Serial femtosecond crystallography (SFX) with X-ray free electron lasers (XFELs) has enabled the determination of damage-free protein structures at ambient temperatures and of reaction intermediate species with time resolution on the order of hundreds of femtoseconds. However, currently available XFEL facility X-ray pulse structures waste the majority of continuously injected crystal sample, requiring a large quantity (up to grams) of crystal sample to solve a protein structure. Furthermore, mix-and-inject serial crystallography (MISC) at XFEL facilities requires fast mixing for short (millisecond) reaction time points (𝑡"), and current sample delivery methods have complex fabrication and assembly requirements.

To reduce sample consumption during SFX, a 3D printed T-junction for generating segmented aqueous-in-oil droplets was developed. The device surface properties were characterized both with and without a surface coating for improved droplet generation stability. Additionally, the droplet generation frequency was characterized. The 3D printed device interfaced with gas dynamic virtual nozzles (GDVNs) at the Linac Coherent Light Source (LCLS), and a relationship between the aqueous phase volume and the resulting crystal hit rate was developed. Furthermore, at the European XFEL (EuXFEL) a similar quantity and quality of diffraction data was collected for segmented sample delivery using ~60% less sample volume than continuous injection, and a structure of 3-deoxy-D-manno- octulosonate 8-phosphate synthase (KDO8PS) delivered by segmented injection was solved that revealed new structural details to a resolution of 2.8 Å.

For MISC, a 3D printed hydrodynamic focusing mixer for fast mixing by diffusion was developed to automate device fabrication and simplify device assembly. The mixer was characterized with numerical models and fluorescence microscopy. A variety of devices were developed to reach reaction intermediate time points, 𝑡", on the order of 100 – 103 ms. These devices include 3D printed mixers coupled to glass or 3D printed GDVNs and two designs of mixers with GDVNs integrated into the one device. A 3D printed mixer coupled to a glass GDVN was utilized at LCLS to study the oxidation of cytochrome c oxidase (CcO), and a structure of the CcO Pr intermediate was determined at 𝑡" = 8 s.

All organisms need to be able to sense and respond to their environment. Much of this process takes place via proteins embedded in the cell membrane, the border between a living thing and the external world. Transient receptor potential (TRP) ion channels are a superfamily of membrane proteins that play diverse roles in physiology. Among the 27 TRP channels found in humans and other animals, TRP melastatin 8 (TRPM8) and TRP vanilloid 1 (TRPV1) are the primary sensors of cold and hot temperatures, respectively. They underlie the molecular basis of somatic temperature sensation, but beyond this are also known to be involved in body temperature and weight regulation, inflammation, migraine, nociception, and some types of cancer. Because of their broad physiological roles, these channels are an attractive target for potential therapeutic interventions.

This dissertation presents experimental studies to elucidate the mechanisms underlying TRPM8 and TRPV1 function and regulation. Electrophysiology experiments show that modulation of TRPM8 activity by phosphoinositide interacting regulator of TRP (PIRT), a small membrane protein, is species dependent; human PIRT attenuates TRPM8 activity, whereas mouse PIRT potentiates the channel. Direct binding experiments and chimeric mouse-human TRPM8 channels reveal that this regulation takes place via the transmembrane domain of the channel. Ligand activation of TRPM8 is also investigated. A mutation in the linker between the S4 and S5 helices is found to generally decrease TRPM8 currents, and to specifically abrogate functional response to the potent agonist icilin without affecting icilin binding.

The heat activation thermodynamics of TRPV1 are also probed using temperature-controlled electrophysiology. The magnitude of the gating enthalpy of human TRPV1 is found to be similar to other species reported in the literature. Human TRPV1 also features an apparent heat inactivation process that results in reduced heat sensitivity after exposure to elevated temperatures. The work presented in this dissertation sheds light on the varied mechanisms of thermosensitive TRP channel function and regulation.

