Estudo da via do ácido aspártico descrevendo uma variedade de técnicas de engenharia genética e bioquímicas / The study of aspartate metabolic pathway: a description of various biochemical and genetic engineering techniques

Nazareno, Amerivan Cirqueira

18 June 2013

Esta pesquisa bibliográfica teve o propósito de elucidar a via do acido aspártico, apontando como fonte deste estudo os cereais. O objetivo principal desta pesquisa consistiu em estudar a via do acido aspártico, visando descrever uma variedade de técnicas de engenharia genética e bioquímicas que podem ser empregadas para aumentar a qualidade nutricional de cereais, podendo, assim, compreender o que acarreta o aumento do acumulo de lisina, metionina e treonina nos grãos para suprir essa necessidade na formação de uma proteína balanceada nutricionalmente. Foi realizada uma busca exaustiva em bases de dados Google Scholar, Portal Capes, ISI web of Science, no período de publicação de 1970 a 2012. Foram adotados textos de referencia internacional e nacional. Esta pesquisa foi dividida em três etapas: via do acido aspártico e seus aminoácidos derivados em plantas superiores de 1970 a 1997, via metabólica do acido aspártico no período de 1997 a 2006 e estratégias interessantes para aumentar o nível dos aminoácidos essenciais da via do acido aspártico em plantas no período de 2006 ate o momento. A primeira etapa foi desenvolvida relatando o acido aspártico como precursor dos aminoácidos essenciais: metionina, lisina, treonina e isoleucina. Entre os essenciais, a lisina e um dos mais estudados devido a escassez em muitos cereais, o que contribuiu para o estudo extensivo da via do acido aspártico, revelando, assim, a importância da aspartato quinase (AK), homoserina desidrogenase (HSDH) e dihidrodipicolinato sintase (DHDPS) como enzimas chaves para a regulação da síntese de lisina. A aspartato quinase (AK) exerce um controle sobre via do acido aspártico. A enzima dihidrodipicolinato sintase (DHDPS) regula a síntese de lisina. Na segunda etapa foi apresentada a importância dos aminoácidos sintetizados nas plantas através de complexas vias metabólicas que são controladas por enzimas, intermediários, substratos e aminoácidos. Este estudo também relata os aspectos importantes para uma melhor compreensão da síntese e o acumulo de aminoácidos solúveis e incorporados em proteínas. A terceira etapa foi apresentar estratégias interessantes para utilização em estudos, visando aumentar o nível de aminoácidos essenciais através da manipulação de genes já existentes, como também a introdução de genes estranhos nas plantas. Devido a importância nutricional, essa via tem sido extensivamente estudada, utilizando técnicas de engenharia genética e bioquímica. Pesquisadores tem apresentado esforços considerados no estudo desta via a fim de contribuir para futuras manipulações genéticas, cujo objetivo e produzir plantas com alto conteúdo de lisina, metionina e treonina. / The aim of this research was to elucidate the aspartate metabolic pathway using grains of cereal as a source of study. Therefore, it was necessary to understand the aspartate metabolic pathway in order to depict various biochemical and genetic techniques which can be used to enhance the nutritional value in cereals. After studying theses issues, it was possible to understand the results of having cereals with a high lysine, methionine, and threonine content, so that grains can have balanced protein content. For that reason, an exhaustive research was done by using international and national scientific data published in 1970 to 2012. These data were found in Google Scholar, Portal Capes, and ISI Web of Science. This research was divided in three parts: studies of aspartate metabolic pathway and their essential amino acids derived from plants published in 1970 to 1997, studies of aspartate metabolic pathway published in the period of 1997 to 2006, and interesting strategies to enhance the level of essential amino acids of the aspartate metabolic pathway in plants from 2006 to this moment. Firstly, this investigation reported about the aspartic acid as a precursor of essential amino acids such as methionine, lysine, threonine, and isoleucyne. Among the essential amino acids, lysine has been the most researched due to its lack in many kinds of grains. Needless to say, it has contributed to the intensive study showing the relevancy of aspartate kinase (AK), homoserine dehydrogenase (HSDH), dihydrodipicolinate synthase (DHDPS), as key enzymes for lysine regulation. The aspartate kinase (AK) has an important role on the aspartate metabolic pathway, meanwhile the dihydrodipicolinate synthase (DHDPS) is intrinsically involved on lysine synthesis regulation. Secondly, this investigation presented the importance of the amino acids which are synthesized by plants through metabolic pathways that are controlled by enzymes, intermediates, substrates, and amino acids. In addition, this research reported relevant aspects whereby scientists can improve their understanding about the synthesis and accumulation of soluble amino acids which are incorporated in proteins. Finally, the third part showed interesting strategies which can be used in future researches in order to increase not only the level of essential amino acids by manipulating genes, but also the introduction of odd genes in plants. Given the nutritional relevancy, this pathway has been extensively investigated by using techniques used by biochemical and genetic engineering. Hence, researchers have demonstrated a considerable effort on this matter contributing for future genetic manipulations, so that plants with high lysine, methionine, and threonine content can be produced.

