The Roles of DNA Mismatch Repair and Recombination in Drug Resistance: A Dissertation

Calmann, Melissa A.

01 December 2004

Cells have evolved different pathways in order to tolerate damage produced by different cytotoxic agents. Each agent reacts differently with DNA causing formation of different types of adducts, each eliciting the SOS stress response to induce different cellular repair pathways. One such type of substrate generated by cytotoxic agents is the DNA double strand break (DSB). The main pathway to repair such damage in the cell is through a process of recombination. In this thesis, I specifically examined the anti-cancer therapeutic agent cisplatin, which forms single- and double-strand breaks in DNA, and methylating agents, which are proposed to also be capable of forming such breaks. Neither type of agent can directly form these breaks; however, they leave a signature type of damage lesion which is recognized by different repair processes. The mismatch repair (MMR) status of a mammalian cell or an Escherichia coli dam mutant relates directly to the sensitivity of the cells to the agents mentioned above. As the dam gene product plays an important role in this pathway and in other processes in the cell, when mutated, dam cells are more sensitive to methylating agents and cisplatin than wildtype. A combination of dam and either mutS or mutL restores resistance to the same agents to wild type levels. Therefore, mismatch repair sensitizes dam bacteria to these agents. The rationale for this comes from examining the viability of dam mutants, as dammutants are only viable because they are highly recombinogenic. The presence of MMR-induced nicks or gaps results in the formation of DSBs that require recombination to restore genomic integrity. Mismatch repair proteins inhibit recombination between homeologous DNA. Homeologous recombination (recombination between non-identical, but similar, DNA sequences) is only possible when the MMR proteins, MutS and MutL, are absent. It is postulated that this is because MutS recognizes the homeologous DNA and subsequently slows down or aborts recombination completely. The double mutant, dam mutS/L shows wild type levels of sensitivity to cisplatin because mismatch repair is no longer recognizing the adducts and recombinational repair is allowed to continue. Human cells behave in an analogous fashion to the bacterial dam mutant, showing sensitivity to cisplatin and methylating agents. When an additional mutation in a mismatch repair gene is present, the cells become as resistant as wild type. Therefore, the E. coli dammutant is a useful model system to study this mechanism of drug resistance. DNA containing cisplatin adducts or lesions resulting from methylation are substrates for other types of repair processes such as nucleotide excision repair and base excision repair; however they have also been implicated as substrates for MMR and recombinational repair. The goal of the work in this thesis was two-fold. The first was to identify the gene products and mechanism necessary for repair of cisplatin damage by recombination. The second was to examine the mechanism of cisplatin toxicity, and specifically how MMR proficiency aids in the cytotoxicity of this drug by preventing recombination. Using the duplicated inactive lac operon recombination assay, we were able to determine the requirements for spontaneous and cisplatin-induced recombination, the RecBCD and RecFOR pathways. We were also able to further postulate that the cisplatin- induced signature damage recognized by recombination was the double strand break, likely formed from fork stalling and regression or a subsequent collapse during DNA synthesis, thus requiring these pathways for repair. This observation led to the experiments involving examination of the mechanism of cisplatin toxicity and where MMR could inhibit specific steps of recombination with DNA containing cisplatin lesions. Low levels of cisplatin lesions slowed the rate of RecA-mediated strand transfer in vitro, likely due to its ability to form a large bend in the DNA. MutS bound to cisplatin lesions in the DNA during heteroduplex formation in the RecA strand exchange step of recombination, inhibiting branch migration, and aborting the reaction. In order for MutS to inhibit recombination with cisplatin lesions, the results in the work in Chapter IV, show that binding to the lesion requires the C-terminus of MutS to be present, possibly due to a requirement for tetramerization of the protein, a domain contained in the C-terminus of MutS. This antirecombination function is different than the mutation avoidance function of MutS, as binding of mismatches requires only dimers. This differential sensitivity for cisplatin versus a mismatch was further exemplified in Chapter V, the experiments with dna mutants, where the greatest difference in sensitivity was observed for a dnaE mutant (catalytic subunit of polIII), which was as sensitive to cisplatin as a dam mutant, but fairly resistant to treatment with MNNG. This is indicative of the potency of a cisplatin adduct to block polymerase progression, versus a mismatch which poses little problem to synthesis. Recombination is invoked to repair DSBs caused by the cisplatin lesions through the RecBCD and FOR pathways after fork regression or collapse. A main conclusion from these studies is that a cisplatin lesion is processed differently than a mismatch. The mechanism of how a cisplatin lesion is processed, forming the DSB which invokes recombinational repair is still unclear and continues to be investigated.

