Functional Analysis of the Murine Oligoadenylate Synthetase 1b (Oas1b)

Elbahesh, Husni

12 January 2006

The flavivirus resistance gene, Flv, in mice has been identified as 2'-5' oligoadenylate synthetase 1b (Oas1b). Susceptible mice produce a protein that is truncated (Oas1btr) at the C-terminus due to a premature stop codon encoded by a C820T transition. Mice produce 8 Oas1 proteins, Oas1a-Oas1h. In the present study, Oas1a, Oas1b and Oas1btr were expressed as MBP-fusion proteins in bacteria and purified. 2-5A synthetase activity was demonstrated using MBP-Oas1a, while neither MBP-Oas1b nor MBP-Oas1btr were functionally active. The 2-5A synthetase activity of MBP-Oas1a was inhibited in a dose-dependent manner by the addition of MBP-Oas1b but not MBPOas1btr. Finally, three RNA probes were synthesized from the 3' end of the WNV Eg101 genome and used to test the ability of the expressed Oas1 proteins to bind to viral RNA. Results of the RNA binding activity assays suggest Oas1 proteins may specifically interact with regions of WNV RNA.

West Nile virus

viral RNA

Oligoadenylate Synthetase

Flavivirus

Developing new orthogonal tRNA/synthetase pairs for genetic code expansion

Willis, Julian C. W.

January 2018

No description available.

Estudo celular, bioquímico e biofísico da enzima selenofosfato sintetase de Naegleria gruberi / Biochemical, biophysical and cellular studies of selenophosphate synthetase from Naegleria gruberi

Natalia Karla Bellini

16 July 2015

O microrganismo alvo deste estudo pertence ao gênero Naegleria, que compreende amebas de vida livre amplamente distribuídas ao redor do mundo. Estas possuem estratégias de adaptação em condições de temperatura e pH que envolvem a diferenciação das células para as formas flagelada e cística. A via de biossíntese e incorporação do aminoácido selenocisteína (Sec, U) em N. gruberi foi descrita e, devido à incorporação co-traducional deste aminoácido em resposta a um códon UGA em fase de leitura, possui diversos fatores específicos que tornam a via alvo de estudos moleculares. Dentre os genes identificados, destaca-se o de selenofosfato sintetase (SPS), uma proteína funcionalmente dimérica envolvida na catálise da conversão de seleneto e adenosina 5´-trifosfato (ATP) em selenofosfato, essencial à síntese de Sec. Diferindo das SPSs homólogas, em N. gruberi a proteína (NgSPS2) é codificada em fusão N-terminal com uma metiltransferase e totaliza 737 aminoácidos. Esta descoberta motivou os objetivos da pesquisa baseada na investigação celular de NgSPS2 nativa nas três diferentes formas de vida de N. gruberi através de ensaios imunoenzimáticos, e a caracterização bioquímica e biofísica da proteína recombinante. A análise dos resultados obtidos por Western blot indicaram que NgSPS2, in vivo, apresenta os dois domínios metiltransferase e SPS separados após a tradução para uma cultura amebóide e, após alcançar a diferenciação de cada uma das formas isoladamente, este resultado se confirmou também para cistos e flagelados. A investigação de N. gruberi em cultura indica o aumento na atividade da via de síntese de selenoproteínas na presença de selênio conferindo resistência às condições de estresse oxidativo. A caracterização bioquímica do domínio C-terminal de NgSPS2, por cromatografia de exclusão molecular analítica e eletroforese não desnaturante, revelou predominância de dímeros em solução, coerente com SPSs homólogas. Os testes de cristalização não resultaram na obtenção de cristais, porém a proteólise limitada permitiu selecionar tripsina como potencial para a clivagem do N terminal do N terminal flexível. A conservação dos resíduos de aminoácidos funcionais em NgSPS2.CTD e seu comportamento em solução confirmam a obrigatoriedade da união de cada monômero e, por isso o domínio metiltransferase adicional pode ser desfavorável à montagem do dímero e in vivo a fusão é desfeita após a tradução. / The target microorganism of the present study belongs to the Naegleria genus. This genus includes free life amoebas widely distributed around the world that, in order to survive in bad temperature and pH environments, developed an adaptive strategy consisting of cells differentiation to flagellate and cystic form. The biosynthesis and incorporation of selenocysteine amino acid (Sec, U) in N. gruberi has been described and, because of the co-translational incorporation of this amino acid in response to a UGA codon during the reading step, this process has several specific factors which make it a target for molecular studies. Among the identified genes, we can highlight the one which encodes the selenophosphate synthetase that is involved in the catalytic conversion of selenite and adenosine triphosphate into selenium phosphate, a necessary step to the Sec synthesis that uses selenide and ATP to produce selenophosphate. SPS from N.gruberi is encoded with an methyltransferase N-terminal fused with the typical SPS C-terminal domain, an open read frame that contains 2211 nucleotides encoding 737 amino acids. This discovery has motivated the initial aims of this project, based on the cellular investigation of SPS2, native on the three different form lifes of N. gruberi, through immunoenzymatic assays, besides a study with the recombinant protein to clarify the biochemistry and biophysics features of NgSPS2. The results indicated that the protein do not keep both domains fused after the translation process, suggesting that they need to be separated to perform their biological function. The investigation of the N. gruberi culture revealed that the cells become less sensitive to stress agent in the presence of selenium, which seems to be correlated with the increasing activity of the selenoprotein synthesis. The biochemistry characterization of the NgSPS2 C-terminal domain, using size exclusion chromatography and electrophoresis under non-denaturing conditions revealed the predominance of dimers in solution according with the typical homologous SPS oligomeric state. The crystallization tests have not resulted in crystal growth; however, the limited proteolysis may be an alternative to optimize the crystallization process. These studies may enlarge the knowledge about the biosynthesis of Sec. in N. gruberi.

