Hsp90-Mediated Maturation of Kinases and Nuclear Steroid Hormone Receptors: A Dissertation

Pursell, Natalie W.

28 April 2011

Among heat shock proteins, Hsp90 is unusual because it is not required for the proper folding of most cellular proteins but rather is disproportionally linked to the activation of signal transduction proteins including over forty kinases and many steroid hormone receptors. Mutated forms of many Hsp90 clients are causative agents in cancer, making Hsp90 a promising pharmacological target. Many small molecular inhibitors have been identified that competitively bind to the ATP binding site of Hsp90, some of which are in clinical trials as anticancer agents. Although the activation of kinase and hormone receptor clients by Hsp90 and its co-chaperones has been extensively studied, the molecular mechanism of client protein activation is poorly understood. Hsp90 is a dimeric chaperone containing three domains: the N-terminal (N) and middle (M) domains contribute directly to ATP binding and hydrolysis and the C-terminal (C) domain mediates dimerization. At physiological concentration, Hsp90 predominantly forms dimers, but the possibility that full-length monomers might also function in cells has not been tested. In Chapter 3, we used a single-chain strategy to design a full-length Hsp90 monomer (NMCC). The resulting construct was predominantly monomeric at physiological concentration and did not function to support yeast viability as the sole Hsp90. NMCC Hsp90 was also defective at ATP hydrolysis and the activation of kinase and steroid hormone receptor clients in yeast cells. The ability to support yeast growth was rescued by the addition of a coiled-coil dimerization domain, indicating that the parental single-chain construct is functionally defective because it is monomeric. After finding that a full-length Hsp90 monomer containing only one ATPase site was unable to support yeast viability or activate Hsp90 clients, we set out to further explore the role of ATPase activity in client protein activation. Approximately 10 % of the yeast proteome binds to Hsp90 making it important to study Hsp90 function in the cellular environment where all binding partners are present. In Chapter 4, we observed that co-expression of different Hsp90 subunits in Saccharomyces cerevisiae caused unpredictable synthetic growth defects due to cross-dimerization. We engineered super-stabilized Hsp90 dimers that resisted cross-dimerization with endogenous Hsp90 and alleviated the synthetic growth defect. We utilized these super-stabilized dimers to analyze the ability of ATPase mutant homodimers to activate known Hsp90 client proteins in yeast cells. We found that ATP binding and hydrolysis by Hsp90 are both required for the efficient maturation of the glucocorticoid hormone receptor (GR) and v-src confirming the critical role of ATP hydrolysis in the maturation of steroid hormone receptors and kinases in vivo. In addition to its role in the activation of signal transduction client proteins, Hsp90 has been shown to suppress the in vitro aggregation of numerous hard-to-fold proteins. In Chapter 5, we examine the role of charge in Hsp90 anti-aggregation activity. The charge on Hsp90 is largely concentrated in two highly acidic regions. We found that deletion of both charge-rich regions dramatically impaired Hsp90 anti-aggregation activity. Addition of an acid-rich region with a distinct amino acid sequence to our double-deleted Hsp90 construct rescued the anti-aggregation activity of Hsp90 indicating that the net charge contributes to its anti-aggregation activity. The in vitro anti-aggregation activity of Hsp90 studied in Chapter 5 occurs in the absence of ATP. However, all of the biologically important functions of Hsp90 in cells identified to date, including the maturation of kinases and nuclear steroid hormone receptors, clearly require ATP hydrolysis. Why does Hsp90 robustly hinder the aggregation of hard-to-fold proteins without ATP in vitro, but in vivo uses ATP hydrolysis for all of its essential functions? By utilizing separation of function Hsp90 variants (that specifically lack in vitro anti-aggregation activity) we have begun to address this question. We find that anti-aggregation deficient Hsp90 is unable to support yeast growth under stressful conditions, potentially due to reduced cellular expression. Interestingly, the ATP-independent anti-aggregation activity of Hsp90 has no measureable impact on cellular function. Thus, hindering the aggregation of most hard-to- fold proteins by Hsp90 (independent of ATP hydrolysis) does not appear to be important for cell function. These results suggest a cellular model where the Hsp40/60/70 machinery is responsible for hindering the aggregation of most hard-to-fold proteins while Hsp90 assists in the maturation of a select set of clients in an ATP-dependent fashion, potentially aided by its inherent anti-aggregation properties.

