DISCOVERING A NOVEL ANTIFUNGAL TARGET IN DOWNSTREAM STEROL BIOSYNTHESIS USING A SQUALENE SYNTHASE FUNCTIONAL MOTIF

Linscott, Kristin Brooke

01 January 2017

The sterol biosynthetic pathway is essential for growth of all eukaryotic cells and the main target of antifungal agents. The emergence of resistance to these antifungals in an already ill patient population indicates a need to develop drugs that have a broad spectrum of activity among pathogenic fungi and have minimal patient toxicity. Squalene synthase is the first committed step in the sterol pathway and has been studied intensively for development of antifungal agents. While the overall architecture of this enzyme is identical throughout eukaryotes, it was shown that plant and animal genes cannot complement a squalene synthase knockout mutation in yeast unless the carboxy-terminal domain is swapped for one of fungal origin. This implies that there is a component of the fungal carboxy-terminal domain that is responsible for the complementation phenotype and that is unique to the fungal kingdom of life. To determine the role of the carboxy-terminal domain of squalene synthase in the sterol pathway, we used the yeast Saccharomyces cerevisiae with a squalene synthase knockout mutation and expressed squalene synthases originating from fungi, plants, and animals. In contrast to previous observations, all enzymes tested could partially complement the knockout mutation when the genes were weakly expressed. When induced, non-fungal squalene synthases could not complement the knockout mutation and instead led to the accumulation of carboxysterol intermediates, suggesting an interaction between squalene synthase and the downstream sterol C4-decarboxylase. Overexpression of a sterol C4-decarboxylase from any kingdom of life both decreased the accumulation of carboxysterol intermediates and allowed non-fungal squalene synthases to complement the squalene synthase knockout mutation. Using chimeric squalene synthases from each kingdom of life, the motif in the C-terminal domain responsible for preventing this toxicity was mapped to a kingdom-specific 26-amino acid hinge motif adjacent to the catalytic domain. Furthermore, over-expression of the carboxy-terminal domain alone containing a hinge motif from fungi, not from animals or plants, led to growth inhibition of wild-type yeast. Since this hinge region is unique to and highly conserved within each kingdom of life, this data provides evidence for the development of an antifungal therapeutic as well as for tools to develop an understanding of triterpene catalytic activity and identify similar motifs in other biosynthetic pathways.

Squalene Synthase

Kingdom-specific Motif

Genetic Complementation

Sterol C4-decarboxylase

Growth Inhibition

Amino Acids, Peptides, and Proteins

Bacterial Infections and Mycoses

Enzymes and Coenzymes

Lipids

Molecular Mechanisms of Neurite Complexity in the <em>Drosophila</em> Brain: A Dissertation

