Delivery Strategies for Nucleic Acids

Shayak Samaddar (7041221)

15 August 2019

<div>Utilization of nucleic acids to manipulate genetic information within a cell is known as gene therapy. It has provided researchers with unprecedented opportunities in treatment and mitigation of several life-threatening diseases. Gene therapy is an attractive alternative to conventional chemotherapy or radiation therapy due to its high efficiency, minimal side effects, and potential to evade drug resistance. The versatility of gene therapy makes it useful for the treatment of diseases dangerous disease like cancer. However, delivery of nucleic acid payloads to the intended target has been the bottleneck in clinical translation of such therapies. Here, we have developed and evaluated three different delivery systems (lipid based, polymer based and lipid-polymer hybrid) which can complex nucleic acid payloads, able to target specific cell types and get dissembled on cellular internalization to release the therapeutic payload. Our lipid and lipid-polymer hybrid delivery systems utilize a novel bacterial peptide sequence which enables these vectors to “stick” to fibronectin present in tumor extracellular matrix making them attractive for intravesical administration in bladder cancer management. Additionally, these systems have pH responsive modalities which aids in vector dissemble under acidic endosomal pH conditions for efficient release of therapeutic cargos after internalization into target cells.</div><div><br></div><div>In our efforts to develop an ideal delivery system with a tunable the assembly/disassembly properties, we synthesized a library of pendent polymer with biodegradable polycarbonate backbone. The ability of the pendent groups to form host-gest interaction with hydrophobic core of cationic cyclodextrins determined the stability of the delivery system. We demonstrate the capability of such polymer systems to form nano-dimensinal complexes with nucleic acid and transfect cancer cells. The above-mentioned property of cyclodextrins to form host-guest interaction with hydrophobic molecules also forms the basis of its utilization in the treatment of a rare metabolic disorder called Niemann Pick type C disease where there the cells loses the ability to remove stored cholesterol from endo-lysosomal compartments. Cyclodextrin forms host-gest complexes with aberrantly stored cholesterol and helps normalization of cellular cholesterol level. However, the soluble nature and small size of the cyclodextrin causes very rapid clearance for the body necessitating dosage levels as high as 9000mg/kg for therapeutic benefit. We have also developed a library of polyrotaxanes, where multiple cyclodextrins are threaded onto linear polymer chains and end-capped with bulky groups to prevent slippage. This kind to assembly drastically increases the systemic circulation time by preventing rapid renal clearance. We evaluated the ability of these constructs to serve as a long circulation delivery system for delivery of β-cyclodextrins for potential treatment of Niemann Pick type C disease. Finally, we have studied the structure-function relationships of these supramolecular assemblies to aid in rational design of therapeutic polyrotaxanes.</div>

Medical Biochemistry: Lipids

Medical Biochemistry: Nucleic Acids

GENE THERAPY

SYNTHESIS AND EVALUATION OF LABELED PHOSPHATIDYLGLYCEROL PROBES TO ELUCIDATE MECHANISMS BEHIND CHOLESTEROL TRAFFICKING IN NIEMANN-PICK TYPE C DISEASE

Zachary J Struzik (12426840)

