – the plastic contraption that divides proteins based on their molecular mass. It’s been a pleasure working with Dr. Li Yin so far, and I’m honored to have witnessed the phenomenal research that she and Dr. Masoudi are conducing to obtain the crystal structure of the beta-2 adrenergic receptor bound to our infamous protein, Nb6B9. I am looking forward to what the rest of summer has to offer!

The lab is a peculiar place. There are professors, doctors, graduate students, undergrads, and high schoolers that speed through the halls, joke around, and take the time to get to know one another. It took me two weeks to realize that it wasn’t only the chemistry in our compounds that made the science interesting – it was the chemistry between people too. The lab is a living, breathing place that depends on scientists and interns who are willing to make sacrifices for each other, who are willing to go extra lengths to not only be good researchers, but good humans as well. These past two weeks have been a formative experience for me, and although the research is overwhelming and engaging, I can’t wait to spend more time with the people that make it all possible.

Have you ever locked yourself in a freezer? Neither have I, but I imagine that it’s something like spending thirty seconds in the lab’s cold room. The microbiologists and chemists of the Lefkowitz lab need the cold room at temperatures near freezing to impede natural processes and preserve the trillions of proteins that line their metallic walls. Dr. Masoudi had to leave for a bit, so I spent the early morning reading up on G-Protein Coupled Receptors and helping Dr. Li Yin, Dr. Masoudi’s co-researcher. Dr. Li Yin was kind enough to let me do a majority of the hands-on work for her protein identification process, but this included heading into the cold room to occasionally refill the plastic column she uses for chromatography with a wash solution (it’s freezing in there). This form of chromatography works by employing an antibody that has a high affinity for the receptor that we want to extract. Everything else in the solution passes through the column without strongly interacting with the antibody in the resin. Eventually, Dr. Li Yin will pass a molecule through the same column that has an even stronger affinity for the antibody than our receptor, removing the receptor from the column. We also spent time grinding the cell membranes of moths – not something I thought I’d write in my lifetime. These moth cell-membranes hold the GPCR that we want, but in order to prepare them for filtration we need to homogenize the cell solutions and eventually mix them with some detergent. These soap molecules will act as a shield for the receptor, sustaining the structures for crystallization.

I also had the opportunity to make some stock solutions and use high-tech pipettes to deliver them into tiny aliquot containers. The LB media that I made is a combination of benzonase, a highly reactive enzyme, and protease inhibitor that prevents the denaturation of helpful cellular proteins. We soon moved on to her Western blots that showed the presence of a receptor using a set of primary and secondary enzymes. The secondary enzyme that was involved actually derives from rabbits! Another one of the enzymes she used was horseradish peroxidase that, yep, comes from horseradish.

A majority of the day was used gathering information to understand these receptors on a broader scale. Dr. Masoudi and I went over the sequence that some of these receptors undergo, from the moment an agonist – adrenaline, morphine, a photon – binds, to the recycling of these receptors in the lysosomes of cells. There’s quite a bit of literature on GPCRs, but barely any information on the mapping of these macro-molecules with X-Ray crystallography, and even less info on our synthetic protein Nb6B9 (FUN FACT: Nb6B9 was originally made from the antibodies of llamas).

Finally, Dr. Masoudi prepared our bacterial colony by taking a set of cells that (hopefully) incorporated the Nb6B9 gene into their DNA. We’ll know for sure that the gene was successfully incorporated after the DNA is sequenced by a lab at Duke, but for now we’re hoping that the colony we’ve set up will grow to produce as much Nb6B9 as possible. To avoid any fungal infections, Dr. Masoudi uses a lamp to ward off aerial imposters, but he also uses ethanol to clean the table. We really only realized how precarious the situation was after we had finished setting everything up.

Ever seen a tornado?

I’m ecstatic for my opportunity with Dr. Ali Masoudi!