Shi, Lei

07 June 2010

Development of functional neural circuits involves a series of complicated steps, including neurogenesis and neuronal morphogenesis. To understand the molecular mechasnims of neurite complexity, especially neurite branching/arborization, the Drosophila brain, especially MBNs (mushroom body neurons) and PNs (projection neurons) in olfactory circuitry, was used in this dissertation work as the model system to study how two molecules, Dscam and Kr-h1 affect neurite complexity in the Drosophilabrain. For the Drosophila Dscam, through alternative splicing it could encode up to 152,064 distinct immunoglobulin/fibronectin type cell adhesion molecules. Each Dscam isoform is derived from one of the 19,008 ectodomain variants connected with one of the two alternative transmembrane segments and one of the four possible endodomain portions. Recent studies revealed that Dscam was widely required for neurite branching/arborizaiton. However, due to the technical difficulty, the functional roles of Dscam transmembrane variants and ectodomain variants remain unclear. In this thesis work, a microRNA based RNA interference was used to knock down distinct subsets of Dscam isoform. First, loss of Dscam[TM1] versus Dscam[TM2], two distinct Dscam transmembrane variants, disrupted the dendritic versus axonal morphogenesis, respectively. Furthermore, structural analysis suggested that the juxtamembrane portion of transmembrane segment was required for the Dscam protein targeting in dendrites/axons and this differential protein targeting might account for the functional distinction between Dscam[TM1] and Dscam[TM2]. Second, to further address the functional significance of having two Dscam transmembrane variants in axons versus dendrites, the possibility that there might be different usage of Dscam repertoire between axons and dendrites that lead to different levels of morphological complexity between axons and dendrites in the same neuron was examined. To this end, end-in targeting approaches were used to exchange Dscam populations between axons and dendrites. Though the genetic data suggested that Dscam populations were exchanged between axons and dendrites, the phenotypic analysis in various neuronal types revealed that depending on the neuronal types, exchange of Dscam populations between axons and dendrites might primarily affect either axonal or dendritic morphology, suggesting that different usage of Dscam population between axons and dendrites might regulate complex patterns of neurite morphology. Finally, the functions of Dscam exon 4 variants had been addressed in different model neurons in the Drosophilabrain. First, 12 Dscam exon 4 variants were divided into three groups based on their phylogenetic distance. Then, three miRNA constructs were engineered to knock down one group at a time. The genetic data suggested that different Dscam exon 4 variants are differentially required in different neurons to support their proper neuronal morphogenesis. In summary, this part of my thesis work identified and characterized previously unrecognized functions of all these distinct Dscam variants and provided novel insights into how diverse Dscam isoforms regulate the different aspects of neuronal morphogenesis. In the honey bee brain, Kr-h1 is upregulated during the behavioral shift from nursing to foraging when there is increased neurite branching in the brain. To directly examine the hypothesis that altered Kr-h1 expression might regulate morphological complexity of neurites, this research work involved the MARCM (mosaic analysis with a repressible cell marker) and TARGET (temporal and regional gene expression targeting) techniques to analyze the roles of Kr-h1 in Drosophila neuronal morphogenesis. Interestingly, increased expression of Kr-h1 blocked the axon branching and further disrupted the lobe formation in the mushroom body whereas the loss-of-Kr-h1 did not show any apparent neuronal morphogenetic defects. In addition, it was observed that Kr-h1 was expressed when MB (mushroom body) did not undergo active morphogenesis, suggesting its potential anti-morphogenetic activity. Indeed, loss of Kr-h1 (Kruppel homolog 1) enhanced the neuronal morphogenesis that was otherwise delayed due to the defective TGF-beta signaling. Furthermore, Kr-h1 expression was closely linked to ecdysone dependent signaling: Kr-h1 was first regulated by usp (ultraspiracle), which dimerized with various ecdysone receptors and then Kr-h1 expression was essential for proper ecdysone patterning in the larval CNS (central nervous system). Together, though Kr-h1could potentially regulate the neurite complexity, it seems primarily involved in the coordinating ecdysone signaling. In conclusion, the powerful genetic toolkit available in the Drosophila has allowed the investigation in the molecular mechanisms of neuronal morphogenesis and understanding of these mechanisms will enhance our understanding of how the complex nervous system is wired to perform the delicate behaviors.

Drosophila

neurite complexity

neuronal morphogenesis

Drosophila Proteins

Neurites

Cell Adhesion Molecules

Kruppel-Like Transcription Factors

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Cells

Nervous System

Neuroscience and Neurobiology

Cooperativity in Mammalian RNA Silencing: A Dissertation

Broderick, Jennifer A.