Naegleria gruberi

Selenocisteína

Selenofosfato sintetase

Naegleria gruberi

Selenocysteine

Selenophosphate synthetase

Estudos estruturais e funcionais da Selenofosfato Sintetase de Trypanosoma brucei e Leishmania major / Structural and functional studies of Selenophosphate Synthetase from Trypanosoma brucei and Leishmania major

Lívia Maria Faim

24 April 2014

A síntese e incorporação de Selenocisteína em selenoproteínas ocorre co tradicionalmente direcionado pelo códon de terminação UGA. Uma maquinaria única de enzimas e fatores proteicos é necessária para síntese de selenocisteína e decodificação do códon UGA de terminação da tradução para inserção de selenocisteína. Dentre as enzimas envolvidas, está a Selenonofosfato sintetase (SPS2), responsável por catalisar a ativação de seleneto com adenosina 5 trifosfato (ATP) para gerar selenofosfato, o doador de selênio reativo que é substrato da próxima enzima da via para formação de selenocisteína. Estudos recentes identificaram a presença da via de biossíntese de selenocisteína em parasitas kinetoplastidas e subsequentemente a proteína SPS2 de Trypanosoma brucei e Leishmania major foram caracterizadas. Entretanto, trabalhos estruturais e funcionais das enzimas permaneceram não reportados. Dessa forma, este trabalho teve seu foco estabelecido na realização de estudos estruturais e funcionais da SPS2 de T. brucei e L. major. Para caracterização da proteína em solução foram empregadas as técnicas de cromatografia de exclusão de tamanho, eletroforese em gel nativo, espalhamento dinâmico de luz (DLS), espalhamento de Raios X a baixo ângulo (SAXS) e ultracentrifugação analítica (AUC). Os resultados obtidos revelaram uma mistura de dímeros e tetrâmeros em solução para ambas SPS2 com predominância de dímeros. Muitas estratégias de cristalização e melhorias na difração foram utilizadas para obtenção de cristais proteicos apropriados para determinação da estrutura cristalográfica das SPS2. Cristais de SPS2 de T. brucei inteira e SPS2 de L. major com N-terminal truncado foram obtidos. Porém, somente a estrutura cristalográfica da proteína SPS2 de Leishmania major com o N-terminal truncado a 1,9 Å de resolução foi determinada. Estudos comparativos entre esta estrutura e outras selenofosfato sintetases mostrou a mesma organização estrutural entre elas. Experimento de complementação funcional das SPS2 truncadas e mutadas pontualmente revelou três resíduos localizados no N-terminal como fundamentais para atividade da SPS2 (Leu33, Thr34; Tyr36 e Leu37, Thr38; Tyr40 para SPS2 de T. brucei e L.major, respectivamente). Análise mutacional baseada nas estruturas cristalográficas indicou que estes resíduos podem estar envolvidos no mecanismo de entrega do selenofosfato para a próxima enzima da via, a Selenocisteína sintase. Isto poderia evitar a difusão de compostos reativos de selênio, resultando em uma eficiência na síntese de selenocisteína. Os resultados aqui apresentados forneceram informações importantes e novas perspectivas a respeito do mecanismo de catalise da enzima selenofosfato sintetase na via de síntese de selenocisteína. / The synthesis and incorporation of selenocysteine in selenoproteins occurs cotranslationally directed by the UGA stop codon. An unique machine of enzymes and protein factors are required for selenocysteine synthesis and decoding of UGA translation termination codon for the insertion of selenocysteine. Among the enzymes involved, Selenonofosfato synthetase (SPS2) is the responsible for catalyzing the activation of selenite with adenosine 5\' - triphosphate (ATP) to generate selenophosphate, the reactive selenium donor, which is substrate of the next pathway enzyme to formation of selenocysteine. Recent studies have identified the presence of selenocysteine biosynthesis in parasites Kinetoplastidas and subsequently, the SPS2 protein of Trypanosoma brucei and Leishmania major have been characterized, however, structural and functional studies of enzymes remain not reported. Thus, this present work report biochemical and biophysical studies of SPS2. To characterize the protein in solution, there were employed the techniques of size exclusion chromatography, native gel electrophoresis, dynamic light scattering (DLS), Small angle X-ray scattering angle (SAXS) and analytical ultracentrifugation (AUC). The results revealed a mixture of dimmers and tetramers in solution for SPS2 with predominance of dimers. Many strategies and improvements in crystallization and diffraction were used to obtain suitable SPS2 crystals for determination of the crystallography structure. T. brucei SPS2 crystals and L. major SPS2 crystals with truncated N-terminal were obtained. However, only the structure of SPS2 protein from L. major with truncated N-terminal to 1.9 Å of resolution was solved. Comparative studies of this structure with other selenophosphate synthases revealed the same structural organization. Functional complementation experiments of truncated and mutated SPS2 revealed three residues located in the SPS2 N- terminal as essential for the activity of the enzyme (Leu33 , Thr34 and Tyr36 to T. brucei SPS2; Leu37 , Thr38 and Tyr40 to L. major SPS2) . Mutational analysis based on the crystal structures indicated that these residues may be involved in the mechanism of selenophosphate delivery to the pathway enzyme next, the selenocysteine synthase. This found could prevent the diffusion of reactive selenium, resulting in selenocysteine synthesis efficient. The results presented here provided important information and new insights about the of selenophosphate synthetase catalysis mechanism in the selenocysteine synthesis pathway.