Rubisco activase (Rca) from higher plants is a stromal ATPase essential for reactivating Rubiscos rendered catalytically inactive by endogenous inhibitors. Rca’s functional state is thought to consist of ring-like hexameric assemblies, similar to other members of the AAA+ protein superfamily. However, unlike other members, it does not form obligate hexamers and is quite polydisperse in solution, making elucidation of its self-association pathway challenging. This polydispersity also makes interpretation of traditional biochemical approaches difficult, prompting use of a fluorescence-based technique (Fluorescence Correlation Spectroscopy) to investigate the relationship between quaternary structure and function. Like cotton β Rca, tobacco β Rca appears to assemble in a step-wise and nucleotide-dependent manner. Incubation in varying nucleotides appears to alter the equilibrium between varying oligomers, either promoting or minimizing the formation of larger oligomers. High concentrations of ADP seem to favor continuous assembly towards larger oligomers, while assembly in the presence of ATP-yS (an ATP analog) appears to halt continuous assembly in favor of hexameric species. In contrast, assembly in the “Active ATP Turnover” condition (a mixture of ATP and ADP) appears to favor an almost equal distribution of tetramer and hexamer, which when compared with ATPase activity, shows great alignment with maximum activity in the low µM range. Despite this alignment, the decrease in ATPase activity does not follow any particular oligomer, but rather decreases with increasing aggregation, suggesting that assembly dynamics may regulate ATPase activity, rather than the formation/disappearance of one specific oligomer. Work presented here also indicates that all oligomers larger than hexamers are catalytically inactive, thus providing support for the idea that they may serve as a storage mechanism to minimize wasteful hydrolysis. These findings are also supported by assembly work carried out on an Assembly Mutant (R294V), known for favoring formation of closed-ring hexamers. Similar assembly studies were carried out on spinach Rca, however, due to its aggregation propensity, FCS results were more difficult to interpret. Based on these findings, one could argue that assembly dynamics are essential for Rca function, both in ATPase and in regulation of Rubisco carboxylation activity, thus providing a rational for Rca’s high degree of polydispersity.

The fundamental photophysics of fluorescent probes must be understood when the probes are used in biological applications. The photophysics of BODIPY dyes inside polymeric micelles and rhodamine dyes covalently linked to proteins were studied. Hydrophobic boron-dipyrromethene (BODIPY) dyes were noncovalently encapsulated inside polymeric micelles. Absorbance and fluorescence measurements were employed to study the photophysics of these BODIPY dyes in the micellar environments. Amphiphilic polymers with a hydrophobic character and low Critical Micelle Concentration (CMC) protected BODIPYS from the aqueous environment. Moderate dye loading conditions did not result in ground-state dimerization, and only fluorescence lifetimes and brightnesses were affected. However, amphiphilic polymers with a hydrophilic character and high CMC did not protect the BODIPYS from the aqueous environment with concomitant ground-state dimerization and quenching of the fluorescence intensity, lifetime, and brightnesses even at low dye loading conditions. At the doubly-labeled interfaces of Escherichia coli (E. coli) DNA processivity β clamps, the interchromophric interactions of four rhodamine dyes were studied: tetramethylrhodamine (TMR), TMR C6, Alexa Fluor 488, and Alexa Fluor 546. Absorbance and fluorescence measurements were performed on doubly-labeled β clamps with singly-labeled β clamps and free dyes as controls. The absorbance measurements revealed that both TMR and TMR C6 readily formed H-dimers (static quenching) at the doubly-labeled interfaces of the β clamps. However, the TMR with a longer linker (TMR C6) also displayed a degree of dynamic quenching. For Alexa Fluor 546 and Alexa Fluor 488, there were no clear signs of dimerization in the absorbance scans. However, the fluorescence properties (fluorescence intensity, lifetime, and anisotropy) of the Alexa Fluor dyes significantly changed when three methodologies were employed to disrupt the doubly-labeled interfaces: 1) the addition of sodium dodecyl sulfate (SDS) detergent to denature the proteins, 2) the addition of clamp loader (γ complex) to open one of the two interfaces, and 3) the use of subunit exchange to decrease the number of dyes per interface. These fluorescence measurements indicated that for the Alexa Fluor dyes, other interchromophoric interactions were present such as dynamic quenching and homo-Förster Resonance Energy Transfer (homo-FRET).

