Дисертації з теми "Enzyme de modification des pectines"

La salinisation des sols est une situation préoccupante rencontrée dans plusieurs régions du monde où la pression sur l'eau devient de plus en plus forte, notamment en raison des changements climatiques et de la nécessité d'augmenter le rendement des cultures face à une population mondiale croissante. La présence d'un excès de sels dans le sol affecte les mécanismes physiologiques de la plante réduisant ainsi la production végétale. Une meilleure connaissance des mécanismes de défense des plantes en réponse au stress salin s'avère indispensable pour fournir des stratégies efficaces dans l'amélioration des cultures. La paroi végétale, première barrière physique entre le compartiment cellulaire végétal et l'environnement, a un rôle essentiel dans les mécanismes de croissance et de différentiation cellulaire et aussi en réponse à différents stress, dont le stress salin. La paroi végétale est une structure complexe et dynamique constituée principalement de polysaccharides (cellulose, hémicelluloses et pectines). Les pectines peuvent être méthylestérifiées et acétylées, les degrés de méthylestérification (DM) et d'acétylation (DA) sont contrôlés in muro par des enzymes spécifiques, les pectine méthylestérases (PME, EC 3.1.1.11) et acétylestérases (PAE, EC 3.1.1.6). Quelques données de la littérature montrent l'implication des pectines et du degré de méthylestérification de ces dernières, dans la tolérance au stress salin. Ces travaux avaient pour objectif d'incrémenter les données parcellaires actuelles sur le rôle de la paroi en réponse au stress salin. Trois stratégies d'étude distinctes ont été mises en place en choisissant comme modèle d'étude la plante glycophyte Arabidopsis thaliana. D'une part, la variabilité naturelle entre deux écotypes communs d'Arabidopsis thaliana (Wassilewskija, Ws et Columbia, Col-0) en réponse au stress salin a été caractérisée par une approche intégrative établissant une corrélation entre les résultats obtenus via des analyses physiologiques, biochimiques, métabolomiques et protéomiques. Les résultats ont montré une meilleure tolérance du stress salin associée au fond génétique Ws, avec un stade de développement plus avancé, une meilleure détoxification des espèces réactives à l'oxygène et une paroi plus riche en hémicelluloses et lignines. D'autre part, une approche de génétique inverse a été développée afin de déterminer les rôles fonctionnels des enzymes de modification des pectines AtPME3 et AtPAE7 dans la réponse au stress salin. Les résultats ont mis en évidence une perturbation du remodelage de la paroi par le stress salin. En effet, le stress salin induit une modulation des activités des enzymes de modification des pectines associée à une altération du patron de méthylestérification des pectines mais également à une réduction plus importante des homogalacturonanes et une augmentation des arabinanes par rapport aux plantes témoins. Enfin, une approche plus informative associant le métabolisme pariétal, la voie de détoxification des ions sodium, et l'impact des ions calcium sur la paroi a été menée afin de caractériser le remodelage pariétal induit par le stress salin chez le mutant hypersensible Atsos1 dont le gène SOS1 code un antiport Na+/H+ responsable de l'exclusion du Na+ à l'extérieur de la cellule. Les résultats préliminaires montrent une activité PME et PAE plus faibles que chez les plantes témoins en réponse au stress salin. Cela s'accompagne d'une réduction des acides galacturoniques et des résidus mannose. Ces résultats montrent que le remodelage des pectines et le mannose, semblent jouer un rôle prépondérant dans la tolérance au stress salin. L'ensemble des données confirme le rôle essentiel de la paroi et l'implication du calcium dans la tolérance au stress salin chez ce mutant
Soil salinization is a alarming situation encountered in several regions of the world where the pressure on water is becoming increasingly strong, especially due to climate change and the need to increase crop yields to face a global growing population. Excess of salt in soil affects plant physiological mechanism thus reducing plant production. A better knowledge of plant defense mechanism in response to salt stress is crucial to provide efficient strategies in crop yield. The plant cell wall is the first physical barrier between the plant cell compartment and the environment and plays an essential role in cell growth and development but also in response to various stresses, including salt stress. The cell wall is a highly complex and dynamic structure, mainly composed of polysaccharides (cellulose, hemicelluloses and pectins). Pectins can be methylesterified and acetylated, and their degree of methylesterification (DM) and acetylation (DA) can be modulated in muro by specific enzymes, pectin methylesterases (PMEs, EC 3.1.1.11) and acetylesterases (PAEs, EC 3.1. 