Ácido aspártico

Aminoácidos essenciais

Aspartate kinase

Aspartato quinase

Aspartic acid

Cereais

Cereals

Dihidrodipicolinate synthase

Dihidrodipicolinato sintase

Essential amino acids

Homoserina desidrogenase

Homoserine dehydrogenase

Unusual Acylation Properties Of Type II Fatty Acid Biosynthesis Acyl Carrier Proteins

Misra, Ashish

07 1900

This thesis entitled ‘ Unusual Acylation Properties of Type II Fatty Acid Biosynthesis Acyl Carrier Proteins’ describes the discovery of self-acylation and malonyl transferase activity in acyl carrier proteins involved in type II fatty acid biosynthesis and assigns a physiological role to these processes inside the cellular milieu. Acyl carrier protein (ACP) is one of the most abundant proteins present inside the cell and almost 4% enzymes require it as a cofactor. Acyl carrier proteins can exist either as discrete proteins or as domains of large functional proteins. They function in a variety of synthases as central molecules to which growing acyl intermediates and nascent product molecules are covalently tethered during the elongation and modification steps required to produce the final product. A prototypical bacterial ACP is composed of 70-80 amino acids and is generally expressed in the apo form. It is post-translationally modified to active holo form by the addition of 4'-phosphopantetheine moiety to an absolutely conserved serine residue in a reaction catalyzed by holo-ACP synthase or 4'-phosphopantetheine transferase. Chapter 1 surveys literature related to carrier proteins inside the cell and describes the thesis objective. It also presents an overview of the acyl carrier proteins and their involvement in various metabolic pathways inside the cell. The chapter details the structural organization of acyl carrier proteins from various sources revealing the conservation in their structure and also details the molecular basis of interaction of ACP with other enzymes inside the cell. The discovery of unusual self-acylation property in acyl carrier proteins involved in polyketide biosynthesis and its absence in acyl carrier proteins involved in fatty acid biosynthesis prompted me to investigate the reasons for this selective behavior. Discovery of self-acylation property in acyl carrier proteins Plasmodium falciparum and chloroplast targeted Brassica napus acyl carrier proteins involved in type II fatty acid biosynthesis and the mechanism of this reaction forms the basis of Chapter 2. In this chapter it has been shown that self-acylation property is intrinsic to a given acyl carrier protein and is not dependent on the pathway in which it is involved. Based on primary sequence analysis and site directed mutagenesis studies presence of an aspartate/glutamate has been identified to be critical for the self-acylation event. Furthermore, it has also been shown that the self-acylation event in type II fatty acid biosynthesis acyl carrier proteins is highly specific in nature employing only dicarboxylic acid –CoAs as substrates unlike the polyketide biosynthesis acyl carrier proteins which utilize both dicarboxylic acid and β-keto acid thiol ester -CoAs as substrates. The detailed kinetics of these reactions has also been worked out. Combining all the results a plausible mechanism for the self-acylation reaction has been proposed. Chapter 3 describes the discovery of a novel malonyl transferase behavior in acyl carrier proteins involved in type II fatty acid biosynthesis. Malonyl transferase property in ACPs of type II FAS from a bacterium (Escherichia coli), a plant (Brassica napus) and a parasitic protozoon (Plasmodium falciparum) were investigated to present a unifying paradigm for the mechanism of malonyl transferase behavior in ACPs. Identification of malonyl transferase property in Plasmodium falciparum ACP and Escherichia coli ACP (EcACP) and the absence of this property in Brassica napus ACP has been described in this chapter. Detailed investigations demonstrated that presence of an arginine or a lysine in loop II and an arginine or glutamine at the start of helix III as the residues that are critical for the transferase activity. In order to assign a physiologic function to these unusual acylation properties, fabD(Ts) mutant strain of Escherichia coli was utilized for heterologous complementation by the various wild type and mutant ACPs that are able to catalyze either or both of the activities. Growth of the mutant strain at non-permissive temperature, when complemented with ACPs catalyzing both the reactions confirmed that these properties have a physiologic relevance. Extensive mutagenesis experiments in conjunction with complementation studies allowed me to propose a plausible mechanism on how the self-malonylation and malonyl transferase properties operate in tandem. Chapter 4 describes the thermodynamic characterization of self-acylation process using Isothermal Titration Calorimetry. Isothermal Titration Calorimetric studies on the binding of malonyl, succinyl, butyryl and methylmalonyl –CoA to Plasmodium falciparum and Brassica napus acyl carrier proteins were performed to investigate the role of thermodynamic parameters in the specificity of self-acylation reaction. Calculation of the parameters showed that the thermodynamics does not control the self-acylation reaction. The evolution of self-acylation property in various acyl carrier proteins and its possible significance in the evolution of various metabolic events is described in Chapter 5. Extensive bioinformatics search was performed and phylogenetic analysis on acyl carrier proteins from 60 different taxa was done using the MEGA4 program. Analysis showed that this property was first found in cyanobacterium. Later, during the course of evolution this property was lost in most acyl carrier proteins, and was retained either in acyl carrier proteins that are targeted to organelles of cyanobaterial orgin viz. apicoplast in apicomplexans and chlorplasts in plants or in acyl carrier proteins involved in secondary metabolic events such as polyketide biosynthesis. Chapter 6 summarizes the findings of the thesis. Acyl carrier protein from Plasmodium falciparum, Brassica napus and Escherichia coli were characterized for their self-acylation and malonyl transferase properties and a combined mechanism for these two properties is proposed. The work done also provides an in vivo rationale to these in vitro processes. Furthermore, the evolutionary significance of the self-acylation behavior is also discussed in the thesis. The thesis also probes into the thermodynamics of the self-acylation reaction in Plasmodium falciparum and Brassica napus acyl carrier proteins. Thus, the thesis adds a new dimension to the much unexplored ACP biology and paves the way to study in vivo roles of these processes in detail. Appendix I describes the Isothermal Titration calorimetric characterization of binding of various acyl-PO4 molecules to Escherichia coli PlsX (Acyl-phosphate acyltransferase). PlsX, the first enzyme of phosphatidic acid biosynthesis pathway catalyzes the conversion of acyl-ACP into acyl-PO4, which is further used by other enzymes leading to the formation of phosphatidic acid. ITC results presented in this section show that longer chain length acyl-PO4 molecules show better binding to PlsX, as compared to the smaller ones demonstrating that long chain acyl molecules serve as better substrates for phosphatidic acid synthesis.