26 July 2011

Argonaute proteins are the core component of an RNA silencing complex. The human genome encodes four Argonaute paralogs –Ago1, Ago2, Ago3 and Ago4– proteins that are guided to target mRNAs by microRNAs. More than 500 miRNAs are conserved between mammals, and each microRNA can repress hundreds of genes, regulating almost every cellular process. We still do not fully understand the molecular mechanisms by which miRNAs regulate gene expression. Although we understand many aspects of microRNA biogenesis and formation of the RNA-induced silencing complex, much less is known about the subsequent steps leading to target mRNA regulation. Mammalian microRNAs rarely have complete complementarity to their target mRNAs so, instead of endonucleolytic cleavage by Ago2, microRNAs destabilize or repress translation of target mRNAs. Here I explored the functional limits of Argonaute proteins bound to their targets directly and indirectly through microRNAs in mammalian cells. I revealed the different abilities for Argonaute proteins bound at multiple sites in a target to generate cooperativity in silencing based on the extent of pairing between the microRNA and target mRNA. Further, I harnessed the endogenous microRNA silencing mechanism to repress an mRNA that is not a direct target of the microRNA by tethering the RNA-induced silencing complex to the 3´ UTR of an mRNA. This strategy allows tissue-specific gene silencing due to the limited endogenous expression profile of the recruited microRNA. Efforts made herein further our mechanistic knowledge of microRNA-induced gene silencing in mammalian cells and advance microRNA-based strategies toward treating human disease.

RNA Interference

MicroRNAs

RNA-Induced Silencing Complex

Amino Acids, Peptides, and Proteins

Cells

Genetic Phenomena

Genetics and Genomics

Life Sciences

Medicine and Health Sciences

Neuroscience and Neurobiology

Tissues

Characterization of the Interaction Between the Attachment and Fusion Glycoproteins Required for Paramyxovirus Fusion: a Dissertation

Melanson, Vanessa R.