01 June 2022

<p>  </p> <p>Niemann-Pick Type C (NPC) disease is a rare lysosomal storage disorder that occurs in about 1/89,000 to 1/120,000 live births and is characterized by an aberrant accumulation of cholesterol within the late endosome/lysosome of cells. Symptoms of this disease include splenomegaly, neurological deterioration, and often death before adulthood. Mutations in the membrane bound NPC1 or luminal NPC2 proteins lead to a decrease in cholesterol efflux within the lysosomes by which excess cholesterol crystallizes within membranes resulting in cell death. It has been demonstrated that increasing the amount of the lysosomal specific phospholipid Bis(monoacylglycerol)phosphate (BMP), also known as Lysobisphosphatidic acid (LBPA), in cells increases the rate of cholesterol transport in <em>npc1</em>-/- cells, but not in <em>npc</em>2-/- cells, indicating a strong synergistic relationship between the NPC2 protein and the lysosomal membranes. Increasing the amount of phosphatidyl glycerol (PG), a hypothesized precursor to BMP, has also shown an increase in cholesterol egress. While it is hypothesized that the increase in cholesterol clearance in the latter is due to the biosynthesis of LBPA from PG, there is no study to directly confirm this phenomenon. Therefore, we set out to synthesize diastereochemically pure PG containing isotopically labeled oleyl acyl chains to examine LBPA levels using lipidomic analysis of <em>npc1-/-</em> cells post treatment with PG. </p> <p>Initially, efforts centered around the use of phosphoramidite methodology commonly encountered in DNA oligonucleotide synthesis. While this route proved to be successful in making PG in modest yield (52%), reproducibility of this route with consistent yields was hindered due to the use of tetrabutylammonium fluoride (TBAF) in the final global deprotection step. Thus, we set out to discover a phosphorylated intermediate that did not require TBAF in the final step or contain easily hydrolysable protecting groups. It was discovered that H-phosphonate methodology using diphenyl phosphite for phosphorylation of the glycerol headgroup and backbone proved to be robust enough for PG synthesis. In this strategy, PG can be isolated in two steps from the final protected intermediate by first oxidizing the H-phosphonate from PIII to PV followed by deprotection of the glycerol head group under acidic conditions. Additionally, the H-phosphonate strategy also allowed us to omit headgroup modification prior to phosphorylation which reduced the number of synthetic steps from 11 steps to 7 steps. As a result, we were able to synthesize diastereochemically pure PG more consistently than the previous route in 75% yield. The route was further modified further to incorporate asymmetric acyl chains allowing the selective installation of a labeled acyl chain on the <em>sn</em>-1 or <em>sn</em>-2 positions of the phosphoglycerol backbone. The results from the lipidomic experiments indicate that increased LBPA concentrations in cells rise upon incubation with labeled PG. Additionally, increases in lyso-PG and acyl-PG are also observed leading to several hypotheses on how LBPA might be synthesized from PG. Future directions on this effort include identification of phospholipid species made from PG containing asymmetrically labeled acyl chains.  Synthesis of photoaffinity labeled PG is also underway to determine the protein partners involved in PG metabolism.</p>

Medical biochemistry - lipids

Niemann-Pick Type C Disease

Bis(monoacylglycero)phosphate

Lipid Probes

Lipid Synthesis

Phosphatidylglycerol

Lysobisphosphatidic Acid

Lysosomal storage disorder (LSD)

Organic Chemistry

Medical Biochemistry: Lipids

Biochemistry

Omega-3 fatty acids, micronutrients and cognitive and behaviour problems associated with child attention deficit hyperactivity disorder

Sinn, Natalie

January 2006

This thesis concerns the role of nutrients in cognitive and behaviour problems associated with child attention deficit hyperactivity disorder (ADHD). Study 1 investigated relationships between Conners' ADHD Index ratings, fatty acid deficiency symptoms (FADS), and cognitive performance in a normal population of children. Studies 2 and 3 comprised a 30 week intervention trial investigating effects of n-3 PUFA supplementation on ADHD symptoms in 7-12 year old children with high ADHD scores.

Medical Biochemistry: Lipids

Nutrition and Dietetics

nutrition

omega-3 fatty acids

mental health

cognition

behaviour

children

ADHD

attention deficit hyperactivity disorder

FAT AND SODIUM QUANTIFICATION AND CORRELATION BY MRSI

Ahmad Abdurahman M. Alhulail (8933363)