1.6). Some parcelar data from the literature showed the role of pectins and their degree of methylesterification in tolerance to salt stress. The aim of this work was to provide new insights on the role of the cell wall in response to salt stress in the glycophyte Arabidopsis thaliana. Three distinct strategies were developed. Firstly, the natural variation between two common accessions of Arabidopsis thaliana (Wassilewskija, Ws and Columbia, Col-0) in response to salt stress has been characterized using an integrative approach establishing a correlation between physiological, biochemical, metabolomics and proteomics analyses. The results showed a better tolerance to salt stress associated with the genetic background Ws with an older developmental stage, a more efficient detoxification of reactive oxygen species and a higher content of xylan, mannan and lignin within the wall. Secondly, a reverse genetics approach has been developed to determine the contribution of two pectin remodeling enzymes, AtPME3 and AtPAE7 in salt tolerance. The results showed changes in the cell wall sugar composition as a reduction in homogalacturonan and an increase in arabinan in both atpme3 and atpae7 mutants after a long exposure to salt. Additionaly, salt stress induces a modulation of the PRE activities with an alteration of the pectin methylesterification pattern indicating a role of PME and PAE in cell wall integrity under salinity. Finally, a more informative approach combining cell wall metabolism, pectin remodeling enzymes, sodium ion detoxification pathway, and impact of calcium ions on cell wall integrity was carried out to characterize the role of the cell wall in the sodium hypersensitive mutant Atsos1. The SOS1 gene encodes a Na+/H+ antiporter which is involved in Na + exclusion. Preliminary results revealed that PME and PAE activities remained unchanged in atsos1 unlike the wild-type where the activites increased. That was associated with a reduction in pectin and mannan in atsos1, which was recovered by Ca2+ supply. All these data suggest the key role of atsos1 to maintain cell wall integrity under salt stress

La paroi primaire des cellules végétales est composée majoritairement de polysaccharides, notamment de microfibrilles de cellulose et d'hémicelluloses maintenues dans une matrice de pectines (Cosgrove, 2001). Parmi ces dernières, les homogalacturonanes (HG) qui sont les plus abondants peuvent être modifiés par des enzymes pariétales à l'origine de changements de structure de la paroi (Yadav et al. , 2009). Les gènes codant certaines de ces enzymes sont exprimés dans la graine d'Arabidopsis thaliana, suggérant un rôle de celles-ci dans le développement de la graine. L'étude de mutants d'insertion obtenus pour certains de ces gènes a mis en évidence un rôle de la pectine méthylestérase 58 (PME58) dans la structuration du mucilage. Le mucilage est une matrice riche en pectines produite par les cellules épidermiques du tégument de la graine et libérée lors de leur imbibition. Notre étude a montré que la PME58 est impliquée dans la déméthylestérification des HG présents dans le mucilage, dont la majorité provient probablement de la fragmentation des parois primaires des cellules épidermiques lors de l'extrusion du mucilage. L'étude des mutants pme58 par des approches analytiques et par immunodétection a montré que la PME58 est impliquée dans la régulation de la structuration et de la cohésion du mucilage, via la modulation des interactions entre les composants pectiques et cellulosiques

Les pectines méthylestérases (PME, EC. 3. 1. 1. 11) et les polygalacturonases (PG, EC. 3. 2. 1. 15) sont des enzymes qui catalysent respectivement la déméthylestérification et la dépolymérisation des homogalacturonanes, constituant majoritaire de la paroi primaire. Ceci conduit à des modifications structurales de la paroi végétale, et a des conséquences sur le développement et la réponse aux stress. Ces enzymes sont présentes chez les plantes mais sont également sécrétées par des phytopathogènes comme Botrytis cinerea, favorisant la colonisation de l'hôte. Afin de mieux comprendre les spécificités des enzymes de plantes vis-à-vis de celles de phytopathogènes, et d'identifier des inhibiteurs chimiques potentiels de ces enzymes, différentes approches ont été mises en œuvre. Des enzymes (PME/PG) d'Arabidopsis thaliana et de Botrytis ont été produites en système hétérologue afin de tester leur spécificité de substrat et de pH. Les substrats pectiques utilisés diffèrent par leurs degrés et patrons de méthylestérification. Dans le but d'identifier des inhibiteurs de ces enzymes, des molécules naturelles, des