16 December 2005

The first step of viral infection requires the binding of the viral attachment protein to cell surface receptors. Following binding, viruses penetrate the cellular membrane to deliver their genome into the host cell. For enveloped viruses, which have a lipid bilayer that surrounds their nucleocapsids, entry into the host cell requires the fusion of viral and cellular membranes. This process is mediated by viral glycoproteins located on the surface of the virus. For many enveloped viruses, such as influenza, Ebola, and human immunodeficiency virus, the fusion protein is responsible for mediating both attachment to cellular receptors and membrane fusion. However, paramyxoviruses are unique among fusion promoting viruses because their receptor binding and fusion activities reside on two separate proteins. This unique distribution of functions necessitates a mechanism by which the two proteins can transmit the juxtaposition of the viral and host cell membranes, mediated by the attachment protein (HN/H), into membrane fusion, mediated by the fusion (F) protein. This mechanism allows for paramyxoviruses to gain entry into and spread between cells, and therefore, is an important aspect of virus infection and disease progression. Despite the conservation of receptor binding activity among members of the Paramyxovirinaesubfamily, for most of these viruses, including Newcastle disease virus (NDV), heterologous HN proteins cannot complement F in the promotion of fusion; both the HN and F proteins must originate from the same virus. This is consistent with the existence of a virus-specific interaction between the two glycoproteins. Thus, one or more domains on the HN and F proteins is thought to mediate a specific interaction between them that is an integral part of the fusion process. Therefore, the primary focus of this thesis is the identification of the site(s) on HN that directly contacts F in the HN-F interaction. The ectodomain of the HN protein consists of a stalk and a terminal globular head. Analysis of the fusion activity of chimeric paramyxovirus HN proteins indicates that the stalk region of HN determines its F protein specificity. The first goal of this research was to address the question of whether the stalk not only determines F-specificity, but does so by directly mediating the interaction with F. To establish a correlation between the amount of fusion and the extent of the HN-F interaction, a specific and quantitative co-immunoprecipitation assay was used that detects the HN-F complex at the cell surface. As an initial probe of the role of the HN stalk in mediating the interaction with F, N-glycans were individually added at several positions in the region. N-glycan addition at positions 69 and 77 in the stalk specifically and completely block both fusion and the HN-F interaction without affecting either HN structure or its other activities. However, though they also prevent fusion, N-glycans added at other positions in the stalk also modulate activities that reside in the globular head of HN. This correlates with an alteration of the tetrameric structure of the protein as indicated by sucrose gradient sedimentation analyses. These additional N-glycans likely indirectly affect fusion, perhaps by interfering with changes in the conformation of HN that link receptor binding to the fusion activation of F. To address the issue of whether N-glycan addition at any position in HN would abolish fusion, an N-glycan was added in another region at the base of the globular head of HN (residues 124-152), which was previously predicted by a peptide-based analysis to mediate the interaction with F. HN carrying this additional N-glycan exhibits significant fusion promoting activity, arguing against this site being part of the F-interactive domain in HN. These data support the idea that the F-interactive site on HN is defined by the stalk region of the protein. Site-directed mutagenesis was used to begin to explore the role of individual residues in the stalk in the interaction with F. The characteristics of the F-interactive domain in the stalk of HN are that it is a conserved motif with enough sequence heterogeneity to account for the specificity of the interaction. One such region that meets these requirements is the intervening region (IR) (residues 89-95); a non-helical domain situated between two conserved heptad repeats. Several amino acid substitutions for a completely conserved proline residue in this region impair not only fusion and the HN-F interaction, but also decrease neuraminidase activity in the globular domain and alter the structure of the protein, suggesting that the substitutions indirectly affect the HN-F interaction. Substitutions for L94 also interfere with fusion, but have no significant effect on any other HN function or its structure. Amino acid substitutions at two other positions in the IR (A89 and L90) also modulate only fusion. In all cases, diminished fusion correlates with a decreased ability of the mutated HN protein to interact with F at the cell surface. These findings indicate that the IR is critical to the role of HN in the promotion of fusion and are consistent with its direct involvement in the interaction with the homologous F protein. These are the first point mutations in the HN protein for which a correlation has been demonstrated between the extent of the HN-F interaction and the amount of fusion. This argues strongly that the co-IP assay is an accurate reflection of the HN-F interaction. The second goal of this research was to address the HN-F interaction from the perspective of the F protein by investigating the relationship between receptor binding, the HN-F interaction, and fusion using a highly fusogenic form of the F protein. It has previously been shown that an L289A substitution in NDV F eliminates the requirement for HN in the promotion of fusion and enhances HN-dependent fusion above wild-type (wt) levels. Here, it was shown that the HN-independent fusion exhibited by L289A-F in Cos-7 cells cannot be duplicated in BHK cells. However, when L289A-F is co-expressed with wt HN, enhanced fusion above wt levels is observed in BHK cells. Additionally, when L289A-F is co-expressed with IR-mutated HN proteins previously shown to promote low levels of fusion with wt F, a 2.5-fold increase in fusion was observed. However, similar to wt F, an interaction between L289A-F and the IR-mutated HN proteins was not detected. These results imply that the attachment function of HN, as well as the conformational change in L289A-F, are necessary for the enhanced level of fusion exhibited by HN proteins co-expressed with L289A-F. Indeed, two MAbs detected a conformational difference between L289A-F and the wt F protein. These findings support the idea that the L289A substitution converts F to a form that is less dependent on an interaction with HN for conversion to the fusion-active form. The last goal of this research was to address the cellular site of the HN-F interaction, still a controversial issue based on conflicting data from studies of different paramyxoviruses, using various approaches. This is a particular point of interest, as it speaks to the mechanism by which the HN-F interaction regulates fusion. Thus, NDV HN and F were successfully retained intracellularly with a multiple arginine or KK motif, respectively. The results of Endoglycosidase H resistance and F cleavage studies indicate that the mutated proteins, HN-ER and F-ER, are retained in a compartment prior to the medial-Golgi apparatus and that they are unable to interact with a high enough affinity to co-retain or even cause reduced transport of their wt partner glycoproteins. This is consistent with the HN-F interaction occurring at the cell surface, possibly triggered by receptor binding. In conclusion, this thesis presents evidence to argue that the IR in the stalk of the NDV HN protein directly mediates the interaction with the F protein that is necessary for fusion. Overall, the data presented in this thesis extend the current knowledge of the mechanism by which the paramyxovirus attachment protein can trigger the F protein to initiate membrane fusion. A clear understanding of this process has the potential to identify new anti-viral strategies, such as small molecule inhibitors, aimed at controlling paramyxovirus infection by interfering with early steps in the virus infection cycle.