Drug Resistance

Cisplatin

Bacterial Proteins

Escherichia coli Proteins

DNA Repair

DNA Damage

Recombination

Genetic

Adenosinetriphosphatase

DNA-Binding Proteins

Amino Acids, Peptides, and Proteins

Bacteria

Cells

Enzymes and Coenzymes

Genetic Phenomena

Inorganic Chemicals

Neoplasms

Pharmaceutical Preparations

Therapeutics

Peptidyltransfer Reaction Catalyzed by the Ribosome and the Ribozyme: a Dissertation

Sun, Lele

08 May 2003

The "RNA world" hypothesis makes two predictions that RNA should have been able both to catalyze RNA replication and to direct protein synthesis. The evolution of RNA-catalyzed protein synthesis should be critical in the transition from the RNA world to the modem biological systems. Peptide bond formation is a fundamental step in modem protein biosynthesis. Although many evidence suggests that the ribosome is a ribozyme, peptide bond formation has not been achieved with ribosomal RNAs only. The goal of this thesis is to investigate whether RNA could catalyze peptide bond formation and how RNA catalyzes peptide bond formation. Two systems have been employed to approach these questions, the ribozyme system and the ribosome system. Ribozymes have been isolated by in vitro selection that can catalyze peptide bond formation using the aminoacyl-adenylate as the substrate. The isolation of such peptide-synthesizing ribozymes suggests that RNA of antiquity might have directed protein synthesis and bolsters the "RNA world" hypothesis. In the other approach, a novel assay has been established to probe the ribosomal peptidyltransferase reaction in the presence of intact ribosome, ribosomal subunit, or ribosomal RNA alone. Several aspects of the peptidyltransfer reaction have been examined in both systems including metal ion requirement, pH dependence and substrate specificity. The coherence between the two systems is discussed and their potential applications are explored. Although the ribozyme system might not be a reminiscence of the ribosome catalysis, it is still unique in other studies. The newly established assay for ribosomal peptidyltransferase reaction provides a good system to investigate the mechanism of ribosomal reaction and may have potential application in drug screening to search for the specific peptidyltransferase inhibitors.

Evolution

Molecular

RNA

Catalytic

RNA

Ribosomal

Protein Binding

Peptide Biosynthesis

Ribosomes

Peptidyl Transferases

Biological Assay

Amino Acids, Peptides, and Proteins

Cells

Pharmaceutical Preparations

Therapeutics

Analysis of Toll-Like Receptor 4 Signal Transduction and IRF3 Activation in the Innate Immune Response: A Dissertation

Rowe, Daniel C.