Selênio

Selenocisteína

Selenofosfato sintetase

SPS2

Selenium

Selenocysteine

Selenophosphate synthetase

SPS2

Variants of Human Lysyl-tRNA Synthetase: In vitro Activity and Relevance to Human Disease

McVey, Chase A.

29 December 2016

No description available.

Chemistry

Biochemistry

Dual blockade of macropinocytosis and asparagine bioavailability shows synergistic anti-tumor effects on KRAS-mutant colorectal cancer / マクロピノサイトーシス阻害とアスパラギン枯渇の併用療法はKRAS変異型大腸癌に対して相乗的な抗腫瘍効果を有する

Hanada, Keita

24 January 2022

京都大学 / 新制・課程博士 / 博士(医学) / 甲第23608号 / 医博第4795号 / 新制||医||1055(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 妹尾 浩, 教授 中島 貴子, 教授 戸井 雅和 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

KRAS mutation

Macropinocytosis

Asparagine synthetase

L-asparaginase

490

Metabolic Alterations Caused by KRAS Mutations in Colorectal Cancer Contribute to Cell Adaptation to Glutamine Depletion by Upregulation of Asparagine Synthetase / 結腸直腸癌におけるKRAS遺伝子変異による代謝変化は、アスパラギン合成酵素の発現亢進を介してグルタミン欠乏に対する耐性を獲得する

Toda, Kosuke

23 March 2017

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第20239号 / 医博第4198号 / 新制||医||1019(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 妹尾 浩, 教授 野田 亮, 教授 武藤 学 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Colorectal cancer

KRAS

Glutamine

Asparagine synthetase

Metabolism

490

Resolving the Limitations of Genetic Code Expansion Platforms:

Grasso, Katherine Taylor

January 2021

Thesis advisor: Abhishek Chatterjee / Thesis advisor: Eranthie Weerapana / Over the past twenty years, the site-specific incorporation of unnatural amino acids (UAAs) into a target protein through genetic code expansion (GCE) has emerged as one of the foremost technologies to selectively modify proteins in their native cellular context. This technology relies on engineered aminoacyl-tRNA synthetase (aaRS)/tRNA pairs that are orthogonal to the host cells’ endogenous aaRS/tRNA pairs. Traditionally, scientists look towards evolutionarily distant domains of life to identify orthogonal aaRS/tRNA pairs that can be further engineered for GCE applications in the host system. For example, bacterial aaRS/tRNA pairs are used for GCE in eukaryotes. The directed evolution of orthogonal aaRS/tRNA pairs for eukaryotic GCE has been less fortuitous due to the cumbersome nature of established yeast-based selection platforms. Recently, our lab circumvented this platform-based limitation by developing “altered translational machinery” (ATM) Escherichia coli strains that enabled the directed evolution of bacterial aaRS/tRNA pairs for eukaryotic GCE applications. In the ATM-tyrosyl (ATMY) E. coli strain, reintroduction of the E. coli tyrosyl-tRNA (tRNAEcTyrCUA) as a nonsense suppressor led to cross-reactivity with the endogenous E. coli glutaminyl-tRNA synthetase (EcGlnRS), restricting the activity range of aaRSs that could be selected, ultimately diminishing the scope of incorporable UAAs. To recover the dynamic range of this platform, cross-reactivity of the tRNAEcTyrCUA was eliminated through directed evolution of the tRNA acceptor stem. This new, orthogonal tRNA revealed weak mutant aaRSs whose suppression efficiencies were boosted through additional rounds of directed evolution. Improved aaRS mutants exhibited higher solubility, thermal stability, and suppression efficiency than their predecessor. While the newly engineered, orthogonal tRNAEcTyrCUA gave access to novel aaRS/tRNA pairs for eukaryotic GCE, some notable UAAs were still missing that could be incorporated with the archaeal Methanococcus jannaschii tyrosyl-tRNA synthetase (MjTyrRS)/tRNA pair in bacteria. Following a systematic investigation into the discrepancy between the E. coli tyrosyl-tRNA synthetase (EcTyrRS)/tRNA and MjTyrRS/tRNA pairs, we found that it can be partially attributed to the low structural robustness of the EcTyrRS. This limitation was overcome by rationally designing chimeric TyrRSs composed of EcTyrRS and a structural homologue from the thermophilic bacterium Geobacillus stearothermophilus. The chimeric scaffolds demonstrated enhanced stability, activity, and resilience to destabilizing active site mutations, offering a potentially more attractive scaffold for GCE. / Thesis (PhD) — Boston College, 2021. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Chemistry.

genetic code expansion

noncanonical amino acids

stability

synthetase

Characterizing the Response of gdhA Transformed Tobacco to Glufosinate

Nolte, Scott

01 December 2009

The gene gdhA from Escherichia coli, that encodes a NADPH-dependent glutamate dehydrogenase (GDH), directs a novel pathway in transgenic plants that potentially allows an increase in ammonium assimilation. Glufosinate leads to plant death by the irreversible inhibition of glutamate synthetase (GS) leading to a disruption of subsequent GS-related processes resulting in elevated ammonium and disruption of photorespiration. Therefore, it was speculated that the gdhA-transformed plants may exhibit a novel mechanism of resistance to glufosinate by altered activity of the GDH pathway and subsequently related processes. Studies were conducted in the greenhouse to evaluate 1) whole plant tolerance to glufosinate, 2) changes in absorption, translocation and metabolism of glufosinate, and 3) metabolic fingerprint changes in response to glufosinate treatment in tobacco plants containing the gdhA gene. Whole plant tolerance experiments showed that tobacco transformed with the gdhA gene expressed up to six fold increased resistance (GR50) to glufosinate compared with the non-gdhA control line. GDH enzyme activity among gdhA-transformed tobacco lines was highly correlated (r2 = 0.9903) with the amount of herbicide resistance. Thus, use of the E. coli gdhA gene in plant transformations can provide an additional mechanism for resistance to glufosinate. Foliar absorption and translocation of 14C from glufosinate was not altered to any large extent in gdhA-transformed plants which suggests these factors cannot fully explain the mechanism for whole-plant resistance to glufosinate. However, the metabolic fingerprint resulting from glufosinate treatment was significantly altered in gdhA tobacco. It was also shown that metabolic perturbation induced by glufosinate was lower in the high GDH activity tobacco line, +gdhA 9, than in the non-gdhA control tobacco line as evidenced by the reduced number of altered peaks recorded in leaves of these two tobacco lines. Thus, gdhA-transformed tobacco plants with low and high expression of GDH activity, exhibited greater overall stability of metabolism following the application of glufosinate, than recorded in non-gdhA control plants. This greater metabolic stability during GS inhibition was likely due to the amelioration of amino acid production through the increased activity of GDH. Therefore, the hypothesized mechanism of increased resistance to glufosinate in gdhA-transformed tobacco lines is by maintenance of amino acid production and maintenance of photorespiratory activity.

gdhA

glufosinate

glutamate dehydrogenase

glutamine synthetase

metabolism

nitrogen

Characterization of the <i>in vitro</i> and <i>in vivo</i> specificity of <i>trans</i>-editing proteins and interacting aminoacyl-tRNA synthetases

Liu, Ziwei

January 2014

No description available.

Biochemistry

tRNA synthetase

editing

quality control

amino acid