HSP90 Heat-Shock Proteins

Signal Transduction

Receptors

Steroid

Adenosine Triphosphate

Receptor Aggregation

Amino Acids, Peptides, and Proteins

Enzymes and Coenzymes

Heterocyclic Compounds

Polycyclic Compounds

A Tale of Two SNPS: Polymorphism Analysis of Toll-like Receptor (TLR) Adapter Proteins: A Dissertation

Nagpal, Kamalpreet

16 May 2011

The innate immune system is the first line of defense against invading pathogens. Recognition of microbial ligands by the innate immune system relies on germ-line encoded, evolutionarily conserved receptors called pattern recognition receptors (PRRs). Toll-like receptors (TLRs) are one such family of PRRs and are involved in innate defenses to a variety of microbes. At the core of TLR signaling pathways are Toll interleukin-1 receptor (TIR) domain containing adapter proteins. Much of the specificity of TLR pathways arise from the differential use of these adapter proteins. The TLR signaling cascade that ensues upon ligand recognition is marked by finely orchestrated molecular interactions between the receptor and the TIR domain containing adapter proteins, as well as various downstream kinases and effector molecules. Conserving the structural integrity of the TLR components is thus essential for maintaining a robust host defense system. Sometimes, changes in a protein can be brought about by single nucleotide polymorphisms (SNPs). Studies carried out in this thesis focus on polymorphisms in MyD88 adapter-like (Mal) and myeloid differentiation protein 88 (MyD88), two TIR domain-containing adapter proteins, which incidentally are also highly polymorphic. Mal is a 235 amino acid protein that is involved in TLR2 and TLR4 signaling. The known polymorphisms in the coding region of Mal were screened with an aim to identify SNPs with altered signaling potential. A TIR domain polymorphism, D96N, was found to be completely defective in TLR2 and TLR4 signaling. Immortalized macrophage-like cell lines expressing D96N have impaired cytokine production as well as NF-κB activation. The reason for this loss-of-function phenotype is the inability of Mal D96N to bind the downstream adapter MyD88, an event necessary for signaling to occur. Genotyping studies reveal a very low frequency of this polymorphism in the population. Similar SNP analysis was carried out in myeloid differentiation protein 88 (MyD88). MyD88 is a key signaling adapter in TLR signaling; critical for all TLR pathways except TLR3. In reporter assays, a death domain variant, S34Y, was found to be inactive. Importantly, in reconstituted macrophage-like cell lines derived from knockout mice, MyD88 S34Y was severely compromised in its ability to respond to all MyD88-dependent TLR ligands. S34Y mutant has a dramatically different localization pattern as compared to wild type MyD88. Unlike wild type MyD88, S34Y is unable to form distinct foci in the cells but is present diffused in the cytoplasm. IRAK4, a downstream kinase, colocalizes with MyD88 in these aggregates or “Myddosomes”. S34Y MyD88, however, is unable to assemble into Myddosomes, thus demonstrating that proper cellular localization of MyD88 is a feature required for MyD88 function. This thesis thus describes two loss‐of‐function polymorphisms in TLR adapter proteins Mal and MyD88. It sheds light not only on the structural aspects of signaling by these two proteins, but also has implications for the development of novel pharmaceutical agents.

Toll-Like Receptors

Myeloid Differentiation Factor 88

Membrane Glycoproteins

Receptors

Interleukin-1

Polymorphism

Single Nucleotide

Amino Acids, Peptides, and Proteins

Biological Factors

Immunology and Infectious Disease

Pharmaceutical Preparations

Therapeutics

Quantitative Analysis of Novel Chemical and shRNA Based Methods to Increase Survival of Motor Neuron Protein Levels

Evans, Matthew C.