16 June 2020

<p>Lipids and sodium (²³Na) are two essential components of the human body. They play a role in almost all biological systems. However, an increase in their levels is associated with metabolic diseases. The elevation of their contents can cause similar health disorders. Examples of prevalent disorders that share an increase of musculoskeletal lipids and ²³Na are hypertension and diabetes. However, the relationship between in vivo lipid and sodium levels in pathophysiology has not been studied enough and therefore is still unclear. Additionally, the available quantification methods to facilitate such a study may not be practical. They are either invasive, not sensitive enough, or require an impractical measurement time.</p> <p>Therefore, in this work, our aims were to develop practical in vivo methods to quantify the absolute sodium concentration as well as the concentration of each lipid component individually, and to study the correlation between them within the skeletal muscles.</p> <p>Since lipids and ²³Na have different nuclear magnetic resonance properties, their quantification by magnetic resonance (MR) techniques face different challenges. Thus, we optimized different MR spectroscopic imaging (MRSI) techniques for lipids and ²³Na. </p> <p>Our proposed proton MRSI was able to provide eight lipid fat fraction (FF) maps representing each musculoskeletal lipid component (fatty acid) detected by our MRSI technique, and demonstrated a superior sensitivity compared to the conventional MR imaging methods.</p> <p>For ²³Na, our developed ²³Na-MRSI was able to measure and map the absolute ²³Na concentration with values agreeing with those reported previously in biopsy studies, and with a high repeatability (CV < 6 %) within significantly shorter acquisition time compared to other available techniques.</p> <p> Finally, the ²³Na concentration and the fat fractions of each lipid component within healthy skeletal muscles were measured and correlated using our developed MRSI methods. Our findings suggest a positive regional relationship between ²³Na and lipids and negative correlation between ²³Na and BMI under healthy conditions.</p>

Medical Biochemistry: Lipids

Radiology and Organ Imaging

Medical Physics

MRI

MRSI

Magnetic Resonance Imaging

Magnetic Resonance Spectroscopic Imaging

MRS

Lipid

Fatty Acids

Quantification

Noninvasive

Sodium

Mapping

Muscle

DEVELOPMENT OF AMBIENT IONIZATION MASS SPECTROMETRY FOR INTRAOPERATIVE CANCER DIAGNOSTICS AND SURGICAL MARGIN ASSESSMENT

Clint M Alfaro (6597242)

15 May 2019

<div> Advancements in cancer treatments have increased rapidly in recent years, but cures remain elusive. Surgical tumor resection is a central treatment for many solid malignancies. Residual tumor at surgical margins leads to tumor recurrence. Novel tools for assessing residual tumor at surgical margins could improve surgical outcomes by helping to maximize the extent of resection. Ambient ionization-mass spectrometry (MS) methods generate and analyze ions from minimally prepared samples in near-real-time (e.g. seconds to minutes). These methods leverage the high sensitivity and specificity of mass spectrometry for analyzing gas phase ions and generating those ions quickly and with minimal sample preparation. Recent work has shown that differential profiles of ions, corresponding to phospholipids and small metabolites, are detected from cancerous and their respective normal tissue with ambient ionization-MS methods. When properly implemented, ambient ionization-MS could be used to assess for tumor at surgical margins and provide a molecular diagnosis during surgery. </div><div><br></div><div>The research herein reports efforts in developing rapid intraoperative ambient ionization-MS methods for the molecular assessment of cancerous tissues. Touch spray (TS) ionization and desorption electrospray ionization (DESI) were utilized to analyze kidney cancer and brain cancer.</div><div><br></div><div> As a demonstration of the applicability of TS-MS to provide diagnostic information from fresh surgical tissues, TS-MS was used to rapidly analyze renal cell carcinoma and healthy renal tissue biopsies obtained from human subjects undergoing nephrectomy surgery. Differential phospholipid profiles were identified using principal component analysis (PCA), and the significant ions were characterized using multiple stages of mass spectrometry and high resolution/exact mass MS. The same TS-MS analyzed renal tissues were subsequently analyzed with DESI-MS imaging to corroborate the TS-MS results, and the significant DESI-MS ions were also characterized with MS.</div><div><br></div><div>Significant efforts were made in developing and evaluating a standalone intraoperative DESI-MS system for analyzing brain tissue biopsies during brain tumor surgery. The intraoperative DESI-MS system consists of a linear trap quadrupole mass spectrometer placed on a custom-machined cart that contains all hardware for operating the mass spectrometer. This instrument was operated in the neurosurgical suites at Indiana University School of Medicine to rapidly analyze brain tissue biopsies obtained from glioma resection surgeries. A DESI-MS library of normal brain tissue and glioma was used to statistically classify the brain tissue biopsies collected in the operating room. Multivariate statistical methodologies were employed to predict the disease state and tumor cell percentage of the samples. A DESI-MS assay for detecting 2-hydroxyglutarate (2HG), the oncometabolic product of the isocitrate dehydrogenase (IDH) mutation (a key glioma prognostic marker), was developed and applied to determine the IDH mutation status during the surgical resection. The strengths, weaknesses, and areas of future work in this field are discussed. </div><div><br></div>