oligosaccharides bioisostères modifiés chimiquement au niveau du méthyle en C6 par différents groupements ainsi que des molécules chimiques issues d’une chimiothèque ont été testés. Les résultats obtenus montrent que, les enzymes de Botrytis cinerea (BcPME 1, BcPG 2 et BcPG 3) n'ont pas les mêmes spécificités de substrat et dépendance de pH que celles d'Arabidopsis (AtPME3, AtPME31 et AtPG80). En particulier, BcPME 1 montre une spécificité pour des HG de degrés de méthylestérification élevés à pH 4, alors que PME 3 et PME 31 sont plus actives à des pH de 6 et 7,5. Par ailleurs, PME 3 et PME 31 diffèrent dans leurs préférences de substrats, permettant de dégager des hypothèses quant à leurs rôles in planta. Ce travail a par ailleurs permis de montrer que les enzymes de plantes sont facilement inhibées par des molécules naturelles et chimiques, au contraire des enzymes de Botrytis. Enfin, le screen d'un chimiothèque a permis d'identifier de nouveaux inhibiteurs de l'activité PME

The aim of this project was to investigate the enzyme catalysed modification of synthetic polymers. It was found that an immobilised lipase from Candida antartica (Novozyme 435) catalysed the selective epoxidation of poly(butadiene) in the presence of hydrogen peroxide and catalytic quantities of acetic acid. The cis and trans double bonds of the backbone were epoxidised in yields of up to 60 % whilst the pendent vinyl groups were untouched. The effect of varying a number of reaction parameters was investigated. These studies suggested that higher yields of epoxide could not be obtained because of the conformational properties of the partially epoxidised polymer. Application of this process to the Baeyer-Villiger reaction of poly(vinyl phenyl ketone) and poly(vinyl methyl ketone) were unsuccessful. The lack of reactivity was found to be a property of the polymer rather than the enzymatic system employed. Attempts to modify hydroxyl containing polymers and polymers bearing active esters close to the polymer backbone were unsuccessful. Steric factors appear to be the most important influence on the outcome of the reactions.

In Nature there are twenty proteogenic amino acid ‘building blocks’, from which proteins and enzymes are constructed. These proteogenic amino acids confer activity to enzymes; however there are many instances where the chemistries provided by these ‘building blocks’ are expanded upon. Nature recruits an array of cofactors, post translational modifications and post translationally generated cofactors, all which help to provide function or activity. Until recently the protein engineer was restricted to the use of the twenty proteogenic amino acids, and so access to this increased chemical diversity was highly challenging. In this thesis, chemical modification has been used to insert a variety of non canonical amino acids (ncAAs) throughout the active site of the enzyme N acetylneuraminic acid lyase (NAL). This modification method incorporates ncAAs site specifically into a protein, via a dehydroalanine intermediate and conjugate addition with a thiol compound. Initial work using this method replaced the catalytic lysine at position 165 with the non canonical analogue γ thialysine. It was possible to obtain homogenously modified protein in high yields for detailed kinetic and X ray crystallographic studies, and therefore possible to elucidate the catalytic and structural consequences of this modification. The work to replace Lys165 with a non canonical analogue provided a starting point to expand the incorporation of ncAAs into NAL. A total of thirteen different non canonical side chains were incorporated, individually, at thirteen different positions within the active site of NAL. These modified enzymes were then screened for activity with ten different substrates to determine the effects of ncAA incorporation. It was seen that the ncAAs were well tolerated by the enzyme, as active modified enzymes were produced. By incorporating ncAAs it was possible to alter the substrate specificity of the enzyme. The modified enzyme F190Dpc, containing a dihydroxypropyl cysteine side chain, was found to have an increased activity with an altered substrate, erythrose. This activity was higher than the wild type enzyme with both the altered substrate and the wild type substrate, and the non canonical Dpc side chain outperformed any of the proteogenic amino acids when inserted at the same position in the protein, for the substrate erythrose. This research begins to explore the possibilities of what may be achieved by use of ncAAs. Facile incorporation of ncAAs will allow protein engineers to take inspiration from Nature and expand the chemistries provided by the proteogenic amino acids, hopefully to engineer novel activities or catalysis.

