Student Research

'09/'10 Research Students

James Chu

Ribosomes are the macromolecular machines responsible for making proteins in living cells. While ribosome function is well investigated, less is known about ribosome assembly and transport. Of the two subunits that join to form a mature ribosome, the export of the smaller 40s subunit is of particular interest to our research group. I am currently working on the ltv1 protein that is attached to the 40s subunit during export. By utilizing fluorescence microscopy and GFP hybrids, I hope to see the effects of ltv1 mutations on the export of 40s subunits in yeasts. 

Patricia Clevenger

This summer I used immunofluorescent techniques to study the intracellular localization of a recently discovered protein. This novel protein is generated by an alternative transcription start site within the ASPP2 locus. ASPP2 stands for Apoptosis-Stimulating Protein of p53-2 and is an important tumor suppressor frequently down-regulated in breast cancers. Upon response to DNA damage in healthy breast tissue, ASSp2 can contribute to a programmed cell death response which protects cells from accumulating harmful mutations. The new gene product I study is particularly intriguing as it is a truncated version of ASPP2. This difference in structure appears to affect its function as the protein is overexpressed at the mRNA level in breast tumors, suggesting that it promotes breast tumorigenesis and/or resistance to therapy. In the coming year, I will continue to examine the location of this potential oncogene in isogenic cell lines after exposure to different chemotherapeutic drugs.

Lindsay Hilken

My research is focused on the role of neuromodulatory proteins in  long-term memory formation. Specifically, I am studying two neuromodulatory proteins, tissue plasminogen activator (tPA) and brain derived neurotrophic factor (BDNF), that promote changes in synaptic strength and are necessary for the early stages of memory formation. Using fluorescence microscopy and live cell imaging, we are investigating presynaptic localization of BDNF and tPA localization and the requirements for their release from synaptic sites in hippocampal neurons. 

Aaron Kim

Spider venom is a complex mixture of small molecules, proteins, and peptides, many of which act as neurotoxins. Potential applications of venom peptides from other species, such as cone snails, have been shown in previous studies. Spider venom contains similar agents that could lead to the development of therapeutic drugs or biodegradable insecticides. I am currently working toward expressing and purifying a small toxin peptide identified from the venom glands of the spider species, Loxosceles hirsuta.  The eventual goal of the research is to determine the structure of this peptide using nuclear magnetic resonance spectroscopy.

Madison Kyger

I conduct my research at OHSU in the lab of Dr. David Farrell, whose work centers on the role of fibrinogen in blood coagulation and angiogenesis. Fibrinogen is the main structural protein involved in clot formation during coagulation. I'm currently investigating the roles of intron splicing and polyadenylation in the regulation of a variant form of fibrinogen, which is believed to arise from alternative splicing. This fibrinogen variant stabilizes fibrin clots and may therefore be a previously unrecognized risk factor for heart disease.

Travis Walton

My daily research experience consists of moving worms, allowing enough time for them to copulate before the males are killed, and then stealing their babies to examine new genetic combinations with a microscope. I use the model organism Caenorhabditis elegans, a small soil nematode, to investigate how the cell is organized into compartments. Specifically, I am studying the formation of a lysosome-related organelle called the gut granule. I am currently identifying and characterizing mutations that can restore compartmentalization when key components are disabled.

Zach Wilson

Spider venom contains hundreds of small peptides. Many of these peptides are neurotoxic and help the spider to capture prey and defend against predators. Furthermore, it has been shown that many of these peptides can act specifically against a wide range of neuronal targets. This diversity creates a potential library of small structures that could be utilized in the creation of pharmaceuticals or biodegradable insecticides. My research focuses on purifying a venom peptide isolated from a relative of the brown recluse spider, in order to determine the structure using solution-state nuclear magnetic resonance (NMR) spectroscopy.