Carrier Proteins

Biosynthesis

Fatty Acids

Fatty Acids - Biosynthesis

Acyl Carrier Protein (ACP)

Polyketide Biosynthesis

Type II FAS

Phospholipid Biosynthesis

Lipid A Biosynthesis

Acyl Homoserine Lactone Synthesis

Biochemistry

Estudo da via do ácido aspártico descrevendo uma variedade de técnicas de engenharia genética e bioquímicas / The study of aspartate metabolic pathway: a description of various biochemical and genetic engineering techniques

Amerivan Cirqueira Nazareno

18 June 2013

Esta pesquisa bibliográfica teve o propósito de elucidar a via do acido aspártico, apontando como fonte deste estudo os cereais. O objetivo principal desta pesquisa consistiu em estudar a via do acido aspártico, visando descrever uma variedade de técnicas de engenharia genética e bioquímicas que podem ser empregadas para aumentar a qualidade nutricional de cereais, podendo, assim, compreender o que acarreta o aumento do acumulo de lisina, metionina e treonina nos grãos para suprir essa necessidade na formação de uma proteína balanceada nutricionalmente. Foi realizada uma busca exaustiva em bases de dados Google Scholar, Portal Capes, ISI web of Science, no período de publicação de 1970 a 2012. Foram adotados textos de referencia internacional e nacional. Esta pesquisa foi dividida em três etapas: via do acido aspártico e seus aminoácidos derivados em plantas superiores de 1970 a 1997, via metabólica do acido aspártico no período de 1997 a 2006 e estratégias interessantes para aumentar o nível dos aminoácidos essenciais da via do acido aspártico em plantas no período de 2006 ate o momento. A primeira etapa foi desenvolvida relatando o acido aspártico como precursor dos aminoácidos essenciais: metionina, lisina, treonina e isoleucina. Entre os essenciais, a lisina e um dos mais estudados devido a escassez em muitos cereais, o que contribuiu para o estudo extensivo da via do acido aspártico, revelando, assim, a importância da aspartato quinase (AK), homoserina desidrogenase (HSDH) e dihidrodipicolinato sintase (DHDPS) como enzimas chaves para a regulação da síntese de lisina. A aspartato quinase (AK) exerce um controle sobre via do acido aspártico. A enzima dihidrodipicolinato sintase (DHDPS) regula a síntese de lisina. Na segunda etapa foi apresentada a importância dos aminoácidos sintetizados nas plantas através de complexas vias metabólicas que são controladas por enzimas, intermediários, substratos e aminoácidos. Este estudo também relata os aspectos importantes para uma melhor compreensão da síntese e o acumulo de aminoácidos solúveis e incorporados em proteínas. A terceira etapa foi apresentar estratégias interessantes para utilização em estudos, visando aumentar o nível de aminoácidos essenciais através da manipulação de genes já existentes, como também a introdução de genes estranhos nas plantas. Devido a importância nutricional, essa via tem sido extensivamente estudada, utilizando técnicas de engenharia genética e bioquímica. Pesquisadores tem apresentado esforços considerados no estudo desta via a fim de contribuir para futuras manipulações genéticas, cujo objetivo e produzir plantas com alto conteúdo de lisina, metionina e treonina. / The aim of this research was to elucidate the aspartate metabolic pathway using grains of cereal as a source of study. Therefore, it was necessary to understand the aspartate metabolic pathway in order to depict various biochemical and genetic techniques which can be used to enhance the nutritional value in cereals. After studying theses issues, it was possible to understand the results of having cereals with a high lysine, methionine, and threonine content, so that grains can have balanced protein content. For that reason, an exhaustive research was done by using international and national scientific data published in 1970 to 2012. These data were found in Google Scholar, Portal Capes, and ISI Web of Science. This research was divided in three parts: studies of aspartate metabolic pathway and their essential amino acids derived from plants published in 1970 to 1997, studies of aspartate metabolic pathway published in the period of 1997 to 2006, and interesting strategies to enhance the level of essential amino acids of the aspartate metabolic pathway in plants from 2006 to this moment. Firstly, this investigation reported about the aspartic acid as a precursor of essential amino acids such as methionine, lysine, threonine, and isoleucyne. Among the essential amino acids, lysine has been the most researched due to its lack in many kinds of grains. Needless to say, it has contributed to the intensive study showing the relevancy of aspartate kinase (AK), homoserine dehydrogenase (HSDH), dihydrodipicolinate synthase (DHDPS), as key enzymes for lysine regulation. The aspartate kinase (AK) has an important role on the aspartate metabolic pathway, meanwhile the dihydrodipicolinate synthase (DHDPS) is intrinsically involved on lysine synthesis regulation. Secondly, this investigation presented the importance of the amino acids which are synthesized by plants through metabolic pathways that are controlled by enzymes, intermediates, substrates, and amino acids. In addition, this research reported relevant aspects whereby scientists can improve their understanding about the synthesis and accumulation of soluble amino acids which are incorporated in proteins. Finally, the third part showed interesting strategies which can be used in future researches in order to increase not only the level of essential amino acids by manipulating genes, but also the introduction of odd genes in plants. Given the nutritional relevancy, this pathway has been extensively investigated by using techniques used by biochemical and genetic engineering. Hence, researchers have demonstrated a considerable effort on this matter contributing for future genetic manipulations, so that plants with high lysine, methionine, and threonine content can be produced.