Neisseria gonorrhoeae (Ng) encounters different microenvironments during its life-cycle. Some of these niches have different concentrations of oxygen, which influences the rate of Ng growth; as well as iron, an element essential for Ng survival. Differential expression of several proteins allows the bacteria to adapt to the diverse conditions it comes encounters. One protein affected by environmental changes during Ng growth is Gcp, a tRNA-modification enzyme essential for protein synthesis. To study the regulation of expression of Gcp, we first analyzed the sequence of its ORF, gcp. Orthologs of this gene are found in all kingdoms of life. In silico analysis shows that among Neisseria species, gcp ranges in homology from 76% to 99%, at the nucleotide level. Reverse transcription PCR indicates that gcp is expressed as part of an operon, together with three cytochrome-associated genes cyc4, resB and resC. Rapid amplification of complementary DNA ends determined the start of transcription of cyc4 (and possibly of the cyc4-gcp operon) at 95 nucleotides from the gene start codon. Transcriptional fusions determined that the promoter region upstream of cyc4 is the strongest promoter in the operon. However, the region directly upstream of gcp also has low level of promoter activity, suggesting that the gene may be expressed from two different promoters. Semi-quantitative determination of the concentration of gcp mRNA indicates that the transcription of the gene is significantly repressed when Ng is grown under low iron or low oxygen conditions. Analysis of an fnr mutant, grown under the same conditions as its parental wild type, indicates that the FNR transcriptional regulator is involved in the repression of gcp in low iron or low oxygen conditions. Contrary to expectation, the cyc4 promoter is upregulated when Ng is grown under low oxygen or low iron conditions. However, these results cannot be compared to the original promoter strength. Determination of which was performed on bacteria grown in liquid medium. Coregulation of gcp with cytochrome genes can guarantee low levels of protein synthesis when Ng encounters adverse microenvironments and needs its energy redirected to the expression of genes that would allow it to survive.

The aim of this thesis is to modify flax pulp fibres (Linum usitatissimum) by more friendly environmental processes. Pulp and paper research is focussing through enzyme systems investigation for developing green chemistry technologies due to existing environmental concerns and to legal restrictions. Moreover, it exists also an increasing strategic interest in using flax fibres to obtain high-quality specialty papers. That is why we study the application of biotechnology as an efficient alternative to traditional industrial processes based on the use of chemical agents. This work is framed by two of the main research topics of the Paper and Graphic Specialty Laboratory in the Textile and Paper Engineering Department of the Universitat Politècnica de Catalunya. One research line is based on pulp bleaching and is focused basically on the study of enzymatic systems as biobleaching agents; the other research topic that has been recently introduced in our investigation group is the use of enzymes as functionalisation agents by promoting the grafting of several compounds. Laccase is the main enzyme used in this thesis; it is an oxidoreductase that can assist reactions in an eco-friendly way since laccase uses air and produces water as the only by-product. Moreover, laccase can work under mill conditions and has wide application potential. The first part of this thesis involved the use of enzymes to bleach flax pulp. The aim was to explore the potential of various natural mediators (lignin-derived compounds) for delignifying flax fibres in order to identify the most efficient and ecofriendly choice among them. Afterwards, we assessed the use of various enzyme delignification stages in an industrial bleaching sequence. The ensuing totally chlorine free (TCF) sequence comprised various laccase-mediator system treatments (L stage) followed by a by a chelating stage (Q stage) and a subsequent bleaching step with hydrogen peroxide (Po stage). A xylanase pretreatment was additionally carried out. Laccases used came from the fungi Pycnoporus cinnabarinus and Myceliophthora thermophila; the performance of several natural mediators was compared with the obtained with the application of various synthetic mediators. In addition, the lack of studies on the properties of effluents from the treatment of non-wood pulp with laccase and natural mediators led A-1 A-2 us to examine effluent properties upon biotreatments and after different bleaching stages. The results obtained warrant upscaling any of the biobleaching sequences for flax pulp as they provide sustainable flax fibre with a high cellulose content and brightness above 80% ISO. The use of xylanase pretreatment was found to efficiently remove HexA and enhance delignification by laccase.