21 June 2006

Over the last decade, the innate immune system has been the subject of extensive research. Often overlooked by the robustness and specificity of the adaptive immune system, the innate immune system is proving to be just as complex. The identification of several families of pattern recognition receptors (PRRs) has revealed an ancient yet multifaceted system of proteins that are responsible for initiating host defense. A wide array of pathogens, from virus to bacteria, is detected using this assortment of receptors. One such family, the Toll-like receptors (TLRs), has been at the forefront of this research. To date, 10 TLRs have been described in the human genome. Activation of TLRs leads to the induction of immune-related genes that ultimately control the response of the host. However, the signaling pathways emanating from activated TLRs and other PRRs are not fully understood. In particular, the pathway leading to the activation of interferon regulatory factor 3 (IRF3), a transcription factor crucial for the induction of type I interferon, remains undefined. IRF3 activation occurs as the consequence of viral infection and through the activation of TLRs 3 and 4 by dsRNA and lipopolysaccharide (LPS), respectively. The focus of this research is to describe components of the IRF3 activation pathway, partly through the analysis of TLR signal transduction. IRF3 normally resides in the cytoplasm of cells. Upon infection with certain viruses and bacteria, IRF3 is activated though phosphorylation at its C-terminus. Phosphorylated IRF3 homodimerizes and associates with co-activators CBP-p300. After translocating to the nucleus, the activate IRF3 complex induces the activation of type 1 interferon and interferon related genes. Little is known about the pathways that lead to the activation of IRF3, especially the kinases involved. In this study we report that the non-canonical IкB kinase homologues, IкB kinase epsilon (IKKε) and TANK-binding kinase-1 (TBK1), which were previously implicated in NF-кB activation, are also essential components of the IRF3 signaling pathway. In particular, mouse embryonic fibroblasts from TBK1 deficient mice fail to activate IRF3 in response to both viral infection and stimulation with LPS or poly (IC), a dsRNA analog. Thus, both IKKε and TBK1 play a critical role in innate immunity and host defense. In addition to viral infection, IRF3 activation also occurs via the activation of TLR3 and 4. TLRs signal through a subfamily of Toll-IL-1-Resistance (TIR) domain containing adapter molecules. One such adapter, MyD88, is crucial for all TLRs, with the exception of TLR3. MyD88 participates in a signal transduction pathway culminating in the activation of the transcription factor NF-кB. Studies from MyD88-deficient mice reveal that both TLR3 and 4 still are capable of activating NF-кB, although with slightly delayed kinetics. Another aspect of the MyD88-independent signal transduction pathway is the activation of IRF3. A second TIR domain containing adapter molecule called Mal/Tirap was discovered and originally thought to mediate the MyD88-independent pathway. However, Mal-deficient mice were found to be defective in both TLR2 and 4 mediated NF-кB activation. We hypothesized that other TIR domain containing adapters could mediate this MyD88-independent pathway of TLR3 and 4 leading to the activation of IRF3. Two additional TIR adapters were discovered, TRIF and TRAM. TRIF was shown to mediate TLR3 signal transduction. In this study, we report that both TRIF and TRAM mediate the activation of the MyD88-independent pathway in response to LPS/TLR4 activation. Unlike any of the other known TIR domain containing adapters, TRAM appears to be restricted to the LPS/TLR4 activation pathway while TRIF plays a role in both TLR3 and TLR4 pathways leading to IRF3 target gene expression. Our studies revealed that TRAM could be acting upstream of TRIF in the LPS/TLR4 pathway. To this end, we sought to determine the localization of TRAM within the cell. We found that TRAM localizes to the plasma membrane. TRAM localization is the result of myristoylation since mutation of the predicted myristoylation site (G2A) resulted in the re-distribution of TRAM from the membrane into the cytoplasm. Reconstitution of TRAM-deficient macrophages with TRAM G2A is unable to rescue LPS/TLR4 signal transduction. Thus, myristoylation and membrane association of TRAM are critical for LPS/TLR4 signal transduction. The data generated in this dissertation extends our understanding of the signaling pathways of the innate immune system. Indeed, the molecules and pathways described herein could prove to be beneficial targets for ameliorating symptoms of disease, both autoimmune and pathogen-associated. Finally, the research described here will spur further insight into the complex signaling pathways of a once ignored arm of the immune system.

Immunity

Natural

Signal Transduction

Adaptor Proteins

Signal Transducing

Isoenzyme

Toll-Like Receptor 4

Antigens

Surface

Carrier Proteins

Lipopolysaccharides

Amino Acids, Peptides, and Proteins

Biological Factors

Carbohydrates

Enzymes and Coenzymes

Hemic and Immune Systems

Lipids

Attrition of CD8 T Cells during the Early Stages of Viral Infections: a Dissertation