Cancer

Biomarkers

Medical Biochemistry: Lipids

Clinical Chemistry (diagnostics)

Cancer Diagnosis

Analytical Biochemistry

Ambient ionization mass spectrometry

Molecular cancer diagnostics

Tumor infiltration

Isocitrate dehydrogenase mutation

2-hydroxyglutarate

Lipid biomarkers

Molecular pathology

DESI-MSI imaging

N-acetylaspartate

Surgical margin assessment

Intraoperative cancer tissue diagnostics

Glioma markers

Neurological smears

Renal cell carcinoma

Multivariate statistics

Characterizing Microglial Response to Amyloid: From New Tools to New Molecules

Priya Prakash (10725291)

29 April 2021

<p>Microglia are a population of specialized, tissue-resident immune cells that make up around 10% of total cells in our brain. They actively prune neuronal synapses, engulf cellular debris, and misfolded protein aggregates such as the Alzheimer’s Disease (AD)-associated amyloid-beta (Aβ) by the process of phagocytosis. During AD, microglia are unable to phagocytose Aβ, perhaps due to the several disease-associated changes affecting their normal function. Functional molecules such as lipids and metabolites also influence microglial behavior but have primarily remained uncharacterized to date. The overarching question of this work is, <i>How do microglia become dysfunctional in chronic inflammation</i>? To this end, we developed new chemical tools to better understand and investigate the microglial response to Aβ <i>in vitro</i> and <i>in vivo</i>. Specifically, we introduce three new tools. (1) Recombinant human Aβ was developed via a rapid, refined, and robust method for expressing, purifying, and characterizing the protein. (2) A pH-sensitive fluorophore conjugate of Aβ (called Aβ^pH) was developed to identify and separate Aβ-specific phagocytic and non-phagocytic glial cells <i>ex vivo</i> and <i>in vivo</i>. (3) New lysosomal, mitochondrial, and nuclei-targeting pH-activable fluorescent probes (called LysoShine, MitoShine, and NucShine, respectively) to visualize subcellular organelles in live microglia. Next, we asked, <i>What changes occur to the global lipid and metabolite profiles of microglia in the presence of Aβ in vitro and in vivo</i>? We screened 1500 lipids comprising 10 lipid classes and 700 metabolites in microglia exposed to Aβ. We found significant changes in specific lipid classes with acute and prolonged Aβ exposure. We also identified a lipid-related protein that was differentially regulated due to Aβ <i>in vivo</i>. This new lipid reprogramming mechanism “turned on” in the presence of cellular stress was also present in microglia in the brains of the 5xFAD mouse model, suggesting a generic response to inflammation and toxicity. It is well known that activated microglia induce reactive astrocytes during inflammation. Therefore, we asked, <i>What changes in proteins, lipids, and metabolites occur in astrocytes due to their reactive state? </i>We provide a comprehensive characterization of reactive astrocytes comprising 3660 proteins, 1500 lipids, and 700 metabolites. These microglia and astrocytes datasets will be available to the scientific community as a web application. We propose a final model wherein the molecules secreted by reactive astrocytes may also induce lipid-related changes to the microglial cell state in inflammation. In conclusion, this thesis highlights chemical neuroimmunology as the new frontier of neuroscience propelled by the development of new chemical tools and techniques to characterize glial cell states and function in neurodegeneration.</p>