20 June 2011

Spinal muscular atrophy (SMA) is an autosomal recessive neurodegenerative disorder that is the leading genetic cause of infantile death. SMA is caused by homozygous deletion or mutation of the survival of motor neuron 1 gene (SMN1). The SMN2 gene is nearly identical to SMN1, however is alternatively spliced. The close relationship to SMN1 results in SMN2 being a very power genetic modifier of SMA disease severity and a target for therapies. In this study we attempt to characterize novel chemical compounds identified as potential activators of the SMN2 gene. Additionally, we sought to determine the regulatory role individual HDAC proteins use to control expression of full length protein from the SMN2 gene. We used quantitative PCR to determine the effects of novel compounds and shRNA silencing of individual HDACs on the steady state levels of a SMN2-luciferase reporter transcripts. We determined that the compounds identified in multiple reporter high throughput screens increased SMN protein levels via transcriptional activation of the SMN2 gene. Other compounds identified in the same screen functioned post-transcriptionally, possibly stabilizing the SMN protein itself by decreasing degradation. Furthermore, we determined that reduction of individual HDAC proteins was sufficient to increase SMN protein levels in a transgenic reporter system. Knockdown of class I HDAC proteins preferentially activated the reporter by increased promoter transcription. Silencing of class II HDAC proteins maintained transcriptional activity; however silencing of HDAC 5 and 6 also appeared to enhance inclusion of an alternatively spliced exon. This collective work defines a quantitative RNA based protocol to determine mechanism of SMN reporter increase in response to any chosen treatment method. Additionally, this work highlights HDAC proteins 2 and 6 as excellent investigative targets. These data are important to the basic understanding of SMN expression regulation and the refinements of current therapeutic compounds as well as the development of novel SMA therapeutics.

Muscular Atrophy

Spinal

Survival of Motor Neuron 2 Protein

Histone Deacetylases

Amino Acids, Peptides, and Proteins

Enzymes and Coenzymes

Nervous System Diseases

Neuroscience and Neurobiology

A CNS-Active siRNA Chemical Scaffold for the Treatment of Neurodegenerative Diseases

Alterman, Julia F.

13 May 2019

Small interfering RNAs (siRNAs) are a promising class of drugs for treating genetically-defined diseases. Therapeutic siRNAs enable specific modulation of gene expression, but require chemical architecture that facilitates efficient in vivodelivery. siRNAs are informational drugs, therefore specificity for a target gene is defined by nucleotide sequence. Thus, developing a chemical scaffold that efficiently delivers siRNA to a particular tissue provides an opportunity to target any disease-associated gene in that tissue. The goal of this project was to develop a chemical scaffold that supports efficient siRNA delivery to the brain for the treatment of neurodegenerative diseases, specifically Huntington’s disease (HD). HD is an autosomal dominant neurodegenerative disorder that affects 3 out of every 100,000 people worldwide. This disorder is caused by an expansion of CAG repeats in the huntingtin gene that results in significant atrophy in the striatum and cortex of the brain. Silencing of the huntingtin gene is considered a viable treatment option for HD. This project: 1) identified a hyper-functional sequence for siRNA targeting the huntingtin gene, 2) developed a fully chemically modified architecture for the siRNA sequence, and 3) identified a new structure for siRNA central nervous system (CNS) delivery—Divalent-siRNA (Di-siRNA). Di-siRNAs, which are composed of two fully chemically-stabilized, phosphorothioate-containing siRNAs connected by a linker, support potent and sustained gene modulation in the CNS of mice and non-human primates. In mice, Di-siRNAs induced potent silencing of huntingtin mRNA and protein throughout the brain one month after a single intracerebroventricular injection. Silencing persisted for at least six months, with the degree of gene silencing correlating to guide strand tissue accumulation levels. In Cynomolgus macaques, a bolus injection exhibited significant distribution and robust silencing throughout the brain and spinal cord without detectable toxicity. This new siRNA scaffold opens the CNS for RNAi-based gene modulation, creating a path towards developing treatments for genetically-defined neurological disorders.