Bahl, Kapil

09 January 2008

Profound lymphopenia has been observed during many acute viral infections, and our laboratory has previously documented a type 1 IFN-dependent loss of most memory (CD44hi) and some naïve (CD44lo) CD8 T cells immediately preceding the development of the antiviral T cell response at days 2-4 following lymphocytic choriomeningitis virus (LCMV) infection. In this thesis, I will examine additional mechanisms involved in the early attrition of CD8 T cells and evaluate whether antigen-specific and non-specific CD8 T cells are equally susceptible. Lastly, I will examine whether the early attrition of CD8 T cells contributes to the generation of an effective immune response. Poly(I:C), a potent inducer of type 1 IFN, was previously shown to cause the attrition and apoptosis of CD8α+CD44hi cells in normal mice, but not in type 1 IFN receptor–deficient mice (IFN1-R KO). I questioned whether additional molecule(s) might contribute to the type 1 IFN-induced apoptosis of CD8α+CD44hi cells. I used a PCR array to determine the expression of 84 apoptosis-related genes at 6 hours post-poly(I:C) treatment, relative to an untreated control. There was an 11-fold increase in CD40 RNA expression in CD8α+CD44hi cells isolated from poly(I:C)-treated mice. CD40 protein expression was also increased on CD8α+CD44hi cells, peaking between 9 and 12 hours following poly(I:C) treatment, before declining thereafter. This increase in CD40 protein expression directly correlated with an increase in Annexin V reactivity, an indicator of early apoptosis. Nevertheless, CD40 was not required for the loss of CD8α+CD44hi cells, as both wildtype and CD40-deficient mice were equally susceptible to the poly(I:C)-induced attrition. Upon further characterization, I found this population of CD40+CD8α+CD44hi cells to be CD11c+B220-Thy1.2- MHCIIhi, which is consistent with a “lymphoid” CD8α+ DC phenotype. Kinetic analysis revealed a type 1 IFN-dependent increase in this CD8α+ DC population at 12 hours post-poly(I:C) treatment. This increase was only observed in the spleen, as no increase in percentage was observed in the peritoneal cavity (PEC), lungs, inguinal lymph nodes (iLN), or peripheral blood. Collectively, these results suggest that the type 1 IFN-dependent increase in splenic CD8α+DCs accounts for the observed increase in Annexin V reactive cells following poly(I:C) treatment. These findings required a re-evaluation of the type 1 IFN-induced attrition of CD8+CD44hi T cells with an anti-CD8β antibody, which is a more exclusive marker for T cells than the anti-CD8α antibody. Kinetic analysis revealed a significant decrease in splenic CD8β+CD44hi T cells at 12 hours post-poly(I:C) treatment. This reduction in splenic CD8β+CD44hi T cells was not due to trafficking to other organs, as the PECs, lungs, iLN, lungs, and peripheral blood all exhibited significant, although varying, decreases in the percentage of CD8β+CD44hi T cells at 12 hour following poly(I:C) treatment. These data support the notion that the type 1 IFN-induced attrition of CD8β+CD44hiT cells was a “global” phenomenon and could not be completely due to migration out of the spleen. The attrition of CD8β+CD44hi T cells was also dependent upon type 1 IFN at 3 days post-LCMV infection, as there was no significant reduction of this population in IFN1-R KO mice. The loss of wildtype CD8β+CD44hi T cells correlated with an increased activation of caspases 3 and 8, which are enzymes that play essential roles in apoptosis and inflammation. A significant loss of CD4+CD44hi T cells, which also correlated with an increased activation of caspases 3 and 8, was observed at 3 days post-LCMV infection. Collectively, these results suggest that attrition of both CD4+CD44hi and CD8β+CD44hiT cell populations is type 1 IFN-dependent and associated with the activation of caspases following LCMV infection. At 3 days post-LCMV infection, both wildtype CD8β+CD44hi and CD4+CD44hi T cell populations had a higher frequency of cells with fragmented DNA, a hallmark characteristic of the late stages of apoptosis, as revealed by terminal transferase dUTP nick end labeling (TUNEL), relative to uninfected controls. This suggests that the loss of both populations was due to apoptosis. Therefore, I questioned whether the LCMV-induced apoptosis of both CD4+CD44hi and CD8β+CD44hi T cell populations occurred through a mitochondrial-induced pathway involving the pro-apoptotic molecule Bim. The attrition of both CD4+CD44hi and CD8β+CD44hi T cells was significantly higher in wildtype mice compared to Bim KO mice at 3 days post-LCMV infection. Moreover, both wildtype CD8β+CD44hi and CD4+CD44hi T cell populations had higher frequency of TUNEL+ cells, relative to Bim KO populations. These results suggest that the apoptosis of CD8β+CD44hi and CD4+CD44hiT cells, following LCMV infection, might occur through a mitochondrial-induced pathway involving Bim. Studies have shown “lymphoid” CD8α+ DCs to be involved in the phagocytosis of apoptotic lymphocytes. Therefore, I evaluated whether host CD8α+ DCs are capable of phagocytosing apoptotic lymphocytes by adoptively transferring CFSE-labeled wildtype donor splenocytes (Ly5.1) into congenic wildtype hosts (Ly5.2), followed by inoculation with poly(I:C). There was an increased frequency of donor cells (Ly5.1, CFSE+) within the host CD8α+CD11c+ gate at 9 and 12 hours post-poly(I:C) treatment. The results suggest that type 1 IFN-activated CD8α+DCs might aid in the rapid clearance of apoptotic cells during the type 1 IFN-induced attrition associated with viral infections. I next questioned whether TCR engagement by antigen would render CD8 T cells resistant to attrition. I tested whether a high concentration of antigen (GP33 peptide) would protect LCMV-specific naïve TCR transgenic P14 cells specific for the GP33 epitope of LCMV and GP33-specific LCMV-immune cells from depletion. Both naïve P14 and memory GP33-specific donor CD8 T cells decreased substantially 16 hours after inoculation poly(I:C), regardless of whether a high concentration of GP33 peptide was administered to host mice beforehand. The increased activation status of naïve antigen-specific cells via peptide inoculation did not confer resistance to type 1 IFN-induced depletion. Donor naïve P14 and LCMV-specific memory cells were also depleted from day 2 LCMV-infected (Clone 13) hosts by 16 hours post-transfer. These results indicate that antigen engagement does not protect CD8 T cells from the type 1 IFN-induced attrition associated with viral infections. Computer models indicated that early depletion of memory T cells may allow for the generation for a more diverse T cell response to infection by reducing the immunodomination caused by cross-reactive T cells. To test this in a biological system, I questioned whether the reduced apoptosis of the crossreactive memory CD8 population (NP205), in aged LCMV-immune mice (18-22 months), following heterologous virus challenge (PV), would allow it to dominate the immune response. At day 8 post-PV infection, the cross-reactive memory CD8 T cell response (NP205) was more immunodominating in aged LCMV-immune mice relative to younger LCMV-immune mice. This was indicated by the increased ratio of the cross-reactive NP205 response to the newly arising noncross-reactive, PV-specific NP38 response in older LCMV-mice relative to younger LCMV immune-mice, at day 8 post-PV infection. These data suggest that the early attrition of T cells allows for the generation of a more diverse T cell response to infection by reducing the immunodomination caused by crossreactive T cells. Collectively, these findings offer further insight into the early attrition of T cells associated with viral infections.