Cell Biology

Neuroscience

Medical Biochemistry: Lipids

Cellular Immunology

Analytical Biochemistry

Cell Neurochemistry

Immunological and Bioassay Methods

Biologically Active Molecules

Microglia

Alzheimer's disease

Lipidomics

Proteomics

Metabolomics

Phagocytosis

Amyloid Beta

Astrocytes

Reactive Astrocytes

Chemical Tools

Chemical Biology

Neuroinflammation

Neurodegeneration

Glia

Neuroscience

Neuroimmunology

Ambient Ionization Mass Spectrometry for Intraoperative and High-Throughput Brain Cancer Diagnostics

Hannah Marie Brown (12476919)

29 April 2022

<p>My research has focused on the development and translation of ambient ionization mass spectrometry (MS)-based platforms in clinical and surgical settings, specifically in the area of brain cancer diagnostics and surgical decision making. Ambient ionization MS methods, such as those described herein, generate and analyze gas phase ions with high sensitivity and specificity from minimally prepared samples in near-real-time, on the order of seconds to minutes, rendering them well suited to point-of-care applications. We used ambient ionization MS methods, specifically desorption electrospray ionization mass spectrometry (DESI-MS) and extraction nanoelectrospray ionization mass spectrometry (nESI-MS) to molecularly characterize brain cancer biopsies. The characterization was made using diagnostic compounds identified as markers of disease state, tissue composition, tumor type, and genotype in human brain tissue. Methods were developed and validated offline in the laboratory and translated to clinical and surgical settings, thereby generating chemical information on prognostic features intraoperatively and providing valuable information that would be otherwise unavailable. We believe that, with approval, the methodologies described can assist physicians and improve patient outcomes by providing analytical tools and molecular information that can inform surgical decision making and adjuvant treatment strategies, complementing and not interfering with standard of care protocols.</p> <p><br></p> <p>We have successfully demonstrated the use of desorption electrospray ionization mass spectrometry (DESI-MS) for the expedient molecular assessment of human glioma tissue biopsies based on lipid profiles and prognostic metabolites, both at the tumor core and near surgical margins, in two small-scale, clinical studies. Maximal surgical resection of gliomas that avoids non-infiltrated tissue is associated with survival benefit in patients with glioma. The infiltrative nature of gliomas, as well as their morphological and genetic diversity, renders treatment difficult and demands an integrated imaging and diagnostic approach during surgery to guide clinicians in achieving maximal tumor resection. Further, the estimation of tumor cell percentage (TCP), a measure of tumor infiltration at surgical margins, is not routinely assessed intraoperatively. </p> <p>We have previously shown that rapid, offline molecular assessment of tumor infiltration in tissue biopsies is possible and believe that the same assessment performed intraoperatively in biopsied tissue near surgical margins could improve resection and better inform patient management strategies, including postoperative radiotherapy. Using a DESI-MS spectral library of normal brain tissue and glioma biopsies to generate a statistical model to classify brain tissue biopsies intraoperatively, multivariate statistical approaches were used to predict the disease state and tumor cell percentage (TCP) of each biopsy, thereby providing an measure of tumor infiltration at surgical margins via molecular indicators. In addition to assessment of tumor infiltration, we have developed DESI-MS assays for detecting the oncometabolite 2-Hydroxyglutarate (2HG) to detect isocitrate dehydrogenase (IDH) mutations in gliomas intraoperatively. Knowledge of IDH genotypes at the time of surgical resection could improve patient outcomes, as more aggressive tumor resection of IDH-mutated gliomas is associated with increased survival. While assessments of IDH genotype are typically not available until days after surgery, we have demonstrated the ability to provide this information is less than five minutes. An intraoperative DESI-MS system has successfully been used in a proof-of-concept clinical study and intraoperative performance validation of this platform is ongoing. The findings of these two studies as well as strengths, weaknesses, and areas of improvement for upcoming future iterations of the research are discussed.</p> <p><br></p> <p>Point-of-care applications necessitate the adaptation of MS methodologies to smaller devices. Miniature mass spectrometers (Mini MS) boast small footprints, simple operation, and low power consumption, noise levels, and cost, making them attractive candidates for point-of-care use. In a small-scale clinical study, we demonstrated the first application of a Mini MS for determination of IDH mutation status in gliomas intraoperatively. This study paves a path forward for the application of Mini MS in the OR. With its small footprint and low power consumption and noise level, this application of miniature mass spectrometers represents a simple and cost-effective platform for an important intraoperative measurement. </p> <p><br></p> <p>While MS-based methods of tissue analysis can detect molecular features of interest and rapidly produce large quantities of data, their inherent speed is rarely utilized because they are traditionally coupled with time-consuming separation techniques (e.g., chromatography). Ambient ionization MS, specifically DESI-MS, is well suited for high-throughput applications due to its lack of sample preparation and purification techniques. In an attempt to rapidly characterize microarrays of tissue biopsies, we developed a high-throughput DESI-MS (HT-DESI-MS) method for the rapid characterization of disease state, human brain tumor type, glioma classification, and detection of IDH mutations in tissue microarrays (TMA) of banked and fresh human brain tissue biopsies. We anticipate that HT-DESI-MS analysis of TMAs could become a standard tool for the generation of spectral libraries for sample classification, the identification of biomarkers through large-scale studies, the correlation of molecular features with anatomical features when coupled to digital pathology, and the assessment of drug efficacy. </p>