RNAi

siRNA

Huntington's disease

neurodegenerative disease

brain

delivery

Biotechnology

Chemical and Pharmacologic Phenomena

Medical Biotechnology

Medical Neurobiology

Medicinal Chemistry and Pharmaceutics

Neurosciences

Other Neuroscience and Neurobiology

Pharmaceutics and Drug Design

Translational Medical Research

Molecule recognition of nucleic acids, nucleosides, nucleotides, and their derivatives

Liu, Wanbo

01 January 2013

It has long been known that the efficiency of anticancer drugs is limited by the emergence of resistance due to the evolving repair of such DNA lesions in malignant cells. Therefore, development of pharmaceutical agents, which can interfere with the DNA repair pathways, may represent a novel approach to enhance the cytotoxic effects of chemotherapy by reducing drug resistance. Abasic sites (AP sites) are the key intermediates in the BER pathway and promising targets for BER inhibition. In chapter 2, we report the synthesis of two small molecules specifically targeting at AP sites and the evaluation of their activity in terms of interstrand crosslinking formation. Our results show no covalent adduct is induced, which is due to the weak DNA binding affinity. In chapter 3, we try to use TFOs to deliver the interstrand crosslinking moiety to the AP site in a sequence specific manner. Two modified phosphoramidites were synthesized and incorporated into the 5' end of TFOs. The activity was evaluated by using various biophysical and biochemical experiments. The work reported in chapter 4 is focused on the G-quadruplex structure formed in the guanine rich telomeric sequence. Many studies have shown G4 ligands can induce and stabilize G-quadruplex within telomere region and inhibit the activity of telomerase that is overexpressed in 80-90% of cancer cells. Our results indicate that phenanthroline based metal complexes, Ni(Phen) 2 , have strong binding affinity and selectivity towards G-quadruplex over duplex DNA. The effect of Ni(Phen) 2 on telomerase activity and cytotoxicity towards cancer cells was also investigated. Calixarenes containing DNA building units such as nucleotides, nucleosides, and nucleobases have recently aroused much interest because of their versatile applications. In chapter 5, we report the synthesis of calix[4]arenes ( 5.11-5.14 ) functionalized with a single nucleobase (thymine, adenine, guanine, or cytosine) at the upper rim via click chemistry. Their complexation with alkali metal ions was examined using MALDI-TOF mass spectrometry and their molecular interactions were determined using 1 H NMR. All calix[4]arene derivatives show good complexation with alkali metal ions with apparent selectivity. The results also reveal that nucleobase-calix[4]arenes are capable of self-association in CDC1 3 and calix[4]arenes bearing complementary nucleobases can bind to each other via base pairing.