CD8-Positive T-Lymphocytes

Apoptosis

Immunologic Memory

Virus Diseases

Antigens

Viral

Glycoproteins

Interferons

Lymphocytic Choriomeningitis

Peptide Fragments

Amino Acids, Peptides, and Proteins

Biological Factors

Carbohydrates

Cells

Hemic and Immune Systems

Nervous System Diseases

Virus Diseases

SOX13, A γδ T Cell-Specific Gene, Is a WNT-Signaling Antagonist Regulating T Cell Development: A Dissertation

Melichar, Heather J.

19 May 2006

Mature αβ and γδ T cells arise from a common precursor population in the thymus. Much debate has focused on the mechanism of T cell lineage choice made by these multi-potential precursor cells. It is widely believed that the decision of these precursor cells to commit to the γδ or αβ T cell lineages is regulated primarily by a specific instructive signal relayed through the appropriate T cell receptor. Contrary to this model, we present evidence for a TCR-independent lineage commitment process. Comparison of global gene expression profiles from immature αβ and γδ lineage thymocytes identified Sox13, an HMG-box transcription factor, as a γδ T cell-specific gene. Unlike other HMG-box transcription factors such as TCF1, LEF1 and SOX4, that are critical for proper αβ T cell development, Sox13 expression is restricted to early precursor subsets and γδ lineage cells. Importantly, SOX13 appears to influence the developmental fate of T cell precursors prior to T cell receptor expression on the cell surface. Transgenic over-expression of Sox13 in early T cell precursors strongly inhibits αβ lineage development, in part, by inhibiting precursor cell proliferation and concomitantly, leading to increased cell death among αβ lineage subsets. Steady-state γδ T cell numbers, however, appear unaffected. Strikingly, the DP αβ lineage cells that do develop in Sox13 transgenic mice are imprinted with a γδ- or precursor-like molecular profile, suggesting that SOX13 plays an active role in the lineage fate decision process or maintenance. Sox13-deficient mice, on the other hand, have selectively reduced numbers of γδ thymocytes, indicating that SOX13 is essential for proper development of γδ T cells. We present additional data demonstrating that SOX13 is a canonical WNT signaling antagonist modulating TCF1 activity, raising a strong possibility that WNT signals, and their modulators, are at the nexus of γδ versus αβ T cell lineage commitment.

T-Lymphocytes

Genes

T-Cell Receptor gamma

Genes

T-Cell Receptor delta

Stem Cells

Cell Differentiation

Autoantigens

High Mobility Group Proteins

Transcription Factors

Amino Acids, Peptides, and Proteins

Cells

Genetic Phenomena

Hemic and Immune Systems

Characterization of the BACH1 Helicase in the DNA Damage Response Pathway: a Dissertation