Ácido aspártico

Aminoácidos essenciais

Aspartato quinase

Cereais

Dihidrodipicolinato sintase

Homoserina desidrogenase

Aspartate kinase

Aspartic acid

Cereals

Dihidrodipicolinate synthase

Essential amino acids

Homoserine dehydrogenase

Le Quorum Sensing chez la bactérie marine Shewanella woodyi : Rôle dans l'émission de luminescence et dans la formation du biofilm / Quorum sensing in the marine bacterium Shewanella woodyi : Role in luminescence emission and biofilm formation

Hayek, Mahmoud

17 May 2018

Le « quorum sensing » (QS) est un moyen de communication bactérienne impliquant des petites molécules appelées auto-inducteurs qui au-delà d’un certain seuil de concentration induisent une synchronisation de l’expression génétique au sein de la communauté bactérienne. Ce mécanisme est impliqué dans plusieurs processus bactériens tels que la luminescence, la formation du biofilm, ce qui en fait une cible privilégiée pour l’inhibition du biofilm bactérien nuisible aux activités humaines. Plusieurs systèmes QS ont été identifiés ; les plus étudiés sont le système AHL (acyl homoserine lactone) et le système AI2 (auto inducteur 2). L’objectif principal de cette thèse est de caractériser le(s) système(s) QS de Shewanella woodyi, une bactérie marine luminescente capable de coloniser rapidement une surface et de former un biofilm. L’utilisation de biosenseurs de référence et des expériences de LC-MS ont montré que S. woodyi synthétise la C8-HSL et l’AI2. La mutation des gènes impliqués dans la synthèse ou la détection des HSL abolit la luminescence mais n’affecte pas la formation du biofilm. De plus, le système AI2 ne semble pas impliqué dans la luminescence et la formation de biofilm de S. woodyi. L’absence d’un récepteur d’AI2 suggère que cette molécule n’a pas un rôle régulateur et qu’elle ne serait qu’un produit secondaire du métabolisme cellulaire. Ce travail a donc permis de caractériser les 2 principaux systèmes QS de S. woodyi et pourrait permettre d’en faire un nouveau biosenseur marin. / Quorum sensing (QS) is a bacterial communication system involving small molecules called autoinducers which above a threshold concentration, induce the synchronization of genes expression within the bacterial community. This mechanism is involved in several bacterial processes such as luminescence and biofilm formation, making it a preferred target for the inhibition of bacterial biofilm harmful to human activities. Several QS systems have been identified; the most studied ones are the AHL system (acylhomoserine lactone) and the AI2 system (autoinducer 2). The main objective of this thesis is to characterize the QS system (s) of Shewanella woodyi, a luminescent marine bacterium able to rapidly colonize a surface and form a biofilm. The use of reference biosensors and LC-MS experiments have shown that S. woodyi synthesizes C8-HSL and AI2. The mutation of the genes involved in the synthesis or detection of HSL abolishes luminescence but does not affect the biofilm formation. Moreover, the AI2 system does not appear to be involved in the luminescence and biofilm formation of S. woodyi. The absence of an AI2 receptor suggests that this molecule does not have a regulatory role and that it is only a secondary product of cellular metabolism. This work has allowed the characterization of the 2 main QS systems of S. woodyi, which could make this strain a new marine biosensor.

Shewanella woodyi

AHL Acyl homoserine lactone

AI2 Auto inducteur 2

Bactérie biosenseur

Shewanella woodyi

AHL Acylhomoserine lactone

AI2 autoinducer 2

Biosensor bacteria

Quorum sensing in Sinorhizobium meliloti and effect of plant signals on bacterial quorum sensing

Teplitski, Max I.

11 September 2002

No description available.

Biology, Microbiology

quorum sensing

sinorhizobium meliloti

rhizobium

acyl homoserine lactone

root mucilage

plant polysaccharide

glycanase

stationary phase

log phase

proteomics

swarming

LuxR

mass spectrometry

Chlamydomonas

secondary products

rhizosphere

Investigation of the Catalytic Mechanism and Biosensing Potential of Phosphotriesterases

Langley, Christopher R.

25 August 2011

This thesis describes the characterization of SsoPox, a lactonase with promiscuous phosphotriesterase activity from the hyperthermophilic archaeon, Sulfolobus solfataricus, and the potential of the phosphotriesterase from Brevundimonas diminuta (PTEBd) to function as an organophosphate sensor. Arg-223 and Tyr-99 of SsoPox are not essential for lactonase activity, however substitution of a phenylalanine in place of Tyr-97 abolished lactonase activity while reducing paraoxonase activity by 20-fold. Substrate specificity of SsoPox can be modulated through the partial blockage of the hydrophobic binding tunnel adjacent to the active site. The specificity constant for N-(3-oxo-decanoyl)-L-homoserine lactone decreased 37-fold when a phenylalanine was introduced in place of Leu-226. PTEBd was expressed and purified from Pseudomonas putida and, like SsoPox, can be immobilized to Disruptor paper. The immobilized enzyme can be used to detect five organophosphates at concentrations as low as 50 μM. Incubation of PTEBd-immobilized sensors at different temperatures proved that the enzyme is stable for at least 40 days at 23.5 degrees Celsius without any detectable change in activity.

SsoPox

PTE

phosphotriesterase

pseudomonas

brevundimonas

sulfolobus

organophosphate

biosensor

paraoxon

parathion

pesticide

agriculture

enzyme

enzymology

biochemistry

microbiology

diminuta

archaea

bacteria

nanoalumina

disruptor

immobilization

mechanism

lactonase

homoserine

lactone

quorum

amino acid

thermophile

stable

thermostable

kinetic

detect

organochlorine

carbamate

Quorum Sensing Signals Produced by Heterotrophic Bacteria in Black Band Disease (BBD) of Corals and Their Potential Role in BBD Pathogenesis

Bhedi, Chinmayee D.