This study was conducted to understand the reactivity of APE1 in repairing abasic sites associated with clustered DNA damages and to determine if the efficiency of APE1 enzyme is affected by the type of bases (purines or pyrimidines) neighboring the AP site. DNA damages are always occurring in living cells and if left uncorrected can lead to various problems such as diseases and even cell death. Cells are able to recognize and correct these DNA damages to prevent further damages to the genome, and the Base Excision Repair (BER) pathway is one of the mechanisms used in repairing DNA damages. A former student in the Levitus Lab, Elana Maria Shepherd Stennett, henceforth referred to as Elana worked on this project. She observed that the activity of the APE1 enzyme increased some when the base opposing the abasic site was changed from thymine (T) to adenine (A) while no difference was observed when the surrounding bases were changed. Thus, this experiment was conducted to further study the results she obtained and to possibly validate her findings. The AP sites used in this study are natural abasic sites created by UDG glycosylase enzyme from a double stranded uracil-containing DNA samples ordered from IDT technologies. Each reaction was carried out at physiological temperature (37degrees Celsius) and analyzed using polyacrylamide gel electrophoresis.

V(D)J Recombination is the mechanism responsible for generating diversity in the repertoire of antigen receptors of T and B cells. This recombination process proceeds in two steps: site-specific cleavage mediated lymphocyte-specific recombinase known as Recombination Activating Genes 1 and 2 complex (RAG) at the junction of coding gene segments and their flanking recombination signal sequence (RSS) and then followed by rejoining of the double strand broken DNA by the non-homologous end joining (NHEJ) complex. Mutations and truncations of the RAG-recombinase have been found associated with genomic instability and chromosomal translocation. It has been hypothesized that these RAG mutants may have abnormality in their interactions with recombination intermediates, ultimately causing premature release of the ends for aberrant joining. Additionally, these mutations have an increase in targeting non-B type DNA instead of legitimate recombination substrates that contain RSSs. To directly test these hypotheses, we have developed a fluorescence-based detection system to monitor in real time the recombination cleavage reaction from the pre-cleavage to the post-cleavage stages and to compare RAG-DNA interactions between wild type and mutant RAG1/2 during this process. Our study provides important insight into the ability of the C-terminus of RAG to regulate RAG recombinase activity.

Rubisco is a very important protein which catalyzes the addition of CO2 to ribulose-1,5-bisphosphate (RuBP) to form two molecules of 3-phosphoglycerate in photosynthesis. Rubisco activase is the protein which functions to uninhibit Rubisco, however proof of a physical interaction has never been shown. A possible method for determining the interaction of the two proteins is by Förster Resonance Energy Transfer (FRET) based analysis of the two proteins. Attempts to get a FRET signal from these two proteins have been unsuccessful. To get better results, Ficoll 70, a crowding agent, was used. Analysis suggests that Ficoll 70 does not affect the fluorescence of Alexa-fluor 488 and Alexa-fluor 647 used to label the two proteins. Further analysis also suggests that while the Alexa label on Rubisco activase does not affect the ATPase activity of the protein, the protein also does not have a high rate of ATP turnover.

The two chapters of this thesis focus on different aspects of DNA and the properties of nucleic acids as the whole. Chapter 1 focuses on the structure of DNA and its relationship to enzymatic efficiency. Chapter 2 centers itself on threose nucleic acid and optimization of a step in the path to its synthesis. While Chapter 1 discusses DNA and Uracil-DNA Glycosylase with regards to the base excision repair pathway, Chapter 2 focuses on chemical synthesis of an intermediate in the pathway to the synthesis of TNA, an analogous structure with a different saccharide in the sugar-phosphate backbone.
Chapter 1 covers the research under Dr. Levitus. Four oligonucleotides were reacted for zero, five, and thirty minutes with uracil-DNA glycosylase and subsequent addition of piperidine. These oligonucleotides were chosen based on their torsional rigidities as predicted by past research and predictions. The objective was to better understand the relationship between the sequence of DNA surrounding the incorrect base and the enzyme’s ability to remove said base in order to prepare the DNA for the next step of the base excision repair pathway. The first pair of oligonucleotides showed no statistically significant difference in enzymatic efficiency with p values of 0.24 and 0.42, while the second pair had a p value of 0.01 at the five-minute reaction. The second pair is currently being researched at different reaction times to determine at what point the enzyme seems to equilibrate and react semi-equally with all sequences of DNA.
Chapter 2 covers the research conducted under Dr. Chaput. Along the TNA synthesis pathway, the nitrogenous base must be added to the threofuranose sugar. The objective was to optimize the original protocol of Vorbrüggen glycosylation and determine if there were better conditions for the synthesis of the preferred regioisomer. This research showed that toluene and ortho-xylene were more preferable as solvents than the original anhydrous acetonitrile, as the amount of preferred isomer product far outweighed the amount of side product formed, as well as improving total yield overall. The anhydrous acetonitrile reaction had a final yield of 60.61% while the ortho-xylene system had a final yield of 94.66%, an increase of approximately 32%. The crude ratio of preferred isomer to side product was also improved, as it went from 18% undesired in anhydrous acetonitrile to 4% undesired in ortho-xylene, both values normalized to the preferred regioisomer.

