Application of Term-Rewriting Grammar in Chemical Reaction Prediction

Volarath, Patra

30 April 2008

Synthesis planning is a critical process in chemical design. A number of computer programs have been developed to assist the chemists with this procedure. Most of the programs utilize combinations of computational approaches. These have been successfully applied to a number of the synthesis predictions. However, they require numerous rules to screen for potential targets, as well as to keep the system from reaching the combinatorial explosion. This results in the advanced algorithms becoming more complex and parameter-sensitive. This can be problematic, particularly in the cases in which a large number of the compounds are to be handled, because it can not only result in a lengthy computational time, but also cause some of the highly potential targets to be missed. We developed a simpler approach for the reaction prediction using a term-rewriting grammar. The term-rewriting strategy is used to directly assign reactions to the compounds. This greatly reduces the number of rules that are usually required for these steps, and, hence, facilitates the prediction performance, while maintaining the prediction accuracy. In this dissertation, the designs of the developed algorithms and their results are first being presented, followed by a discussion of the approach’s application in the chemical design in the final chapter.

Term-rewriting programming

Reaction

Chemical Design

Maude

Chemistry

Structure and Energetics of RNA - Protein Interactions for HIV RREIIB Targeting Zinc Finger Proteins.

Mishra, Subrata H

01 July 2008

RNA - protein interactions constitute a vital part of numerous biochemical processes. In the HIV life cycle, the interaction of the viral protein Rev and the Rev Responsive Element (RRE), a part of unspliced HIV RNA, is crucial for the propagation of infectious virions. Intervention of this interaction disrupts the viral life cycle. Rev - RRE interaction initially occurs at a high affinity binding site localized to a relatively small stem loop structure called RREIIB. This binding event has been well characterized by a variety of biochemical, enzymatic and structural studies. Our collaborators have previously demonstrated the efficacy of zinc finger proteins, generated by phage display, in the specific targeting of RREIIB. We have shown that the binding of these zinc finger proteins is restricted to the bulge in stem loop IIB that Rev also targets. Currently these proteins bind RREIIB with dissociation constants in the nanomolar range. We have employed a wide assortment of biophysical techniques such as gel shift assays, circular dichroism, isothermal titration calorimetry and NMR structural studies to further investigate this interaction. Several mutants of the zinc finger protein and the RNA were also studied to delineate the parts of the protein secondary structure as well as the role of specific side chains in this interaction. We have generated a solution structure of the RREIIBTR RNA bound zinc finger protein, ZNF29G29R, which displayed the highest affinity to this RNA. This has allowed us to shed further light on the molecular basis of this RNA - protein interaction and provides input for further refinement in our structure guided phage display.

HIV

RRE

RNA

zinc finger

NMR

thermodynamics

Chemistry

Rational Design of Calcium Biosensors

Ellis, April L

04 August 2008

Understanding the temporal and spatial changes in calcium concentration has been a difficult endeavor for many years due to the relatively small changes in calcium concentration during messenging events, the rapid changes upon physiological messenging, and the unavailability of fast, efficient, and sensitive sensors to detect calcium changes. In addition, the key factors in calcium binding have yet to be determined due to the metal-metal interactions, cooperativity, and conformational change involved in calcium binding to natural calcium-binding proteins. To overcome these obstacles and to engineer calcium sensors for in vivo studies of calcium signaling events, calcium binding sites have been engineered into Green Fluorescent Protein. The engineered binding sites demonstrate terbium binding affinity from 2-30 ƒÝM and calcium binding affinity from 50-100 ƒÝM. Site 177 demonstrates green fluorescence when expressed in mammalian cells and produces a response to calcium concentration changes when expressed in the cytosol. Addition of the cycle 3 mutations (M153T, V163A, F99S) to Site 177 allowed for increased brightness in the emission of the chromophore but still exhibited calcium response. The second generation Site 1 demonstrates fluorescence response to calcium concentration changes when expressed both in the cytosol and in the endoplasmic reticulum. Addition of M153T and V163A to Site 1 allowed for expression of fluorescent protein at 37 ¢XC in HeLa cells and at 30 ¢XC in bacteria. Site 1-M153T/V163A exhibits chromophore fluorescence response to calcium with a Kd of 100 ƒÝM and competition with Rhodamine-5N produced a calcium Kd of 107 ƒÝM. This designed sensor, Site 1-M153T/V163A is the first demonstration of a designed calcium binding GFP with calcium response measured both in vivo and in vitro.