'08/'09 Research Students

Steffen Bernard

Spider venom contains a diverse mixture of small proteins some of which have been shown to be highly specific to the targets with which they interact. Their high specificity makes them potential leads for biodegradable insecticides and pain relievers. I am currently working to generate and purify a sample of a toxin protein isolated from Loxosceles hirsuta, a relative of the brown recluse spider, in order to determine the structure using solution state nuclear magnetic resonance spectroscopy.

This fall, I will begin a PhD program in Chemical Biology at the University of Michigan and focus my studies on protein structure-function relationships and methods of protein structure determination.

Claire Fassio

I work in Deborah Lycan's lab, and we are interested in ribosome biogenesis. Ribosomes are the molecular machines within cells that are responsible for protein synthesis. I use genetics, fluorescent microscopy, and biochemistry to study nuclear export of the small ribosomal subunit in the budding yeast S.cerevisiae. 

I will be attending UC Berkeley in the fall to begin a PhD program in Molecular Biology.

Audrey Fulwiler

I am currently conducting research germane to the molecular and biochemical events that underlie long-term memory formation. In particular, my work is focused on a protein that plays a critical role in memory enhancement, brain derived neurotrophic factor (BDNF). Single amino acid polymorphisms of BDNF have been found to affect human memory by influencing the localization and secretion of BDNF. Utilizing live-imaging fluorescence microscopy and biophysical methods of analysis, I am studying the synaptic localization of BDNF and evaluating the dynamics of BDNF-containing granules at presynaptic sites in hippocampal neurons.

Isaac Holeman

I have been studying bakers yeast (S. Cerevisiae) in Lewis & Clark's Lycan lab for about three years. My current work explores how ribosomes, the large macromolecular machines that produce all protein, are exported from their place of birth in the cell nucleus to the cell fluid where protein is produced. My thesis research revolves around a single protein on the surface of the small subunit of the ribosome that appears to play a role in this process.

After graduation I will work for a year with MobilizeMRS.org, a venture that I founded to enable health workers in the most remote and overlooked communities to record medical data and perform $1 CD4 counts (CD4 count measures the progression of HIV), and send this data directly to a central electronic health record using mobile phones. At the end of this year I hope to attend medical school, and will pursue a career in academic medicine, global health, informatics, and social entrepreneurship.

Conor Jacobs

The capability of neural networks to change over time underlies many crucial processes in the brain, such as long-term memory formation in the hippocampus. These systemic changes result from many individual synaptic modifications, which are carried out by a class of secreted proteins known as neuromodulators. One of these neuromodulatory proteins, which is necessary for long-term memory formation, is known as tissue plasminogen activator (or tPA). tPA, a protease, is thought to promote synaptic modification through its ability to cleave other proteins. My current work utilizes cultured hippocampal neurons, molecular biological tools, and fluorescence microscopy to investigate the presynaptic secretion of tPA.

I will be pursuing a PhD in Biology at Stanford University.

Brian King

For my senior thesis I am studying the biogenesis of a specialized lysosome-related organelle, the gut granule, in C. elegans. Previous research in our lab identified a gene, glo-1, that is necessary for the formation of the gut granule. I am doing a genetic suppressor screen on glo-1 to identify other genes that are involved in the gut granule biogenesis pathway.

Next year I am attending UCSD medical school.

Rachel Kroencke

VGF is a protein that influences energy homeostasis and expression of this protein is upregulated during exercise. Recent work suggests that VGF is also implicated in learning and memory. I am working on a research project targeted at creating a DNA construct of VGF linked to a fluorescent marker protein EGFP. Once the construct is created we will determine where VGF is localized in neuronal cells and if it is copackaged with other key neuromodulatory proteins that facilitate long term memory formation.

Sage Coe Smith

I am currently researching the endosomal system within /Caenorhabditis elegans/ intestinal cells. I hope to elucidate the natures of several currently unclassified lysosome-like organelles. This will hopefully enhance the use of /C. elegans/ as a model system for the study of lysosomal storage diseases, inherited metabolic disorders caused by defects in lysosomes.