Litman, Rachel

15 February 2007

DNA damage response pathways are a complicated network of proteins that function to remove and/or reverse DNA damage. Following genetic insult, a signal cascade is generated, which alerts the cell to the presence of damaged DNA. Once recognized, the damage is either removed or the damaged region is excised, and the original genetic sequence is restored. However, when these pathways are defective the cell is unable to effectively mediate the DNA damage response and the damage persists unrepaired. Thus, the proteins that maintain the DNA damage response pathway are critical in preserving genomic stability. One essential DNA repair protein is the Breast Cancer Associated gene, BRCA1. BRCA1 is essential for mediating the DNA damage response, facilitating DNA damage repair, and activating key cell cycle checkpoints. Moreover, mutations in BRCA1 lead to a higher incidence of breast and ovarian cancer, highlighting the importance of BRCA1 as a tumor suppressor. In an effort to better understand how BRCA1 carried out these functions, researchers sought to identify additional BRCA1 interacting proteins. This led to the identification of several proteins including the BRCA1 Associated C-terminal Helicase, BACH1. Due to the direct interaction of BACH1 with a region of BRCA1 essential for DNA repair and tumor suppression, it was speculated that BACH1 may help support these BRCA1 function(s). In fact, initial genetic screenings confirmed that mutations in BACH1 correlated not only with hereditary breast cancer, but also with defects in DNA damage repair processes. The initial correlation between BACH1 and cancer predisposition was further confirmed when mutations in BACH1 were identified in the cancer syndrome Fanconi anemia (FA) (complementation group FA-J), thus giving BACH1 its new name FANCJ. These findings supported a previously established link between the FA and BRCA pathways and between FA and DNA repair. In particular, we demonstrated that similar to other FA/BRCA proteins, suppression of FANCJ lead to a substantial decrease in homologous recombination and enhanced both the cellular sensitivity to DNA interstrand cross-linking agents and chromosomal instability. What remained unknown was specifically how FANCJ functioned and whether these functions were dependent on its interaction with BRCA1 or other associated partners. In fact, we identified that FANCJ interacted directly with the MMR protein MLH1. Moreover, we found that the FANCJ/BRCA1 interaction was not required to correct the cellular defects in FA-J cells, but rather that the FANCJ/MLH1 interaction was required. Although both the FA/BRCA and MMR pathways undoubtedly mediate the DNA damage response, there was no evidence to suggest that these pathways were linked, until recently. Our findings not only indicate a physical link between these pathways by protein-protein interaction, but also demonstrated a functional link.

DNA Damage

DNA Repair

Genes

BRCA1

BRCA Protein

Amino Acids, Peptides, and Proteins

Genetic Phenomena

Hemic and Lymphatic Diseases

Nutritional and Metabolic Diseases

Understanding Assembly of AGO2 RISC: the RNAi enzyme: a Dissertation

Matranga, Christian B.

17 September 2007

In 1990, Richard Jorgensen’s lab initiated a study to test if they could create a more vivid color petunia (Napoli et al. 1990). Their plan was to transform plants with the chalcone synthase transgene––the predicted rate limiting factor in the production of purple pigmentation. Much to their surprise, the transgenic plants, as well as their progeny, displayed a great reduction in pigmentation. This loss of endogenous function was termed “cosuppression” and it was thought that sequence-specific repression resulted from over-expression of the homologous transgene sequence. In 1998, Andrew Fire and Craig Mello described a phenomenon in which double stranded RNA (dsRNA) can trigger silencing of cognate sequences when injected into the nematode, Caenorhabditis elegans (Fire et al. 1998). This data explained observations seen years earlier by other worm researchers, and suggested that repression of pigmentation in plants was caused by a dsRNA-intermediate (Guo and Kemphues 1995; Napoli et al. 1990). The phenomenon––which soon after was coined RNA interference (RNAi)––was soon discovered to be a post-transcriptional surveillance system in plants and animals to remove foreign nucleic acids.

RNA Interference

MicroRNAs

RNA

Small Interfering

Drosophila Proteins

Methyltransferases

RNA-Induced Silencing Complex

RNA 3' End Processing

Plants

RNA Helicases

RNA-Binding Proteins

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Enzymes and Coenzymes

Modulation of Voltage-Gated N-Type Calcium Channels by G Protein-Coupled Receptors Involves Lipids and Proteins: A Dissertation