GFP

calcium

calcium binding protein

Chemistry

Determining The Site Specific Metal Binding and Structural Properties of EF-Hand Protein Using Grafting Approach

Lee, Hsiau-Wei

04 August 2008

Calmodulin is an essential EF-hand protein with a helix-loop-helix calcium binding motif. Understanding Ca(II) dependent activation of calmodulin and other EF-hand proteins is limited by Ca(II)-induced conformational change, multiple and cooperative binding of Ca(II) ions, and interactions between the paired EF-hand motifs. The goal of this research project is to probe key determinants for calcium binding properties and pairing interactions at the site specific level using a grafting approach and high resolution NMR. An individual Ca(II) binding site of the EF-hand motifs of calmodulin was grafted into a non-calcium dependent protein, CD2, to bypass limitations associated with natural EF-hand proteins and peptide fragments. Using high resolution NMR, we have shown that the grafted EF-loop III of calmodulin in the host protein retains its native conformation with a strong loop and β-conformation preference. Grafted ligand residues in the engineered protein are directly involved in binding of Ca(II) and La(III). The NMR studies support our hypothesis that both ligand arrangement and dynamic properties play essential role in tuning Ca(II) binding affinities. Using pulse-field diffusion NMR and protein engineering, we further demonstrated that grafted EF- loop remains as a monomer. Although the EF-loop with flanking helices dimerizes in the presence of Ca(II). Additionally, removal of conserved hydrophobic residues at the flanking helices of the EF-hand motif leads to be monomer in the absence and presence of metal ions. Our results suggest that conserved hydrophobic residues are essential for the pair-paired interaction in the coupled EF-hand protein. We have shown that our developed grafting approach can be applied to probe intrinsic Ca(II) binding affinities of different Ca(II) binding sites.

EF-hand

Calmodulin

CD2

NMR

Diffusion

Calcium

Chemistry

Binding, Bending and G Jumping in the Minor Groove: Experimental and Theoretical Approaches

Rahimian, Maryam

29 October 2008

It has been shown that heterocyclic diamidines, a class of minor groove binders, are promising antimicrobial agents. These compounds bind none covalently to the minor groove of A/T rich regions of the kinetoplast DNA and kill the parasite. The mechanism of action of these compounds is not well understood, yet many hypotheses have been proposed. One of the methods that improve the specificity is cooperative binding. Since there are many binding sites available in k-DNA thus the cooperativity in adjacent binding sites is desirable. A library of compounds has been scanned and few of those compounds identified that are able to bind to two adjacent A/T binding sites separated by a single G. Many biophysical methods such as isothermal titration calorimetry, surface Plasmon resonance, circular dichroism and thermal melting have been used to explore the thermodynamic profiles and binding mode of these compounds. The pulsed field gradient NMR was used to investigate the structural changes to the DNA sequence upon binding of the minor groove binders and find a correlation between their biological difference and structural changes. The molecular dynamics was applied to look at the interaction of some of the heterocyclic diamidines to the DNA with more details and predict the unknown structures.