30 June 2017

Black band disease (BBD) of corals is a temperature dependent, highly virulent, polymicrobial disease affecting reef-building corals globally. The microbial consortium of BBD is primarily comprised of functional physiological groups that include photosynthetic cyanobacteria, sulfate reducers, sulfide oxidizers and a vast repertoire of heterotrophic bacteria. Quorum sensing (QS), the cell-density dependent communication phenomenon in bacteria, is known to induce expression of genes for a variety of virulence factors in diseases worldwide. Microbes capable of QS release signals such as acyl homoserine lactones (AHLs) and autoinducer-2 (AI-2), which coordinate microbial interaction. The focus of the present study was to investigate the presence and potential role of QS in BBD pathogenicity, utilizing culture dependent and independent methodologies. Isolates across coral health states including BBD, were screened for production of QS signals, and AHL and AI-2 production capabilities were analyzed via LC-MS/MS. The effect of temperature on AHLs was also examined. Additionally, antimicrobial production capabilities of isolates were tested. BBD metagenomes were utilized to screen for sequences related to QS, antimicrobial synthesis, and antimicrobial resistance genes. BBD isolates represented a significantly higher proportion of isolates capable of producing QS signals in comparison to healthy coral isolates. Several AHLs produced by coral derived bacterial cultures were identified, and three AHLs, specifically 3OHC4, 3OHC5 and 3OHC6, showed a significant increase in production at an elevated temperature of 30 °C, which correlates with increased BBD incidence on reefs with increasing water temperature. Most of the BBD cultured isolates were identified as vibrios. Several sequences related to QS, antimicrobial synthesis and resistance genes were detected in the BBD metagenomes. Based on the findings of this study, a model for potential microbial interactions amongst BBD heterotrophs, centered around QS, is proposed. Taken together, the findings from this study provide a clearer understanding of the potential role of QS in BBD, and serve as the basis for further studies aimed at elucidating the pathogenesis of an intricate coral disease.

black band disease

corals

quorum sensing

acyl homoserine lactones

metagenomics

temperature

coral disease

secondary metabolites

autoinducer-2

antimicrobial production

Bacteriology

Biology

Biotechnology

Marine Biology

Microbial Physiology

Microbiology

Pathogenic Microbiology

Investigating the Intercarbonyl X...C' (X=O/S/N) Interactions in Short Peptides and Peptidomimetics. Evidence of charge->II* Interactions. Synthesis and Characterization of Thioimidate Isostere Containing Peptidomimetics