Cancer

Biomarkers

Medical Biochemistry: Lipids

Clinical Chemistry (diagnostics)

Cancer Diagnosis

Analytical Biochemistry

Intraoperative cancer diagnostics

Molecular pathology

Point-of-care diagnostics

Ambient ionization mass spectrometry

High-throughput mass spectrometry

Desorption electropray ionization

Nanoelectrospray ionization

Brain cancer

Glioma tumors

Meningioma tumors

Pituitary tumors

Isocitrate dehydrogenase mutation

2-Hydroxyglutarate

Tumor infiltration

Surgical margin delineation

Lipid biomarkers

HOW TO BE A BAD HOST FOR VIRUSES BY UNDERSTANDING THE COMPLEXITIES OF HOST LIPID-VIRAL PROTEIN INTERACTIONS

Emily A David (17583603)

10 December 2023

<p dir="ltr">The recent global pandemic, COVID-19, has revealed to all the importance of understanding the complex relationship between viruses and hosts. Before COVID-19, I started my study of viral protein-host lipid interactions in the hemorrhagic fevers Ebola and Marburg viruses. These viruses contain a matrix protein that interacts with the plasma membrane to facilitate the formation of both authentic viruses and virus-like particles. My goal was to understand the limitations of their specific host lipid interactions. However, when the COVID-19 pandemic began, so to be our swift response in the development of a biosafety level 2 compatible model. This model can be used for studying severe acute respiratory distress syndrome 2 (SARS-CoV-2) assembly, egress, and entry. This model enabled exponentially greater access to more facilities to study the intricacies of SARS-CoV-2 assembly. With more access to studying the virus in a safe model, our goal is to push the understanding of viral assembly faster. I then began to take apart the individual pieces of the model and started to look at understanding the roles that they play independently. The membrane protein is the most abundant structural protein and I studied the specific lipid interactions of the soluble fraction of the protein. Physicians observed nucleocapsid protein mutations in the clinic with the increasing number of SARS-CoV-2 variants that are on the rise. The microscopy data collected can give us more insight into perhaps how the nucleocapsid protein induces the formation of filopodia structures at the plasma membrane. The envelope protein proved to be a challenge, but I determined a specific envelope and ceramide interaction in cells. The envelope protein was also causing the formation of microvesicles for an undefined function. I was able to determine the subcellular localization of the protein to the mitochondria. The localization to the mitochondria appears to induce depolarization of the mitochondria membrane action potential and induces the increase in mitochondria dysfunction signal, cytochrome c. Although the mitochondria were dysfunctional, there was no increase in apoptosis signal in the presence of the protein alone.</p>

Enzymes

Protein trafficking

Virology

Medical biochemistry - lipids

Medical virology

Cell physiology

Basic pharmacology

BSL-2

Virus-like particle VLP

SARS-CoV-2

EBOV (Ebola virus)

mitochondrial membrane localization

lipid interaction studies

ceramide

scanning electron microscopy methodology

SARS-CoV-2-N

SARS-CoV-2-E

SARS-CoV-2-M

VP40