Circular dichroism

Cooperativity

G jumpers

Minor groove binders

Chemistry

Integration of Extracellular and Intracellular Calcium Signals: Roles of Calcium-Sensing Receptor (CASR), Calmodulin and Stromal Interaction Molecule 1 (STIM1)

Huang, Yun

20 November 2008

Ca2+, both as a first and a second messenger, is closely involved in the modulation and regulation of numerous important cellular events, such as cell proliferation, differentiation and cell death. Fine-tuned Ca2+ signaling is achieved by its reversible or irreversible binding to a repertoire of Ca2+ signaling molecules. Among them, the extracellular calcium sensing receptor (CaSR) senses Ca2+ concentration ([Ca2+]o) in the milieu outside of cells where Ca2+ serves as a first messenger. An array of naturally-occurring mutations in CaSR has been found in patients with inherited disorders of Ca2+ homeostasis, leading to abnormal intracellular responses toward [Ca2+]o. In the present study, we have computationally predicted and experimentally characterized the metal-binding properties of five Ca2+-binding sites within CaSR and the accompanying metal--induced conformational changes by using two complementary methods-the grafting approach and the subdomain approach. Based on our results, a model has been proposed to explain the distinct CaSR-mediated responses toward abnormally ¡°high¡± or ¡°low¡± extracellular Ca2+ levels. In addition, we predicted and verified the interaction between CaSR with the most ubiquitously expressed four EF-hand-containing intracellular Ca2+ sensor protein, calmodulin (CaM). Our results demonstrate that the C-terminal CaM-binding domain of the CaSR is essential for proper intracellular Ca2+ response to external signals. Furthermore, we have applied the grafting approach to study the metal-binding properties and oligomeric state of the single EF-hand containing protein, STIM1. Our studies confirmed that the single EF-hand motif in STIM1, which resides in an equilibratium between its monomeric and dimeric forms, was capable of binding Ca2+ with a dissociation constant comparable to the ER Ca2+ concentration, suggesting it could function as a ER Ca2+ sensor responsible for sensing the Ca2+ filling state of ER.

Signaling

Ca2+

Fluorescence

Sensor

STIM1

Protein engineering

CD2

Prediction

Calmodulin

EF-hand

Calcium sensing receptor

Chemistry

Synthesis, Structure and Function Studies of Selenium and Tellurium Derivatized Nucleic Acids

Sheng, Jia

21 April 2009

Nucleic acids play important roles in living systems by storing and transferring genetic information and directing protein synthesis. Recently, it was found that nucleic acids can catalyze chemical and biochemical reactions similar to protein enzymes. In addition, they can also serve as drug targets for the treatment of deadly diseases such as AIDS and cancers. As a result, the 3D structure study of nucleic acids and proteinnucleic acids complexes by X-ray crystallography has become one of the most active research areas. However, the two intrinsic bottlenecks of macromolecule X-ray crystallography, including crystallization and phase determination, have significantly limited its application in study and discovery of the new structures and folds, as well as in exploration of the biological mechanisms. So far, the selenium derivatization (Se-Met) of proteins and multiple anomalous dispersion (MAD) or single anomalous dispersion (SAD) technology have revolutionized the protein crystallography field by providing a rational solution to solve the phase determination problem. Similarly, it’s important and urgent to develop a corresponding methodology for nucleic acid X-ray crystallography. The work presented here includes two general research directions: the selenium derivatized nucleic acids (SeNA) and tellurium derivatized nucleic acids (TeNA): 1) The SeNA strategy by site-specifically replacing oxygen with selenium at the 2’ and 4 positions of thymidine and uridine has been developed. We found that the selenium derivatization at both sites are relatively stable and doesn’t cause significant structure perturbations by comparing with their corresponding native counterparts. In addition to the phase determination, the 2’-Se modification can also facilitate crystal growth of many oligonucleotides. Moreover, we have observed colorful DNAs and RNAs with the 4-Se modification for the first time. 2) The TeNA strategy by covalently incorporating tellurium functionalities into different positions of nucleic acids, particularly at the 2’ and 5 position of thymidine, has been developed. We have demonstrated the compatibility of the tellurium modification and solid-phase synthesis, as well as the potential application of the tellurium modifications in anti-viral drug synthesis and DNA-damage investigation.