Organic chemistry

Pharmacy sciences

Pure sciences

Health and environmental sciences

Abasic sites

Calixarenes

G-quadruplexes

Nucleosides

Telomeres

Chemicals and Drugs

Chemistry

Medical Pharmacology

Medicinal-Pharmaceutical Chemistry

Medicine and Health Sciences

Pharmaceutical Preparations

Pharmacy and Pharmaceutical Sciences

Physical Sciences and Mathematics

Synthesis of constrained tricyclic nucleosides and the core of nagilactone B

Giacometti, Robert

08 1900

Cette thèse décrit deux thèmes principaux: 1) la conception, la synthèse, et l'évaluation biophysique des nucléosides tricycliques, et 2) la synthèse de nagilactone B, un produit naturel norditerpenoïde dilactone de la famille de produits naturels “podolactone”. Le premier chapitre décrit la stratégie de design rationnel des nucléosides nommé “restriction conformationnelle double” basée sur les études de modélisation structurales des duplex ADN–ARN modifiés. Cette stratégie implique un blocage du cycle furanose dans une configuration de type N- ou S, et une restriction de la rotation torsionelle autour de l’angle γ. La première contrainte a été incorporée avec un pont méthylène entre l’oxygène en position 2′ et le carbone 4′ du nucléoside. Cette stratégie a été inspirée par les acides nucléiques bloqués (ou “locked nucleic acid”, LNA). La deuxième contrainte a été réalisée en ajoutant un carbocycle supplémentaire dans l'échafaud de l’acide nucléique bloqué. Les défis synthétiques de la formation des nucléotides modifiés à partir des carbohydrates sont décrits ainsi que les améliorations aux stabilités thermiques qu’ils apportent aux duplex oligonucléïques dont ils font partie. Chapitres deux et trois décrivent le développement de deux voies synthétiques complémentaires pour la formation du noyau de nagilactone B. Ce produit naturel a des implications pour le syndrome de Hutchinson–Gilford, à cause de son habilité de jouer le rôle de modulateur de l’épissage d’ARN pré-messager de lamine A. Ce produit naturel contient sept stereocentres différents, dont deux quaternaires et deux comprenant un syn-1,2-diol, ainsi que des lactones à cinq ou six membres, où le cycle à six ressemble à un groupement α-pyrone. La synthèse a débuté avec la cétone de Wieland-Miescher qui a permis d’adresser les défis structurels ainsi qu’explorer les fonctionnalisations des cycles A, B et D du noyau de nagilactone B. / The present thesis comprises two major themes: 1) the design, synthesis, and biophysical evaluation of conformationally restricted tricyclic nucleosides for antisense applications, and 2) strategic approaches for synthesizing the core of nagilactone B, a norditerpenoid dilactone from the podolactone family of natural products. Guided by structural studies of modified DNA–RNA duplexes, Chapter One focuses on a proposed dual-conformational-restriction strategy, in which two modes of conformational restriction are incorporated into a single nucleotide modification: 1) locking the furanose ring in an N- or S-type configuration and 2) restricting rotation around backbone torsion angle γ. The first constraint was incorporated by way of a 2′,4′-anhydro bridge that is found in the scaffold of locked nucleic acid (LNA), while the second was realized by annealing an additional carbocyclic ring to the modified nucleoside. The synthetic challenges associated with preparing these highly constrained molecules from carbohydrate-derived starting materials are described, in addition to the corresponding improvements in duplex thermal stability they provide to oligonucleotide sequences containing them. Chapters Two and Three describe complementary approaches for the synthesis of the core of nagilactone B, a natural product with implications for Hutchinson–Gilford progeria syndrome, as a consequence of its ability to act as a modulator of splicing events leading to lamin A. This natural product contains seven stereogenic centers overall, including a syn-1,2-diol moiety, a γ-lactone, and a pair of quaternary stereocenters, which are complemented by the presence of an α-pyrone moiety. To address the synthesis of these structural features, the utility of the Wieland–Miescher ketone was explored with an emphasis on synthesizing rings A, B, and D of the core of nagilactone B.

Antisense therapy

Tricyclic nucleic acids

Locked nucleic acids

Nucleosides

Nucleic acids

Nagilactone B

Podolactones

Wieland–Miescher ketone

Allylic oxidation

Reductive carbomethoxylation

Thérapie antisens

Acides nucléiques tricycliques

Acides nucléiques bloqués

Nucléosides

Acides nucléiques

Cétone de Wieland–Miescher

Carbomethoxylation réductrice

Oxydation allylique

TOWARD AN ENZYME-COUPLED, BIOORTHOGONAL PLATFORM FOR METHYLTRANSFERASES: PROBING THE SPECIFICITY OF METHIONINE ADENOSYLTRANSFERASES

Huber, Tyler D.

01 January 2019

Methyl group transfer from S-adenosyl-l-methionine (AdoMet) to various substrates including DNA, proteins, and natural products (NPs), is accomplished by methyltransferases (MTs). Analogs of AdoMet, bearing an alternative S-alkyl group can be exploited, in the context of an array of wild-type MT-catalyzed reactions, to differentially alkylate DNA, proteins, and NPs. This technology provides a means to elucidate MT targets by the MT-mediated installation of chemoselective handles from AdoMet analogs to biologically relevant molecules and affords researchers a fresh route to diversify NP scaffolds by permitting the differential alkylation of chemical sites vulnerable to NP MTs that are unreactive to traditional, synthetic organic chemistry alkylation protocols. The full potential of this technology is stifled by several impediments largely deriving from the AdoMet-based reagents, including the instability, membrane impermeability, poor synthetic yield and resulting diastereomeric mixtures. To circumvent these main liabilities, novel chemoenzymatic strategies that employ methionine adenosyltransferases (MATs) and methionine (Met) analogs to synthesize AdoMet analogs in vitro were advanced. Unstable AdoMet analogs are simultaneously utilized in a one-pot reaction by MTs for the alkylrandomization of NP scaffolds. As cell membranes are permeable to Met analogs, this also sets the stage for cell-based and, potentially, in vivo applications. In order to further address the instability of AdoMet and analogs thereof, MAT-catalyzed reactions utilizing Met and ATP isosteres generated highly stable AdoMet isosteres that were capable of downstream utilization by MTs. Finally, the development, use, and results of a high-throughput screen identified mutant-MAT/Met-analog pairs suitable for postliminary bioorthogonal applications.