Mitra Ganguli, Tora

15 October 2008

Pain signaling involves transmission of nociceptive stimuli in the spinal cord where a critical balance between excitatory and inhibitory inputs determines the response to noxious stimuli. The neuropeptide, substance P (SP), mediates transmission of pain in part by binding to the tachykinin receptor (NK-1R) in the dorsal horn (DH) of the spinal cord. One of SP’s downstream effects is to modulate N-type Ca2+(N-) channels. While phospholipid breakdown is a part of the inflammatory process that accompanies tissue damage, the role of this metabolic pathway has not been completely described with respect to N-channel modulation during pain signaling. Despite the incomplete understanding of this modulation, pharmacological antagonists of both NK-1R and N-channels have been used to treat pain. In Chapter II, using whole-cell patch clamp recording techniques, the SP signaling cascade that mediates inhibition of recombinant N-channel activity was characterized. By adopting a pharmacological approach, I show that this pathway resembles the slow pathway that was earlier described for modulation of N-current by the M1 muscarinic receptor (M1R). M1R couples to Gq to stimulate phospholipid breakdown. Together with previous observations, the data presented in this chapter provide evidence for involvement of the extracellular receptor kinase (ERK1/2), phospholipase A2 and release of phospholipid metabolites in the modulation of N-current by SP. Overall, this chapter shows that phospholipid metabolism involved in modulation of N-currents is not specific to M1Rs but that other Gq-coupled receptors may also modulate N-currents via the same signal transduction pathway. In Chapter III, enhancement of N-current by SP was studied as part of a collaborative project to understand current enhancement that occurs when a palmitoylated accessory CaVβ2a subunit is co-expressed with the pore-forming subunit CaV2.2 and the accessory subunit α2δ-1. When CaVβ3 is present, SP inhibits N-current as described in Chapter II. However, when palmitoylated CaVβ2a is co-expressed with CaV2.2 (and α2δ-1), current enhancement is observed at negative test potentials, demonstrating that both M1Rs and NK-1Rs exhibit the same profile of N-current modulation. This change in modulation by muscarinic agonists is not observed in the presence of a depalmitoylated CaVβ2a. However a chimeric CaVβ2aβ1b subunit that contains the palmitoylated N-terminus from CaVβ2a confers enhancement. Normally expression of the β1b subunit resulted in current inhibition. These findings indicated that the palmitoylated CaVβ2a participates in enhancement of current. Our data support a model where inhibition dominates over enhancement; when inhibition is blocked, enhancement may be observed. Lastly, we show that N-current inhibition by SP is minimized when exogenous palmitic acid is applied to cells co-expressing CaVβ3 subunits with N-channels. These results indicate that the presence of palmitic acid can prevent N-current inhibition when SP is applied most likely by interacting with CaV2.2. We propose a model where palmitic acid occupies the inhibitory site and serves to antagonize inhibition by a lipid metabolite, which is most likely arachidonic acid. The CaVβ2a protein seems to have a role in positioning the palmitoyl groups near CaV2.2. This chapter provides a new role for protein palmitoylation where the palmitoyl groups of CaVβ2a are both necessary and sufficient to block inhibition of another protein: CaV2.2. In Chapter IV, I probe the role of the relative orientation of CaVβ2a and the pore-forming subunit of the N-channel in N-current modulation. Evidence is presented that shows that not just the presence of a palmitoylated CaVβ2a is necessary, but the relative orientation of CaVβ2a to CaV2.2 is critical for blocking inhibition. Using N-channel mutants that cause a change in the orientation of CaVβ2a relative to CaV2.2, I show that the block of inhibition is disrupted; inhibition by the slow pathway is rescued. These findings further support my model that the palmitoyl groups of CaVβ2a normally reside in a specific location that overlaps with the slow pathway inhibitory site on CaV2.2. Lastly I present data showing that the enhancement of N-current, observed when palmitoylated CaVβ2a is present, occurs via the slow pathway. In Chapter V the effect of CaVβ’s orientation on N-channel modulation by the dopamine D2 receptor is tested. In this form of modulation, inhibition is rapid and voltage-dependent. The signaling pathway is membrane-delimited since Gβγ, released after receptor stimulation, directly interacts with the N-channel at a site that overlaps with a high affinity binding site for CaVβs. While N-currents are modulated by this pathway, the deletion mutants show aberrant membrane-delimited modulation. The findings in this chapter further underscore the importance of proper positioning of CaVβ to CaV2.2 for eliciting proper N-current modulation after GPCR stimulation. Overall, the data presented in this dissertation provides a mechanistic approach into examining modulation of N-current by different GPCRs via two different signaling pathways as well as the role CaVβ subunits serve in each modulatory pathway.