3D-structure

RNA

DNA

Nucleic acids

Tellurium

Selenium

X-ray

Chemistry

Development of Boronic Acid-Based Chemosensors

Jin, Shan

21 April 2009

It is well known that boronic acids can bind with diols and can be further applied as chemosensors for biomolecules such as carbohydrates and dopamine. Carbohydrates are known to mediate a large number of biological and pathological events. Small and macromolecules capable of carbohydrate recognition have great potentials as research tools, diagnostics, vectors for targeted delivery of therapeutic and imaging agents, and therapeutic agents.

Fluorescence

Carbohydrate

Sensor

Boronic acid

Chemistry

Metal-Assisted Hydrolysis of Biological Molecules

Cepeda, Sarah Shealy

28 April 2009

In Chapter I is a general description of novel metal complexes which hydrolytically cleave peptides, proteins, DNA, and other biological molecules. These reagents are becoming the more important as potential therapeutic agents. A panel of ligands was investigated for coordination to ZrIV and other metals in groups 4, 5, and 6 to effect the greatest degree of hydrolysis. Chapter II describes a ZrIV complex which is capable of hydrolyzing a 30 amino acid peptide, insulin chain B, with amino acid specificity. Oxidized insulin chain B peptide was hydrolyzed after only 4 h of treatment at pH 7.0 and 60 °C using ZrCl4 in the presence of 4,13-diaza-18-crown-6. MALDI-TOF and ESI LC-MS mass spectra indicated that insulin chain B was hydrolyzed by ZrIV at the Gly8-Ser9, Ser9-His10, and Gly20-Glu21 amide bonds within the oligopeptide. To our surprise, the cysteine sulfonic acid sequences Cys(SO3H)7-Gly8 and Cys(SO3H)19-Gly20 were also cleaved. To the best of our knowledge, this constitutes the first example of metal-assisted hydrolysis of a Cys(SO3H)-Xaa amide bond. This is significant in light of the fact that cysteine sulfonic acid formation in proteins is triggered by oxidative stress and has been associated with amyloid fibril formation, Parkinson’s disease, and other deleterious, physiological processes. Chapter III describes the metal-assisted hydrolysis of sphingomyelin which is a principle phospholipid component of animal cell membranes. The sphingomyelin assays showed evidence of metal-assisted hydrolysis after 20 h of treatment at lysosomal pH 4.8 and cytosolic pH 7.0 at both physiological temperature 37 °C and 60 °C. The metal ion CeIV was the most reactive, followed by ZrIV, and then HfIV. The goal of this work is to develop metal-based reagents to reverse the lethal build-up of sphingomyelin that occurs in lysosomes of patients suffering from Niemann-Pick disease.

ESI-MS

Sphingomyelin

Cholesterol

Vesicle

Micelle

Triton X-100

MALDI-TOF

Metals

Zirconium(IV)

Insulin chain B

Cleavage

Cerium(IV)

Hydrolysis

Chemistry

Application of Boronic Acids in Medicinal Chemistry (Inhibitors, Sensors)

Ni, Nanting

13 April 2010

It is well known boronic acids have its unique chemistry and related applications in organic synthesis. The boronic acid functionally group also plays very important roles in medicinal chemistry and chemical biology. For example, boronic acids have been developed as potential therapeutic agents, chemical biology tools. All these applications are directly related to the unique electronic and chemical properties of the boronic acid group. Herein, several application of boronic acids have been studied: 1) several groups of compounds were found as bacterial quorum sensing inhibitors; 2) a boronate compound was developed as a probe for detecting reactive oxygen species (ROS); and 3) boronic acid-modified aptamers can be used for glycoprotein recognition.

SPR

Selex

Aptamer

Boronic acids

Sensor

Quorum sensing

Autoinducer-2

Inhibitor

Hydrogen peroxide

Chemistry