Paramyxovirinae

Antibodies

Monoclonal

HN Protein

Membrane Fusion

Receptors

Virus

Viral Fusion Proteins

Newcastle disease virus

Amino Acids, Peptides, and Proteins

Carbohydrates

Viruses

The Function of the Tyrosine Kinase, Itk, in CD4+ T Cell Differentiation and Death: a Dissertation

Miller, Andrew Todd

31 July 2003

The Tec family tyrosine kinase, Itk, plays an important role in signal transduction following T cell receptor engagement. Several prior studies have established the importance of Itk in immune system processes, such as T cell development and T cell activation. Additional biochemical studies have found that Itk specifically functions within a multi-molecular signalosome complex, which ultimately functions to provide a platform by which Itk can phosphorylate and activate PLC-γ1, a crucial step in T cell activation. To further study how Itk regulates distinct immune outcomes via T cell effector processes within the peripheral immune system, and to further understand how Itk functions in T cells in response to a physiological ligand-receptor interaction, I crossed Itk-deficient mice to mice transgenic for a TCR specific for a moth cytochrome C peptide. My studies have established a unique role for Itk in several important aspects of T cell function. Following T cell activation, I identified an imperative role for Itk in activation-induced cell death via FasL, a mechanism of immune homeostasis. Furthermore, I found Itk plays a unique role in the process of T cell differentiation, where Itk positively regulates the induction of cytokine genes, such as IL-4, while negatively regulating the induction of T-bet, a transcription factor important for Th1 differentiation. Lastly, following T cell differentiation, I found that Itk mRNA and protein are up-regulated during Th2 differentiation, while Rlk, a related Tec kinase, disappears rapidly from Th2 cells, indicating a critical role for Itk in Th2 cell function. Collectively, my thesis work has more clearly defined an important function for Itk not only in TCR signaling, but also in immune processes such as T cell differentiation and activation-induced cell death that are required for proper immune function.

CD4-Positive T-Lymphocytes

Immunity

Cellular

Protein-Tyrosine Kinase

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Cells

Enzymes and Coenzymes

Hemic and Immune Systems

A Characterization of Substrates and Factors Involved in Yeast Nonsense-Mediated mRNA Decay: A Dissertation

Belk, Jonathan Philip

08 January 2002

Many intricate and highly conserved mechanisms have evolved to safeguard organisms against errors in gene expression. The nonsense-mediated mRNA decay pathway (NMD) exemplifies one such mechanism, specifically by eliminating mRNAs containing premature translation termination codons within their protein coding regions, thereby limiting the synthesis of potentially deleterious truncated polypeptides. Studies in Saccharomyces Cerevisiae have found that the activity of at least three trans-acting factors, known as UPF1, UPF2/NMD2, and UPF3is necessary for the proper function of the NMD pathway. Further research conducted in yeast indicates that the degradation of substrates of the NMD pathway is dependent on their translation, and that the sub-cellular site of their degradation in the cytoplasm. Although most evidence in yeast suggests that substrates of the NMD pathway are degraded in the cytoplasm while in association with the translation apparatus, some mammalian studies have found several mRNAs whose decay appears to occur within the nucleus or before their transport to the cytoplasm has been completed. In addition, study of the mammalian TPI mRNA found that this transcript was unavailable as a substrate for the NMD pathway once it had been successfully exported to the cytoplasm, further supporting the notion that the degradation of mammalian substrates of the NMD pathway occurs in association with the nucleus, or during export from the nucleus to the cytoplasm. To determine if yeast cytoplasmic nonsense-containing mRNA can become immune to the NMD pathway we examined the decay kinetics of two NMDS substrate mRNAs in response to repressing or activating the NMD pathway. Both the ade2-1 and pgk1-UAG-2nonsense-containing mRNAs were stabilized by repressing this pathway, while activation of NMD resulted in the rapid and immediate degradation of each transcripts. These findings demonstrate that nonsense-containing mRNAs residing in the nucleus are potentially susceptible to NMD at each round of translation. The remainder of this thesis utilizes protein overexpression studies to gain understanding into the function of factors related to the processes of nonsense-mediated mRNA decay and translation in Saccharomyces cerevisiae. Overexpression of a C-terminal truncated form of Nmd3p was found to be dominant-negative for cell viability, translation and the normal course of rRNA biogenesis. Overexpression studies conducted with mutant forms of the nonsense-mediated mRNA decay protein Upf1p, found that overexpression of mutants in the ATP binding and ATP hydrolysis region ofUpflp were dominant-negative for growth in an otherwise wild-type yeast strain. Furthermore, overexpression of the ATP hydrolysis mutant of Upf1p (DE572AA), resulted in the partial inhibition of NMD and a general perturbation of the translation apparatus. These results support previous studies suggesting a general role for Upf1p function in translation.

