Author: jillianj606

Even though it was the last day of my WEP, I still learned so much. Dr. Bermek and I had our usual morning meeting to discuss our plans for the day. We briefly talked about our gel from yesterday that unfortunately didn’t work, but that was what we were expecting. We decided to run an EtBr experiment that had been successful again because we wanted a better direct comparison. The samples we compared last time on the EM and on a gel were from different experiments, so this time, we prepared a larger amount of each sample so we could split them in half. We planned to analyze half the sample in the EM and half the sample on an Agarose gel to get the most accurate results. I was familiar with this experiment, and we already knew it worked, so it seemed to run very smoothly. I was also nice to have 7 days of experience under my belt. While Dr. Bermek was getting other things started, she had me add all the necessary ingredients to microfuge tubes. I added 50uL of Tris, 10uL of BSA, 25uL of NaCl, and varying amounts of water to each sample.

During the middle of the day, I presented what I had learned over my past two weeks the UNC Lineberger Cancer Center to four other people in the lab. It was a nice end to my wonderful two-week experience. I was happy to get feedback from Dr. Berkmek’s other collaborators.

After my presentation, there were still 30 minutes left before the end of the day. Dr. Bermek is a very hard worker, and she likes to take advantage of every minute she has, so we got right back to work. I started getting the grids ready so they could be drop spreaded and put into the EM. Once I was finished with that, I prepared my last Agarose gel with success! And just like that my work experience was over. It finished on a high note with a good presentation and a successful gel. I cannot even explain how much I learned by immersing myself in a lab setting. Although the experience was a little daunting at first, I am really glad I got this unique opportunity. I would like to thank Dr. Bermek for her continued patience as I was learning and making mistakes. Her warm personality is really what made this experience so enjoyable. I’m really thankful for all the lessons I got to learn, and I’m ready for summer!

The facinating -80 degree freezer

The EtBr samples I prepared

Our calculations and plans

The grids I prepared for the EM

Today was full of learning new techniques and exciting experiments. Dr. Bermek and I spent the first half of the morning discussing the experiments she still had to complete before her paper about the Herpes Simplex virus could be written. We decided to perform an experiment that could potentially lead to never seen before results. There is a shape of DNA that people have not been able to get, but with the protein UL8 we have been working with, Dr. Bermek wondered if this protein could help make the DNA shape because UL8 relaxes DNA and creates a nicked structure. Dr. Bermek wasn’t super optimistic we would get results but she wanted to try anyway. A large experiment like the one we were about to do calls for a lot of controls because, if it works, we want to make sure we know exactly what helped create the desired DNA shape. We set up 7 reactions that each included or didn’t include a specific ingredient. For example, one sample didn’t have UL8 but had UL30. The reason is because there has been speculation that UL30 might cause DNA to become nicked, so we wanted to have it as an option, but if it worked, we wanted to make sure that it was the UL30 protein that caused the DNA shape not the UL8.

Dr. Bermek had me make the master mix which is basically a large volume of ingredients that needed to be added to each reaction. It is used to save time and eliminate unwanted errors. I was happy she trusted me enough to make it. The timing of the preparation of the samples was overwhelming and difficult. We had four different timers going all for different things. We had to add specific ingredients to some of the seven samples but not others in addition to making sure the timing was perfect. Some samples had to be heated for five minutes others had to be heated for 30, and there were other parts of the experiment that required keeping a close eye on the time. Dr. Bermek and I had a good system going to help everything run smoothly. She would take the samples out the hot water bath and give them to me so I could pipette the ingredients in. She would then put the samples back in the hot water bath to continue heating them. While she was working with radioactive materials, I prepared two Agarose gels. I measured out the Agarose, added the TAE or TBE buffer, dissolved the Agarose for 2 minutes and 15 seconds, let the mixture cool, and then poured the gel liquid into the apparatus to let it settle. This time, Dr. Bermek loaded the samples into the gel because some of them were radioactive and required special precautions. I didn’t trust myself enough to load after we had spent about 3 hours preparing the samples.

While the gel was running we prepared grids for the EM that we would use tomorrow. When I first used grids last week, they were already prepared so I was glad I got to see the full process today. There was a special solution we poured over the mesh where our grids would be housed. Once the mesh was completely submerged in the liquid, we carefully placed the grids one by one on the mesh making sure they stuck. I got to help Dr. Bermek with this step, and I really liked the precise nature of it. Then came the coolest part: adding the Parlodion. Parlodion is used to coat the gel grids so they can be used in the EM. The coolest thing was when we added a few drops of it to the solution that the mesh was in, it created a rainbow colored layer over the grids. I was really fascinated.