Fluorescence spectroscopy is a powerful tool for biophysical studies due to its high sensitivity and broad availability. It is possible to detect fluorescence from single molecules allowing researchers to see the behavior of subpopulations whose presence is obscured by “bulk” collection methods. The fluorescent probes used in these experiments are affected by the solution and macromolecular environments they are in. A misunderstanding of a probe’s photophysics can lead researchers to assign observed behavior to biomolecules, when in fact the probe is responsible. On the other hand, a probe’s photophysical behavior is a signature of the environment surrounding it; it can be exploited to learn about the biomolecule(s) under study. A thorough examination of a probe’s photophysics is critical to data interpretation in both cases and is the focus of this work. This dissertation investigates the photophysical behavior of symmetric and asymmetric cyanines in a variety of solution and biomolecular environments. Using fluorescent techniques—such as time-correlated single photon counting (TCSPC) and fluorescence correlation spectroscopy (FCS)—it was found that cyanines are influenced by the local environment. In the first project, the symmetric cyanines are found to be susceptible to paramagnetic species, such as manganese(II), that enhance the intersystem crossing (ISC) rate increasing triplet blinking and accelerating photobleaching. Another project found the increase in fluorescence of Cy3 in the protein induced fluorescence enhancement (PIFE) technique is due to reduced photoisomerization caused by the proximity of protein to Cy3. The third project focused on asymmetric cyanines; their photophysical behavior has not been previously characterized. Dy630 as a free dye behaves like Cy3; it has a short lifetime and can deactivate via photoisomerization. Preliminary experiments on Dy dyes conjugated to DNA show these dyes do not photoisomerize, and do not show PIFE potential. Further research will explore other conjugation strategies, with the goal of optimizing conditions in which Dy630 can be used as the red-absorbing analogue of Cy3 for PIFE applications. In summary, this dissertation focused on photophysical investigations, the understanding of which forms the backbone of rigorous fluorescent studies and is vital to the development of the fluorescence field.

Fluorescence spectroscopy is a popular technique that has been particularly useful in probing biological systems, especially with the invention of single molecule fluorescence. For example, Förster resonance energy transfer (FRET) is one tool that has been helpful in probing distances and conformational changes in biomolecules. In this work, important properties necessary in the quantification of FRET were investigated while FRET was also applied to gain insight into the dynamics of biological molecules. In particular, dynamics of damaged DNA was investigated. While damages in DNA are known to affect DNA structure, what remains unclear is how the presence of a lesion, or multiple lesions, affects the flexibility of DNA, especially in relation to damage recognition by repair enzymes. DNA conformational dynamics was probed by combining FRET and fluorescence anisotropy along with biochemical assays. The focus of this work was to investigate the relationship between dynamics and enzymatic repair. In addition, to properly quantify fluorescence and FRET data, photophysical phenomena of fluorophores, such as blinking, needs to be understood. The triplet formation of the single molecule dye TAMRA and the photoisomerization yield of two different modifications of the single molecule cyanine dye Cy3 were examined spectroscopically to aid in accurate data interpretation. The combination of the biophysical and physiochemical studies illustrates how fluorescence spectroscopy can be used to answer biological questions.