RNA-Binding Proteins

RNA Stability

Saccharomyces cerevisiae Proteins

Trans-Activators

Translation

Genetic

Amino Acids, Peptides, and Proteins

Cells

Fungi

Transport of Nucleotide Derivatives into Endoplasmic Reticulum and Golgiapparatus Derived Vesicles: a Dissertation

Clairmont, Caroline A.

01 May 1993

In mammals, newly synthesized proteins destined for secretion are translocated cotranslationally into the lumen of the Endoplasmic Reticulum (ER). Once inside, these nascent polypeptide chains are bound by a lumenal ER protein called BiP (Immunoglobulin Binding Protein) or Grp 78 (Glucose Regulated Protein 78). It is hypothesized that this binding is necessary to protect the nascent chains until they are properly folded or assembled with other subunits. When the proteins are folded and assembled, they are released from BiP by a process that is dependent on ATP hydrolysis. Since ATP is synthesized mainly in the mitochondria, we hypothesized that there must be an ATP transporter in the ER which would allow the protein mediated transport of ATP from the cytosol into the ER lumen. We studied the transport of ATP in vitro and found that ATP enters the lumen of the ER in a saturable manner with a Kmapp~3μM. ATP transport is dependent on time, protein, and vesicle integrity, it is also inhibited by the general anion transport inhibitor, 4,4' diisothiocyano-2,2'-disulfonic acid stilbene (DIDS). We also found that the transport was inhibited by membrane impermeable protein modifying agents such as N-ethlymaleamide (NEM) and Pronase when added to intact ER vesicles. These results suggest that the transport is mediated by a protein with an active cytoplasmic face. Using monoclonal and polyclonal antibodies to BiP and Grp94 (another resident ER protein) and U.V. crosslinking, we demonstrated that after transport of ATPα32P into intact vesicles, radiolabeled BiP and Grp94 could be immunoprecipitated. We also found that labeling of lumenal proteins with ATP is dependent on the transport of ATP. Finally using ATP labeled with 35S, we concluded that BiP was able to bind intact ATP and we confirmed earlier work that BiP was thiophosphorylated while Grp94 is not. The second area of study involves processes that occur further along the secretory pathway in the Golgi apparatus. It was known from previous work that the nucleotide sugar substrates necessary for the synthesis of the linkage region, UDP-xylose (UDP-Xyl), UDP-galactose (UDP-Gal) and UDP-glucuronic acid (UDP-GlcA) were transported into the Golgi apparatus from the cytosol via protein mediated transporters. In order to eventually purify one of these transporter proteins, we wanted to reconstitute their activities. We were able to reconstitute the activities that exhibited kinetic parameters and inhibitor sensitivities very similar to those seen in intact Golgi vesicles. In the case of UDP-xylose it was necessary to prepare the liposomes using endogenous Golgi lipids in order to get transport activity similar to that seen in the intact Golgi vesicles. This suggested a specific lipid requirement for the UDP-xylose transporter. These transporters seem to be antiporters, whereby the nucleotide sugar enters the lumen of the Golgi coupled to the equimolar exit of the corresponding nucleoside monophosphate (Hirschberg, C.B. and Snider, M.D. 1987). We also showed that we could reproduce the hypothesized antiporter system in the reconstituted proteoliposomes by preloading the proteoliposomes with the putative antiporter molecule UMP. The rationale for developing the reconstituted system is eventually to use this system to purify one of these nucleotide sugar translocators. In the last set of studies, I have shown that this reconstituted system can be used to monitor the purification of the UDP-galactose translocator. Using column chromatography we were able to purify this membrane translocator protein 45,000 fold from a rat liver homogenate.