Tumminakatti, Shama

January 2016

This thesis entitled “Investigating the Intercarbonyl X···C′ (X = O/S/N) Interactions in Short Peptides and Peptidomimetics. Evidence of Charge→π* Interactions. Synthesis and Characterization of Thioimidate Isostere Containing Peptidomimetics” is divided into two chapters. First chapter is further subdivided into four sections where investigation of the nature of intercarbonyl X···C′ (X = O/S/N) interactions in short peptides and peptidomimetics has been described. The second chapter also has been subdivided into three parts where the syntheses and characterization of thioimidate (1,3-thiazine) and imidate (1,3-oxazine) isostere containing peptidomimetics have been discussed. Chapter 1: Section A: Revisiting the earlier models for the intercarbonyl O···C′ interactions The proximity between carbonyls is ubiquitous in crystals. Here we review the key reports that have assigned an n→π* nature to interactions between carbonyl oxygen (O) atoms and adjacent carbonyl carbon (C′) atoms (O···C′). Based on earlier hypotheses (by Burgi-Dunitz) that suggest that “the minimum energy trajectory of a nitrogen nucleophile adding to the C′ of carbonyl is at N···C′ distances of ≤ 3.2 Å and along N···C′=O angles of 109±10o”, the optimum trajectory for addition of an O to an adjacent C′ has also been assigned to be the same (O···C′ distance ≤ 3.2 Å and O···C′=O angle is 109±10o). Additionally, all O and C′ atoms within these boundary conditions in crystal structures were assigned a status of interacting and those outside of the same as non-interacting. Based on quantum mechanical models for electronic orbitals that contain the valence electrons of such proximal O and C′ atoms – derived through NBO (Natural Bond Order) calculations (on crystal structures) – it has been proposed that the filled non-bonding lone pair orbital of the O (donor) overlaps with the empty π* orbital of the carbonyl C′ (acceptor), in these O···C′ interactions. Hence, these have been termed as n→π* interactions. Using DFT (Density Functional Theory) calculations energies for these interactions have been predicted to range from 0.5 to 5.0 kcal mol-1, which are similar to those for other strong non-covalent interactions such as H-bonding, weak cation-π, etc. This n→π* interaction model is assumed to prevail between adjacent carbonyls (Oi-1···C′i) at Xaa-Pro dipeptide motifs and to be exclusively responsible for the changes in equilibrium constant values (Kc/t) for the trans to cis isomerisation reaction at Xaa-Pro peptide bond in chosen analogue molecules. Based on this assumption, these Kc/t values have been used as direct experimental equivalents for the energies of these n→π* interactions. Simultaneous to such review of literature, this chapter highlights several anomalies in this n→π* model for the intercarbonyl O···C′ interactions. We discuss the alternate models that also exist for the O···C′ proximities and show that several features – such as improved pyramidalization at the acceptor carbonyl; decrease in Kc/t values at Xaa-Pro peptide bonds; and small changes in 13C NMR chemical shift values for the acceptor carbonyls; etc. – that accompany the shortening of O···C′ distance, can be explained without invoking the n→π* interaction model. Moreover, we discuss key observations such as the presence of near-symmetric antiparallel short contacts between carbonyl groups (C=O) in crystal structures, which cannot be explained by the quantum mechanical n→π* model for the O···C′ interactions. Chapter 1: Section B: Spectroscopic and kinetic investigations into the nature of X···C′ (X = O/S) interactions in N-acyl homoserine lactones (AHLs) In this section the key interactions involving the adjacent carbonyls in model N-acyl homoserine lactones (AHLs) (which are signalling molecules in quorum sensing) in solution, their electronic nature and their influence on solvolysis of the lactone ring have been investigated. Earlier, in the crystal structures of two sterically encumbered synthetic AHL analogues N-trimethyl acetyl homoserine lactone and N-tribromoacetyl homosrine lactone the presence of an n→π* orbital overlap type interaction between Oacyl and C′lact had been suggested. Based primarily on this, the operation of similar OacylC′lact interaction was proposed in all AHLs in their solution conformations as well. More intriguingly, the interaction was hypothesized to decrease the rates of lactone hydrolysis, rendering AHLs with longer biological half-life. This is contrary to physical organic understanding of nucleophilic catalysis of addition to carbonyls. Here we synthesize a variety of AHLs and analyze their NMR and FT-IR data in solution. The spectral data reveal that the role of the N-acyl group in AHLs is to withdraw eˉs from lactone C=O inductively and to improve electronic shielding at C′lact. Lack of appreciable changes in C=O stretching frequencies of lactone and 13C NMR chemical shift values of C′lact indicate the absence of electronic perturbation of the π* of the lactone. Similar non-variance of spectral bands with improvement in nucleophilicity of the N-acyl group indicates the absence of any evidence for n→π* nature for the O···C′ interactions (between the lone pair of eˉs from Oacyl to π* at C′lact). Further the spectroscopic data indicate that any change in charge at the acyl O is felt by C′lact and this weak interaction releases energy in the order of ≤ 0.05 kcal mol-1. The combined influence of the electron withdrawing N-acyl group and the weak Oacyl···C′lact interaction in AHLs is that, increasing the charge at Oacyl increases the rate of solvolysis of lactone. Analysis of the conformation of the lactone ring in the LuxR receptor-bound and unbound crystal structure forms reveals the flattening of the puckered ring in the LuxR bound state – facilitated by several interactions with the receptor. Conserved interactions between LuxR and AHLs lock the N-acyl carbonyl motif such that they are orthogonal to the lactone carbonyl and intramolecular interaction between Oacyl and C′lact is precluded. We propose the design of flat cyclic analogues of γ-butyrolactone bearing electron withdrawing side chains as potential molecules for taking advantage of bacterial quorum sensing in environmental applications and biotechnology. Chapter 1: Section C: Spectroscopic investigation into the nature of intercarbonyl X•••C′ (X = O/S/N) interactions: Carbamyl-cisPro model systems In this section we investigate the nature of intercarbonyl X···C′ interactions in carbamyl-Pro model systems using spectroscopic methods like FT-IR and 1D NMR. Further we derive the enthalpic and entropic contributions towards the free energy for trans to cis isomerization (Kc/t) at these model carbamyl-Pro systems. Our results reveal that changes in Kc/t values cannot always be used as proof for the presence or absence of electronic interactions, and hence to unambiguously suggest the nature of these interactions. Cis/trans isomerism exists at Xaa-Pro amide and carbamate motifs, and it was proposed that in acyl-Pro systems the O···C′ interactions are responsible for the stability of either cis or trans depending upon their direction of operation (Forward direction: O of Xaa is the donor of electrons to π* at C′ of Pro; Reverse direction: O of Pro is the donor of electrons to π* at C′ of Xaa). Investigation of the carbamyl-Pro systems can shed further light on this hypothesis. Hence we undertook the first spectroscopic and Van’t Hoff analysis of homologous carbamyl-Pro model systems. The Kc/t of the homologous series surprisingly increased with increase in the bulk at R (R varies from Me to tBu). The spectroscopic data revealed the presence of charge→σ* interactions at carbamyl groups. This interaction locks the carbamyl motif in the s-transoid conformation, along the C′-O σ-bond. Such conformational lock is observed to be greater in carbamyl groups where R has at least one Cα-H bond. Interestingly, we observe the absence of X···C′ electronic interactions that may selectively stabilize the cisPro conformer in these molecules. Van’t Hoff analyses on the other hand showed that as the number of Me substituents in R increases (R = Me to iPr), there is a favorable increase in entropy ( So) associated with the transPro to cisPro conformational isomerism. As a result, the population of the cisPro conformer improves significantly as the