By the time we had finished the UL8 experiment and set up the grids, they day was just about over. Even though we may not get the results that weren’t likely to happen, I’m excited to see what the gel image and EM show us tomorrow on my last day working with Dr. Bermek.

The gel that contains radioactive material getting run behind a protective shield.

Getting ready to add the Parlodion.

The cool rainbow effect of the Parlodion.

The Agarose gel I set up.

Our designed experiment plans for the day.

Day three was full of gels, gels, and more gels. I felt much more comfortable today due to my acquired knowledge about gels from biotech class. Even though I was familiar with the process for running gels, there were still some differences between our Biotech protocol and Dr. Bermek’s protocol which allowed for so much learning. Preparing the gels one on one also helped me learn and understand so many new things about them because I didn’t have any lab partners to rely on. I started the day similar to yesterday with a run down about the results from the experiments that were pending. Once I heard the results, we made a plan for today. The first thing we did was run a protein gel. I was vaguely familiar with this type of gel because of our recent fish project in biotech. I really enjoy Dr. Bermek’s warm and comforting personality. When I make a mistake she’s really nice about it. I really appreciate how she lets me feel like I’m involved with each experiment while giving me just the right amount of help I need.

First, I added 4 uL of 6x dye to tubes labeled 1-9. Then, I added 14 uL of each sample to the various tubes. Once the samples were ready to be loaded, she walked me through the process of setting up the protein gel. Unlike an agarose gel, the gel we used for protein electrophoresis was already prepared, so we didn’t have to pour it. We retrieved the ready-made gel from the refrigerator. We put on gloves for this specific gel because it needed to be handled with care. We took it out of its package and removed the sticky strip of plastic on the bottom or else the electric currents would not run through it. We also removed the comb from the top, so we could load the samples. Then, we placed the gel on one side of the tetra gel box. We made sure it was firmly placed into the gasket so there were no leaks. Parallel to the gel, we put a sheet of plastic so the liquid TBE buffer would be contained. When placing the piece of plastic I learned it was important to have the words “buffer dam” facing me. Dr. Bermek showed me some tricks when setting up the gel like putting it on the side closest to the edge of the gel box so the samples would be easier to load. Once we had the gel rig all set up, we placed it in the tetra gel box with the red cathode matching the red sticker on the box and the black anode matching the black sticker on the box. Once the whole box contraption was set up, it was time for loading the samples. I was extremely nervous because, for me, this was the hardest gel to load. The wells were so small and samples could easier drift into another well causing unwanted contamination. With Dr. Bermek’s wonderful teaching approach she showed me how to load the first three wells and then gave me a chance to do the last 7. I was doing okay on my first two, but when I got to the third one I didn’t place my pipette in at the right angle and some of my sample got into the next well. I informed Dr. Bermek of my mistake and she was really understanding a offered an easy fix. She pipetted out the contaminated well and finished loading the rest of the samples. Once they were all loaded, she turned on the electric currents. Unfortunately, 30 minutes later we saw the samples swimming in the buffer. We made a common mistake when turning on the electric currents because the black and red wires got mixed up. Since we realized 30 minutes into the gel being run, we couldn’t salvage the samples.

We repeated the experiment again, but this time, I did it all almost entirely by myself. I setup the gel rig and box under Dr. Bermek’s eye but I physically did everything. I then, repeated mixing 9 more samples, so they would be ready to load. I incubated them and spun them all by myself. Then while Dr. Bermek was checking on another gel. I loaded all 10 wells by independently with only a few small mistakes. I was very proud of myself. I won’t know until tomorrow how the gel turned out because it needed to be stained for a long time, but I’m hoping everything worked out well. Once we had finished repeating the protein gel, Dr. Bermek’s agarose gel she had done the night before had finished staining, and she showed me the results. The reason she did this gel was to compare the work I did with the electron microscope yesterday. She showed me the gel image and began explaining and annotating it. The first lane there was just plain DNA which was the control. It had a lower molecular weight, therefore it was super coiled. This gel confirmed our results we obtained from the electron microscope yesterday. The second lane contained the UL8 protein which relaxed the DNA therefore the band was at a higher molecular weight. The third band had UL8 and CIP. UL8 relaxes the DNA but CIP supercoils it, so the band had a lower molecular weight meaning the DNA was supercoiled showing us the CIP was working. The fourth lane had topoisomerase which again relaxes the DNA therefore the band was at a higher molecular weight; however, lane 5 did not produce results we wanted. Lane 5 had topoisomerase and CIP, but the band had a higher molecular weight meaning it was relaxed and not supercoiled even though CIP is supposed to super coil the DNA. We suspected that since the topoisomerase she used was a different brand than normal it might require more CIP than the UL8 needed. The next 6 lanes were treated with different amounts of UL8 which had all the bands at a lower and higher molecular weight meaning they were intermediate DNA (some parts supercoiled and some parts relaxed). It was cool to see what intermediate DNA looked like through the EM and on a gel. The last 5 lanes had topoisomerase and Ethidium Bromide. The topoisomerase relaxes the DNA whereas the Ethidium Bromide is supposed to super coil it, but again, our results didn’t quite match what we were expecting. I learned so much about the function different proteins have on DNA. It was cool to compare and contrast my findings on the EM and on Dr. Bermek’s gel. I like how in science you can do so many different tests and learn about the functions of things. After our day full of various gels, we topped it off setting up one more agarose gel to use for tomorrow. I really enjoyed today. I got to work with techniques I was familiar with, but still learn countless new things about gels. I also learned so much, just from, hearing about and annotating the gel image from yesterday. I don’t know what’s in store for tomorrow, but I can’t wait to get some of our results and continue preforming experiments.