Endoplasmic Reticulum

Golgi Apparatus

Nucleotides

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Cells

Digestive System

Investigative Techniques

The Role of ITK and RLK in CD8+ T Cell Development and Function: a Dissertation

Atherly, Luana O

26 July 2004

Itk and Rlk are members of the Tec kinase family of non-receptor protein tyrosine kinases that are preferentially expressed in T cells. Numerous previous studies have demonstrated that these proteins play an important a role in the regulation of signalling processes downstream of TCR activation in CD4+ T cells, particularly in the phosphorylation of PLCγl. In addition, Itk and Rlk have both been shown to be important for CD4+ T cell development, differentiation, function and homeostasis following TCR activation. In the absence of Itk and Rlk, CD8+ SP thymocytes and T cells develop a memory/previously activated phenotypic profile, however, very little is known about the influence of Itk and Rlk on CD8+ T cell development and function. This study illustrates a previously unappreciated role for Itk and Rlk in the regulation of cytokine signals during CD8+ SP thymocyte maturation, and in the development of the memory CD44hi profile of Itk -/- and Itk -/- Rlk -/- CD8+ SP thymocytes and CD8+ T cells. This study also provides the first detailed study of the role of loss of Itk and particularly both Itk and Rlk in CD8+ signalling and function and shows that these Tec kinase family members play an important role in the maintenance of CD8+ T cell fitness and function, particularly in the ability of CD8+ T cells to accumulate in response to infection. Collectively, my studies demonstrate a critical role for Itk and Rlk in the generation of optimal CD8+ T cell responses. They also raise the novel observation that these proteins may be involved on the regulation of cytokine signals in T cells.

Protein-Tyrosine Kinase

CD8-Positive T-Lymphocytes

CD4-Positive T-Lymphocytes

Cytokines

Amino Acids, Peptides, and Proteins

Biological Factors

Cells

Enzymes and Coenzymes

Hemic and Immune Systems

The Stimulation of Luteinizing Hormone Secretion from Anterior Pituitary Cells in Culture by Substance P: A Dissertation

Shamgochian, Maureen

01 May 1990

The observations that substance P (SP) is localized in the anterior pituitary gland (AP) and is regulated by the hormonal status of the animal, as well as the demonstration of SP binding sites in the AP, have led to the idea that SP may participate in the regulation of AP function. Numerous and sometimes contradictory reports of SP effects on AP hormone secretion, particularly on luteinizing hormone (LH), left the question of whether SP acts directly at the level of the AP to regulate LH secretion still unanswered. To investigate a possible physiological function of SP in the AP, the effects of exogenous SP on LH secretion from AP cells from adult and prepubertal male and female rats in short term culture were studied. It was found that SP (100nM-1μM) significantly stimulates LH release in cultured AP cells and that this effect varies as a function of age and sex. SP has no significant effect on LH release from AP cells of male and female prepubertal rats. After day 30 a sharp increase in the response to SP occurs in both sexes. This level of responsiveness continues through adulthood in AP cells from the female rat. In contrast, AP cells from male rats failed to respond during adulthood (over 50 days of age) but were highly responsive during the peripubertal period (30-35 days). The possibility that the responsiveness to SP is influenced by the endocrine status of the animal was investigated by exposing AP cells from responding animals to androgens in vivo and in vitro. It was found that AP cells from female rats treated with androgen were less responsive to 100nM SP but did respond at higher doses of SP. SP effects on AP function were further analyzed in experiments using radioligand binding assays to assess possible changes in SP receptor number or affinity as related to age and sex. In AP membranes from female rats, maximum binding is 8-fold higher (Bmax=4.2 pmo1/mg membrane protein) than in AP membranes from male rats (Bmax=560fmo1/ mg membrane protein). These studies suggest a role for SP as a secondary regulator of LH secretion with possible physiological significance for reproductive function.