steric bulk at R increases. We note that the enthalpy of cisPro is however relatively small and remains unfavourable as R-bulk increases (Me to iPr). These data reveal the influence of electrostatic interactions between charged groups, on the change in entropy associated with cis/trans isomerism at carbamayl-Pro motifs. This not only opposes the n→π* model, but also provides an example for the important point that changes in Kc/t can/should not be taken as direct evidences of any single electronic interaction. Importantly, this study provides another example where electronic interactions between charged, polarized carbonyl motif rather than nonbonding lone pair eˉs of carbonyl motifs influence cis/trans isomerism at Xaa-Pro systems. Chapter 1: Section D: Investigation of the stereoelectronic nature of the X···C′ (X = O/S) contacts In this section we provide experimental evidence for the existence of inverse correlation between the charge on the O nucleophile and the O···C′ distances. We show that O and C′ atoms (of adjacent carbonyls), which are separated at distances > 3.20 Å in carefully chosen analogues, come together to σ-bonding distances when the charge on O is increased to -1. Additionally, the influence of backbone steric factors on these charge→π* interactions is investigated. A partial covalent nature was proposed for the O···C′ interactions. Our study showed that the shortest intercarbonyl O···C′ distances between the O of 1°, 2° and 3° amide carbonyls and proximal C′ in molecules found in the Cambridge Structural Database (CSD) (v5.36, November 2014) show an inverse linear correlation with the partial negative charge (δ‾) on the amide carbonyl O rendered by natural amide carbonyl polarization. These data suggest the interaction of charge on the nucleophilic O with π* of the acceptor carbonyl. Further on increasing the charge on nucleophilic carbonyl O to -1 in the model compound, we achieved the formation of σ-bond through non-native (natively disallowed) Oi‾¹→C′i-1 interaction. Here we provide the first experimental evidences that suggest the interaction between charge of O and π* at adjacent C′ (the charge→π* interaction) and the latent covalent nature of the O···C′ interactions. This charge→π* model explains the origins of variations in O···C′ distances (3.20 Å–1.43 Å) in proteins and complexes that occur to suit biological functions; and the mutual interactions between antiparallel carbonyls. Further the effect of 3 key steric factors – namely the allowed τ (N-Cα-C′) angle, entropy and allowed (ϕ,ψ) angles – on the non-native Oi→C′i-1 interactions were investigated in the model compounds. Our kinetic data revealed that, the allowed τ angles have the greatest influence on charge→π* interaction, followed by entropy. Importantly the allowed (ϕ,ψ) torsional angles for residues, that govern protein folding pathways, have little influence on the O···C′ electronic interactions. Chapter 2: Section A: Design and synthesis of novel 1,3-Thiazine containing peptidomimetics This section describes the first synthesis of peptidomimetics containing the 1,3-thiazine isostere (thioimidate isostere for the peptide bond), at the C-terminus and also at the middle of the peptide. The synthesis of the 6-membered heterocycles – 1,3-oxazine (Oxa) – have earlier been reported. Oxa motifs constrain preceding amino acid backbones into natively disallowed conformations. Here we present the first synthesis of peptidomimetics containing the 1,3-thiazine (Thi) (the thioimidate analogue of Oxa) motif, by the treatment of N-(3-hydroxypropyl)thioamides with MsCl/Et3N, which leads to intramolecular S-alkylation / cyclization. When placed at the C-terminus of acyl-Pro motifs the Thi group selectively improves the stability of the rare s-cis conformation of the acyl-Pro peptide bond. Further this method has been used to synthesize peptidomimetics in which an endogenous peptide bond is replaced with the Thi isostere. These Thi analogues are shown to be stable to standard conditions of peptide coupling and N- and C- terminus protection, deprotection and can be extended selectively at their N- or C- termini. Chapter 2: Section B: Epimerization in 1,3-Thiazine containing peptidomimetics The epimerization in 1,3-thiazine containing peptidomimetics and its mechanism has been described in this section. Further the aggregation behaviour of these thiazines, in solution and crystal structures, has been studied. It has been well-documented that epimerization (Racemization) occurs at the chiral centers at the C(2) exo methine of 1,3-thiazolines and 1,3-thiazoles. Similar epimerizations in 1,3-thiazines have however not been explored. Here we report our observation of epimerization in chiral aminoacid (non Pro) containing 1,3-thiazine peptidomimetics. Our studies revealed that, the epimerization happens at C2 positions of chiral (non-Pro) amino acids-derived 1,3-thiazine containing peptiomimetics. And NH of chiral (non-Pro) amino acid fused to Thi ring at C2 position is necessary for the epimerization. Further we investigated the Boc-Xaa*-Thi analogues in solution, which showed two resonances for the carbamate N-H (HN) and the H of Xaa*, irrespective of the side chain in Xaa, in CDCl3 a weakly polar solvent. The integral ratios of the major : minor peak increased with increase in concentration for Boc-Val*-Thi, indicating the formation of H-bonded aggregates. Even in the polar aprotic (DMSO-d6) and polar protic (D2O) solvents the two sets of resonances were observed for Boc-Val*-Thi in 1H NMR. But when the thioimidate N is protonated (N of Thi is no longer a H-bond acceptor), showed only a single set of resonances. Formation of intermolecular H-bonds involving N of Thi in solution is thus evident in the aggregates. This is further suggested by the crystal structures obtained for the peptide mimetics Boc-Val*-Thi, Boc-Leu*-Thi and Boc-Phe*-Thi in which the racemic pair, instead of one enantiomer of it, are present in the unit cell and are locked in a pair of intermolecular 10 membered H-bonding interactions between NThi and HLeu* similar to an antiparallel β-sheet. A mechanism for racemization is proposed, where this strong H-bond assists enamination/racemization process. Chapter 2: Section C: Influence of a disallowed conformation of Aib on the structure of a 310-helical fold In this section, the effect of the presence of a disallowed conformation of Aib at the C-terminus of a 310-helical peptide, on the structure and fold of the rest of the peptide body has been studied in solution. We constrain the C-terminal Aib in the Aib-rich octapeptide (N-tert-butoxycarbonyl-Leu1-Aib2-Ala3-Leu4-Aib5-Ala6-Phe7-Aib8-CO2Me (1), which adopts a complete 310-helical conformation throughout the peptide body in the crystal structure and in solution) in one of its disallowed conformations using a method earlier developed in our group. This involves the synthetic modification of the C-terminal ester (Aib8-CO2Me) in 1 to an Oxa (Aib*8-Oxa) in 2 and the study of its effect on the peptide body. Analyses of the solution FT-IR, CD, ¹H, 2D (TOCSY, HSQC, HMBC and ROESY) and solvent polarity dependent NMR data reveal that 2 adopts a 310-helical conformation similar to that of 1. The C-terminal CO2Me → Oxa (E → O) modified Aib*8-Oxa motif is constrained in a unique conformation where the two Cβ atoms of Aib*8 are staggered with respect to the Aib*8 C=O and are both interacting with the two Hβ of Phe7. Here the Aib* backbone is constrained by a 5-membered ring NOxa∙∙∙HAib* H-bond, in a C5i structure. Solvent polarity dependent ¹H NMR data indicate the formation and persistence of C5i H-bond at the Aib*8-Oxa motif in 2. Analyses of the ROESY, solvent polarity dependent ¹H NMR and CD spectra reveal that four crucial changes in ROESY cross peaks occur at the Phe7-Aib*8 motif of 2, compared to that in 1. From these spectroscopic data it has been confirmed that there is no change in the structure of 2 from Leu1 to Ala6. Whatever the crucial changes happened are at Phe7-Aib*8 motif of 2. Hence our study showed that the significant structural consequences of this disallowed conformation of Aib* are primarily observed to occur in the residue in its immediate vicinity, rather than in the whole peptide body. Presence of a disallowed fold at a residue need not result in disruption of the structure, or the overall fold, in the rest of the peptide body.