Methionine Adenosyltransferase

Methyltransferase

S-Adenosyl-L-methionine

Natural Product Diversification

Bioorthogonal Labelling Platforms

Amino Acids, Peptides, and Proteins

Biochemistry

Biotechnology

Chemical and Pharmacologic Phenomena

Enzymes and Coenzymes

Medicinal and Pharmaceutical Chemistry

Medicinal Chemistry and Pharmaceutics

Medicinal-Pharmaceutical Chemistry

Molecular Biology

Organic Chemistry

Structural Biology

A Proposal to Test the Effects of Factor ECAT1 on Pluripotency, from Reprogramming to Differentiation of Human Somatic Cells

Goel, Vritti R.

01 January 2012

The field of stem cell research has been growing more because of the interest in using stem cells to cure diseases and heal injuries. Human embryonic stem cells, because of the controversy surrounding them—and subsequently the difficulties in acquiring samples of the existing aging cell lines—can only be used in limited capacities. While the development of induced pluripotent stem cells in the last decade has allowed the field to progress closer to medical treatments, the low efficiency of reprogramming a somatic cell to a pluripotent state, and the vast molecular and genomic differences between human embryonic stem cells and human induced pluripotent stem cells is still an issue. Therefore, the goal is to discover methods, chemicals, and factors that can reduce these differences and increase the efficiency of inducing pluripotency. This proposal aims to look at the effects of the protein ECAT1 in inducing pluripotency in human somatic cells. Little is known about ECAT1, otherwise known as Embryonic Stem Cell-Associated Transcript 1, beyond its presence in human embryonic stem cells and oocytes and its absence in differentiated cells. While originally considered by scientists during the development of the reprogramming technique, ECAT1's effects have not been tested in humans. Therefore, a series of experiments will be performed in which ECAT1 will be used in conjunction with OSKM to induce pluripotency in adult human dermal fibroblasts, which will then be differentiated into spinal motor neurons. The three stages of this proposal--inducing pluripotency, comparing pluripotencies in the reprogrammed cells and embryonic stem cells, and differentiating the stem cells--should answer questions about ECAT1 and the reprogramming process. It is predicted that ECAT1 should reduce the genomic and molecular differences between embryonic stem cells and induced pluripotent stem cells. ECAT1's presence should also increase the efficiency of reprogramming as well as successful differentiation to other cell types.

stem cells

OSKM

induced pluripotency

reprogramming

differentiation

ECAT1

Amino Acids, Peptides, and Proteins

Bioethics and Medical Ethics

Bioinformatics

Biological Factors

Biology

Cell Biology

Cellular and Molecular Physiology

Developmental Biology

Enzymes and Coenzymes

Genetic Structures

Medical Molecular Biology

Molecular and Cellular Neuroscience

Molecular Biology

Transcript-Specific Cytoplasmic Degradation of YRA1 Pre-mRNA Mediated by the Yeast EDC3 Protein: A Dissertation