Thesis (PhD (Process Engineering))--University of Stellenbosch, 2010.
ENGLISH ABSTRACT: There is growing interest to utilise xylan as speciality biopolymers in similar ways as high molecular weight polysaccharides such as starch and cellulose. The need to utilise xylan as alternative to cellulose and starch has increased because the cellulose and starch have many other competing uses. Unlike cellulose and starch, xylans are heteropolymers with higher degree of substitution and are of lower molecular mass and therefore, do not readily become insoluble to form hydrogels and biofilms. Consequently, xylans do not suit applications of starch and cellulose as speciality biodegradable additives and coatings in the food, pharmaceutical, pulp and paper and textile and many other industries. This study was conducted to develop an enzyme technology, based on recombinant α-L-arabinofuranosidase and purified α-D-glucuronidase with polymeric xylan substrate specificity, for controlled reduction of the solubility of water soluble polymeric xylan, leading to formation of insoluble nanohydrogels. Although xylan is available in abundance, a large proportion of it is currently wasted in lignocellulose process waste streams with little prospects for recovery and addition of value. Lignocellulosic materials including Eucalyptus grandis, Pinus patula, Bambusa balcooa (bamboo) and sugarcane (Saccharum officinarum L) bagasse (bagasse) found in South Africa were investigated as sources of water soluble xylan for enzyme modification. Two mild alkali-low temperature methods (alkali charge of < 14% and temperature of < 80ºC), one with ultrapurification denoted as the Hoije and the other with ethanol precipitation, denoted as Lopez method, were evaluated for their selective extraction of water soluble xylans from the specified lignocellulosic materials. The water soluble xylans were extracted from P. patula, bagasse, E. grandis and bamboo by the Hoije method with extraction efficiencies of 71.0, 66.0, 35.0 and 20.0% respectively. Using the Lopez method, the xylans from bagasse and E. grandis were extracted with extraction efficiencies of 28.0 and 12.0% respectively. The xylans extracted from P. patula, bamboo and bagasse were identified as arabinoglucuronoxylans, which were substituted with arabinose and 4-O-methyl-D- glucuronic acid (MeGlcA) side chains, whereas, the xylan extracted from E. grandis were identified as 4-O-methyl-β-D-glucuronoxylan (glucuronoxylan) substituted with MeGlcA groups on the main xylan chain. In addition, the glucuronoxylans contained some traces of arabinose and rhaminose sugar residues. The extracted xylan fractions had degree of polymerisation (DP) of > 10 and were water soluble, which suited the required properties of xylans for customised enzyme modification. The selective removal of the arabinose, MeGlcA and acetyl groups to create linear regions of xylose units in xylans that causes intra and inter-polymer bonding is considered to be the key process for reducing the solubility of water soluble xylans. The α-L-arabinofuranosidase of Aspergillus niger (AbfB) and α-D-glucuronidase of Schizophyllum commune (AguA) are special enzymes so far identified with the ability to selectively remove arabinose and MeGlcA side chains respectively, from water soluble xylans. Large scale application of the AbfB and AguA for reducing solubility of the water soluble xylans would require their extracellular production in large quantities and free of contamination from the xylan main chain degrading enzymes including the endo-1,4-β -xylanase. Selective production of the AbfB free of xylanase activity was achieved in recombinant A. niger D15 [abfB] strain under the transcriptional control of the glyceraldehyde-3-phosphate dehydrogenase promoter (gpdP) and glucoamylase terminator (glaAT). The recombinant AbfB was secreted extracellulary in 125 mL shake flasks and 10 L bioreactor fermentation cultures with volumetric activities of up to 10.0 and 8.0 nkat mL-1 