Nature of Intercarbonyl

Synthesis of Thiomidate Isotere

Isostere Peptidomimetics

Peptides and Peptidomimetics

1,3-Thiazine

Peptide Mimics

N-acyl Homoserine Lactones (AHLs)

Carbamyl-cisPro Model Systems

X···C′ (X = O/S) Contacts

Aib

Organic Chemistry

Small molecule signaling and detection systems in protists and bacteria

Rajamani, Sathish

13 September 2006

No description available.

Biophysics, General

Quorum sensing

Chlamydomonas reinhardtii

Quorum sensing mimics

Acyl homoserine lactone (AHL)

Boron derivative of AI-2 (BAI-2)

Cyan fluorescent protein (CFP)

Yellow fluorescent protein (YFP)

Mycobacterium tuberculosis kinases as potential drug targets: production of recombinant kinases in E. coli for functional characterization and enzyme inhibition screening against the medicinal plant Pelargonium sidoides

Lukman, Vishani

01 1900

Tuberculosis (TB) is an infectious and fatal disease that ranks as the second leading killer worldwide. It is caused by Mycobacterium tuberculosis (Mtb) which is an obligate intracellular parasite that colonizes the alveolar macrophages of the immune system. The major health concern associated with TB is its co-infection with HIV and the development of strains with multi-drug resistance. The elimination of TB has been hindered due to the lack of understanding of the survival strategies used by this pathogen. Thus, research towards discovering new effective antibacterial drugs is necessary and a group of Mtb kinase enzymes were targeted in this study because these enzymes are crucial for metabolism, pathogenesis and, hence, the survival of Mtb. Kinases are a group of structurally distinct and diverse proteins that catalyze the transfer of the phosphate group from high energy donor molecules such as ATP (or GTP) to a substrate. The phosphorylation of proteins modifies the activity of specific proteins which is subsequently used to control complex cellular processes within Mtb. The starting point of this research targeted eight specific Mtb kinases namely; Nucleoside diphosphokinase, Homoserine kinase, Acetate kinase, Glycerol kinase, Thiamine monophosphate kinase, Ribokinase, Aspartokinase and Shikimate kinase. The aim of this project was to subclone the gene sequences for these eight recombinant Mtb kinases and express them in Escherichia coli, to purify the proteins and determine their activity. In the effort to find new lead compounds, the final stage of this study focused on the basic screening of the TB kinases against an extract prepared from Pelargonium sidoides, a medicinal plant, to identify any inhibitory effects. Although this traditional medicinal plant has been broadly researched and extensively used to treat TB, there is still a lack of understanding of this plant’s scientific curative effect. Various molecular and biochemical methods were used to achieve the aims of this project. The putative gene sequence was obtained from the annotated genome of H37Rv, deposited at NCBI as NC_000962.2. The genes encoding the kinases were successfully PCR-amplified from genomic DNA, cloned into an expression vector in-frame with a C- or N-terminal 6-histidine-tag and expressed in E. coli BL21 (DE3). The purification of the protein was complex, but various different methods and techniques were explored to obtain sufficient amounts of protein. The functional characterization of the kinases involved an HPLC enzyme assay that showed that the recombinant kinases were active. These enzymes were then screened against the potential inhibitory compounds in P. sidoides using enzyme assays to generate dose-response curves. This allowed an effective comparison not only of the Mtb kinases’ activity under normal conditions but also the kinases’ activity in the presence of a potential inhibitor. Overall, the inhibition of the enzymes required the presence of higher concentrations of the P. sidoides extract. However, the SK enzyme results presented a significantly higher inhibition and the lowest IC50 value, in comparison to the other kinases, which makes this kinase an attractive potential drug target against TB. In summation, cloning and purification of SK was successful, resulting in a concentration of 2030 μg/ml of purified enzyme and its activity analysis demonstrated enzyme functionality. This activity was reduced to zero in the presence of 1 x 102 mg/ml dilution of P. sidoides plant extract. This research conducted has extended the quality of information available in this field of study. These interesting results, proposing and identifying SK as a suitable potential target can be a starting point to significantly contribute and progress in this field of research, with the eventual goal of developing a drug to combat this fatal disease. / Life Sciences / M. Sc. (Life Sciences)

Tuberculosis

Mycobacterium tuberculosis

Kinases

Nucleoside diphosphokinase

Homoserine kinase

Acetate kinase

Glycerol kinase

Thiamine monophosphate kinase

Ribokinase

Aspartokinase

Shikimate kinase

Pelargonium sidoides

Cloning

E. coli expression

Protein purification

Functional characterization

Inhibitory screens

616.995

Tuberculosis -- Prevention

Mycobacterium tuberculosis

Mycobacterium tuberculosis -- Infection

Tuberculosis -- Microbiology

Medical sciences