Dong, Shuyun

17 December 2007

mRNA degradation is a fundamental process that controls both the level and the fidelity of gene expression. Using a combination of bioinformatic, genomic, genetic, and molecular biology approaches, we have shown that Edc3p, a yeast mRNA decay factor, controls the stability of the intron-containing YRA1 pre-mRNA. We found that Edc3p-mediated degradation of YRA1 pre-mRNA: 1) is a component of a negative feedback loop involved in the autoregulation of YRA1, 2) takes place in the cytoplasm, 3) is independent of translation, 4) occurs through a deadenylation-independent decapping and 5΄ to 3΄ exonucleotic decay mechanism, and 5) is controlled by specific cis-acting elements and trans-regulatory factors. Cis-regulation of YRA1 pre-mRNA degradation is complicated and precise. Sequences in exon1 inhibit YRA1 pre-mRNA splicing and/or promote pre-mRNA export in a size-dependent but sequence-independent manner. Sequences in the intron dictate the substrate specificity for Edc3p-mediated decay. Five structurally different but functionally interdependent modules were identified in the YRA1 intron. Two modules, designated Edc3p-responsive elements (EREs), are required for triggering an Edc3p-response. Three other modules, designated translational repression elements (TREs), are required for repressing translation of YRA1 pre-mRNA. TREs enhance the efficiency of the response of the EREs to Edc3p by inhibiting translation-dependent nonsense-mediated mRNA decay (NMD). Trans-regulation of YRA1 pre-mRNA is governed by Yra1p, which inhibits YRA1 pre-mRNA splicing and commits the pre-mRNA to nuclear export, and the RNP export factors, Mex67p and Crm1p, which jointly promote YRA1 pre-mRNA export. Mex67p also appears to interact with sequences in the YRA1 intron to promote translational repression and to enhance the Edc3p response of YRA1 pre-mRNA. These results illustrate how common steps in the nuclear processing, export, and degradation of a transcript can be uniquely combined to control the expression of a specific gene and suggest that Edc3p-mediated decay may have additional regulatory functions in eukaryotic cells.

Gene Expression

Cell Nucleus

Feedback

Biochemical

Nuclear Proteins

RNA Stability

RNA Precursors

RNA-Binding Proteins

Saccharomyces cerevisiae

Amino Acids, Peptides, and Proteins

Biochemistry

Bioinformatics

Cells

Computational Biology

Fungi

Genetic Phenomena

Genetics

Genetics and Genomics

Genomics

Molecular Biology

Molecular Genetics

Optimizing CRISPR/Cas9 for Gene Silencing of SOD1 in Mouse Models of ALS

Kennedy, Zachary C.

09 August 2019

Mutations in the SOD1 gene are the best characterized genetic cause of amyotrophic lateral sclerosis (ALS) and account for ~20% of inherited cases and 1-3% of sporadic cases. The gene-editing tool Cas9 can silence mutant genes that cause disease, but effective delivery of CRISPR-Cas9 to the central nervous system (CNS) remains challenging. Here, I developed strategies using canonical Streptococcus pyogenes Cas9 to silence SOD1. In the first strategy, I demonstrate effectiveness of systemic delivery of guide RNA targeting SOD1 to the CNS in a transgenic mouse model expressing human mutant SOD1 and Cas9. Silencing was observed in both the brain and the spinal cord. In the second strategy, I demonstrate the effectiveness of delivering both guide RNA and Cas9 via two AAVs into the ventricles of the brain of SOD1G93A mice. Silencing was observed in the brain and in motor neurons within the spinal cord. For both strategies, treated mice had prolonged survival when compared to controls. Treated mice also had improvements in grip strength and rotarod function. For ICV treated mice, we detected a benefit of SOD1 silencing using net axonal transport assays, a novel method to detect motor neuron function in mice before onset of motor symptoms. These studies demonstrate that Cas9-mediated genome editing can mediate disease gene silencing in motor neurons and warrants further development for use as a therapeutic intervention for SOD1-linked ALS patients.

CRISPR/Cas9

Cas9

Amyotrophic lateral sclerosis

ALS

Motor Neuron Disease

SOD1

superoxide dismutase

gene therapy

gene editing

AAV

adeno associated vector

adeno-associated vector

AAV9

Biology

Biotechnology

Molecular and Cellular Neuroscience

Musculoskeletal Diseases

Nervous System Diseases

Other Neuroscience and Neurobiology

Therapeutics