Pain

Calcium Channels

N-Type

Nociceptors

Signal Tranduction

Substance P

Amino Acids, Peptides, and Proteins

Biological Factors

Life Sciences

Medicine and Health Sciences

Psychological Phenomena and Processes

piRNA Function and Biogenesis in the <em>Drosophila</em> Female Germline: A Dissertation

Klattenhoff, Carla Andrea

20 November 2008

The studies presented in this thesis addressed mainly two aspects of Piwi-interacting RNA (piRNA) biology in the Drosophilagermline. We investigated the role of the piRNA pathway in embryonic axis specification. piRNAs mediate silencing of retrotransposons and the Stellate locus. Mutations in the Drosophila piRNA pathway genes armitage and aubergine disrupt embryonic axis specification, triggering defects in microtubule polarization and asymmetric localization of mRNA and protein determinants in the developing oocyte. Mutations in the ATR/Chk2 DNA damage signal transduction pathway dramatically suppress these axis specification defects, but do not restore retrotransposon or Stellatesilencing. Furthermore, piRNA pathway mutations lead to germline-specific accumulation of γ-H2Av foci characteristic of DNA damage. We conclude that piRNA based gene silencing is not required for axis specification, and that the critical developmental function for this pathway is to suppress DNA damage signaling in the germline. We have also identified a new member of the piRNA pathway. We show that mutations in rhino, which encodes a rapidly evolving Heterochromatin Protein 1 (HP1) chromo box protein, lead to germline specific DNA break accumulation, trigger Chk2 kinase dependent defects in axis specification, and disrupt germline localization of Piwi proteins. Mutations in rhino and the piRNA pathway gene armitage disrupt silencing of all major transposon families, but do not alter expression of euchromatic or heterochromatic protein coding genes. Deep sequencing studies show that rhino mutations significantly reduce or eliminate anti-sense piRNAs derived from the majority of transposable elements in the Drosophila genome, and lead to a dramatic reduction in piRNAs derived from major piRNA production clusters on chromosomes 2R and 4. Rhino protein localizes to distinct nuclear foci, and associates with the chromosome 2R and 4 clusters by chromatin immunoprecipitation. The Rhino HP1 homologue is therefore required for piRNA biogenesis, transposon silencing, and maintenance of germline genome integrity.

RNA

Small Interfering

Drosophila Proteins

Biogenesis

Germ Cells

Body Patterning

Cell Cycle Proteins

Mutation

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Cells

Embryonic Structures

Genetic Phenomena

CIS/SOCS Proteins in Growth Hormone Action: A Dissertation

Du, Ling

01 October 2000

CIS/SOCS (cytokine-inducible SH2 protein/suppressor of cytokine signaling) are a family of proteins that are thought to act as negative regulators of signaling by erythropoetin, interleukin-6 and other cytokines whose receptors are related to the growth hormone receptor (GHR), and like growth hormone (GH), signal through the JAK/STAT pathway. We examined the possibility that CIS/SOCS proteins may also be involved in GH signaling, in particular, in termination of the transient insulin-like effects of GH. mRNAs for CIS, SOCS3, and to a lesser extent SOCS1 were detectable by Northern blot analysis of rat adipocyte total RNA, and the expression of CIS and SOCS3 was markedly increased 30 min after incubation with 500 ng/ml hGH. Both CIS and SOCS3 were detected in adipocyte extracts by immunoprecipitation and immunoblotting with their corresponding antisera. GH stimulated the tyrosine phosphorylation of a 120 kDa protein (p120) that was co-precipitated from adipocyte extracts along with αCIS and detected in Western blots with phospho-tyrosine antibodies. However, no tyrosine phosphorylated proteins in these cell extracts were immunoprecipitated with antibodies to CIS3/SOCS3. p120 was later identified as the GHR based on the observations that two GHR antibodies recognized p120 in scale-up experiments and that p120 and the GHR share several characteristics, including their molecular weights, tyrosine phosphorylation upon GH stimulation, interaction with CIS, similar extent of glycosylation as judged by electrophoretic mobility shift after Endo F digestion, comparable mobility shifts upon thrombin digestion, and N-terminal histidine-tagging. The findings, however, do not rule out the possibility that there might be other tyrosine phosphorylated 120 kDa protein(s) that interact with CIS and contribute to the p120 signal, as well as the GHR. Further studies of the association of CIS with the GHR revealed that CIS might selectively interact with multiply tyrosine phosphorylated forms of the GHR, and these tyrosines are likely located near the carboxyl end of the GHR. Overexpression of CIS partially inhibited GH-induced STAT5 phosphorylation in CHO cells. Studies in freshly isolated and GH-deprived (sensitive) adipocytes revealed that the abundance of CIS does not correlate with the termination of the insulin-like effects of GH or the emergence of refractoriness. Neither the association of CIS with the GHR nor the tyrosine phosphorylation status of the GHR, JAK2 and STAT5 appear responsible for refractoriness in adipocytes. These data imply that some negative regulators other than CIS might contribute to the termination of GH-induced insulin-like effects in adipocytes.

Immediate-Early Proteins

Human Growth Hormone

Human Growth Hormone

Cytokines

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Biological Factors

Cells