Pituitary Gland

Anterior

Luteinizing Hormone

Substance P

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Biological Factors

Cells

Endocrine System

Nervous System

Regulation of IgA Class Switch Recombination in the I.29μ B Cell Lymphoma by Cytokines and Inhibitors of Poly(ADP-ribose) Polymerase: A Thesis

Shockett, Penny E.

01 September 1993

Heavy chain isotype switch recombination is preceded by the appearance of RNA initiating 5' of the specific switch region which will undergo recombination. In an effort to understand the potential function of germline transcripts in switch recombination and the degree to which the regulation of germline transcripts correlates with the regulation of switching, we studied this process in the murine B-lymphoma cell line I.29μ, which in the presence of bacterial lipopolysaccharide (LPS) switches primarily to IgA and less frequently to IgE. Levels of α-germline transcripts initiating upstream of α switch (Sα) sequences are elevated in clones of this line which switch well as compared to clones which switch less frequently. TGFβ1 has been shown to increase α-germline transcripts and switching to IgA expression in LPS-stimulated murine splenic B-cells. We now demonstrate in I.29μ cells that TGFβ also increases switching to IgA and increases the level of α-germline transcripts 5 to 9 fold. Nuclear run-on analysis shows that this increase is at the level of transcription. Thus, TGFβ appears to direct switching to IgA by inducing transcription from the unrearranged Sα- CαDNA segment. Germline α RNA is quite stable in I.29μ cells, having a half life of about 3 to 5 hours, and we find only slight stabilization in the presence of TGFβ. Levels of ε-germline transcripts are not increased by TGFβ . IL-4, which modestly increases switching to IgA in I.29μ cells, slightly increases trancription of α-germline RNA. However, we present evidence suggesting that endogenously produced IL-4 may also act at additional levels to increase switching to IgA. IFNγ, which reduces IgA expression in these cells, also reduces the level of α-germline transcripts. IFNγ also reduces the level of ε-germline transcripts induced by IL-4. Our results support the hypothesis that the regulation of transcription of particular switch sequences by cytokines in turn regulates the specificity of recombination. In studies aimed at identifying other signalling pathways that promote class switching, we discovered that inhibitors of the nuclear enzyme poly(ADP-ribose) polymerase (PARP) increase lipopolysaccharide (LPS)-induced switching to IgA in the B cell lymphoma I.29μ and to IgG1 in LPS + IL-4-treated splenic B cells. PARP, which binds to and is activated by DNA strand breaks, catalyzes the removal of ADP-ribose from NAD+ and poly(ADP-ribosylation) of chromatin-associated acceptor proteins. This enzyme is believed to function in cellular processes involving DNA strand breaks as well as in modulating chromatin structure. In I.29μ cells, PARP inhibitors increase IgA switching by day 2 and cause a 5-fold average increase in switching on day 3 as assayed by immunofluorescence microscopy. The PARP inhibitor, nicotinamide, also causes a reduced intensity of hybridization of Cμ and Cα specific probes to genomic DNA fragments containing the expressed VDJ-Cμ and the unrearranged Sα - Cα segments, respectively, indicating that PARP inhibition increases rearrangment of these fragments. Induction of switching by PARP inhibitors is not mimicked by treatment with cAMP analogs or reduced by inhibitors of protein kinase A (PKA). Induction of switching by PARP inhibitors does not appear to involve increased levels of transcription of the unrearranged Cα gene, although TGFβ is required for optimal induction by PARP inhibitors, consistent with a requirement for transcription of the unrearranged CH gene. PARP inhibitors do not overcome the requirement for endogenously produced IL-4.

Immunoglobulin A

Immunoglobulin Switch Region

Lymphoma

B-Cell

ADP Ribose Transferases

Amino Acids, Peptides, and Proteins

Carbohydrates

Cells

Enzymes and Coenzymes

Genetic Phenomena

Hemic and Lymphatic Diseases

Immune System Diseases

Neoplasms