 

Informative annotated Agarose gel.

Tetra gel box setup and ready to be run.

My beautifully loaded wells!

Our sad samples swimming in the buffer after our mistake.

Second times the charm! The correct box with the samples down at the bottom of the gel instead of floating in the buffer.

 

 

Day two was just as action packed as the first. The anticipation from the first day was slowing wearing off, and I felt ready to work. I started off the morning hearing about the results from the previous days experiments which led to the plan for today’s work. Almost immediately after my arrival, I headed into the EM (electron microscope) room with Dr. Bermek. I had gotten a taste of the EM yesterday, but today it was like I was eating a three course meal. Dr. Bermek loaded a grid which required lots of precise and intricate detail to move the spec sized grid, put it in the right place on the tip of a long metal wand looking piece of equipment, and put the wand shaped piece of metal into its correct spot on the EM. Since it took a little while to get loaded she showed me how to switch between the two computers in front of us which made my task a little more daunting because I had to worry about working with two different programs.

Once the EM, was loaded she showed me how to focus the beam – another tricky aspect of the EM. There were so many controls it felt like I was sending a space ship into outer space. She first showed me the magnification which was pretty self-explanatory except it worked in accordance with another control – the intensity. Whenever I changed the magnification I also had to change the intensity. I had to make sure not to move the magnification to quickly or too much or the beam would be too wide for the etched circle on the plate, and I wouldn’t be able to see anything. The next control she taught me was the one that allowed me to look at different parts of the grid. There was also a button called R1 which I would press when I was finished choosing the part of the grid I was looking at, and it moved the bottom of the plate upwards so I see the sample we were analyzing. The first sample we were looking at was the DNA which was the control. My job was to analyze the sample by counting the number of super coiled, relaxed, and “other” stands of DNA that appeared. After showing me the basics of the EM controls and the features on the computer, Dr. Bermek left me to count while she continued working on a different experiment. I was a bit hesitant when she left because I didn’t trust myself with a machine that costs more than college tuition, but she had set up everything so well I felt prepared, and I was very cautious. As one sample after another went by I felt more comfortable. I used a  handy counting machine that made the process a little easier because on some samples I was categorizing over 400 DNA strands. The hardest part was figuring out where I was on the sample because it all looked the same, and I didn’t want to accidently count a DNA strand twice. It was really neat to see up close what super coiled and relaxed DNA look like. Some grids had a UL8 protein while others had topoisomerase. The different solutions added caused the super coiled DNA (what its normally like) to become more open looking by uncoiling it.

Once I had finished counting the results from mini grids, Dr. Bermek asked me to drop spread some more grids. It made me feel really important because she left me to do it by myself while she worked on something else. I used the same technique from yesterday where I dipped each grids in various solutions and then immersed it in 75% ethanol for 30 seconds and then 80% ethanol for 45 seconds. Once I was done preparing the samples, we looked at a few more things through the EM, and just like that my second day was already over. It was super cool to work so closely and independently with a electron microscope, a piece of material super intricate but really useful. I was also glad I could help Dr. Bermek with the preparation for other experiments. It felt like I was really working in the lab. Day two was just as informative and action packed as the first. I can’t wait for tomorrow!

 

My handy dandy counting tool.

Examples of what some of the DNA strands I counted looked like.

My Drop Spreading layout.

Up-close example of the tiny grids after they were prepared.

 

My control panel for working and manipulating the EM.