respectively, against para-nitrophenol arabinofuranoside (pNPA). The secretion of the recombinant AbfB was growth associated and therefore, increased up to 2.5 times with addition of concentrate corn steep liquor (CCSL) as an additional source of nitrogen in the 2 x minimal standard cultivation media. The biomass specific activity of the recombinant AbfB against the pNPA substrate was approximately 366 nkat g-1 (dry weight basis). The recombinant AbfB displayed a single pure species band on 10% SDS-PAGE stained with Coomassie blue and had an estimated molecular mass of 67 kDa. In addition, the recombinant AbfB showed optimal activity at 40-55ºC and pH 3.0-5.0 and was stable under cultivation, storage and operating conditions at temperatures between 30-60ºC and pH 3.0-6.0. Furthermore, the recombinant AbfB showed broad substrate specificity selectively removing arabinose side groups from low viscosity wheat and oat spelt arabinoxylans, larchwood arabinogalactan, debranched arabinan and arabiglucuronoxylans extracted from bagasse, bamboo and P. patula found in South Africa,. The recombinant AbfB was able to precipitate xylans extracted from bagasse, bamboo and oat spelt but not from P. patula. Over 95% of the activity of the recombinant AbfB against the pNPA was recyclable after selective hydrolysis of the xylan at 40ºC for 16 h. On the other hand, the purified AguA enzyme could only precipitate the birch glucuronoxylan but not the glucuronoxylan extracted from E. grandis and arabinoglucuronoxylans extracted from bagasse, bamboo and P. patula. The synergetic action of the recombinant AbfB and the purified AguA increased the removal of the arabinose side chains from bagasse xylan by 22% and from bamboo xylan by 33%, whereas, the removal of the MeGlcA side chains from bagasse xylan increased by only 5% and that from bamboo xylan decreased by 13%. The selective removal of the arabinose side chains from oat spelt, bagasse and bamboo xylans by the recombinant AbfB had higher apparent viscosity relative the corresponding untreated xylans. However, the apparent viscosity of both the treated and untreated xylans reduced with increased shear rate. The viscosity had an overall negative correlation with arabinose side chain removal reaching a minimum of 2.03 mPa.s for hydrolysis of oat spelt xylan that was performed for 9.0 h at a temperature of 45.8ºC with recombinant AbfB xylan specific dosage of 400.0 nkat g-1substrate . The alteration of the viscosity of the xylans by the selective removal of the side chains is of special interest in the production of speciality emulsifying, thickening and antifoaming agents. The optimal values for hydrolysis time, enzyme dosage and temperature for maximum degree of removal of arabinose side chains from oat spelt xylan by the recombinant AbfB and of the removal of MeGlcA side chains from birch xylan by the purified AguA were determined by the Box-Benhken response surface method (RSM). The experimental region covered the xylan specific dosage for the recombinant AbfB between 18.0 and 540.0 nkatg-1substrate and for the purified AguA xylan between 2.0 and 18.0 μkatg-1substrate at temperatures between 30 and 50ºC and hydrolysis time between 1 and 16 h. The temperature, enzyme xylan specific dosage and hydrolysis time had significant effect (p<0.05) on both the selective removal of arabinose from oat spelt xylan by the recombinant AbfB and the selective removal of MeGlcA from birch xylan by the purified AguA. However, the interaction of these hydrolysis parameters were significant (p<0.05) on only the removal of arabinose side chains from oat spelt xylan by the recombinant AbfB. The optimal values for hydrolysis time, temperature and xylan specific dosage were estimated to be 14-16 h, 38-45ºC and 607.0 nkatg-1substrate respectively, for maximum removal of 43% of the available arabinose in oat spelt xylan by the recombinant AbfB. Whereas, the optimal values for hydrolysis time, temperature and xylan specific dosage for maximum removal of 0.5% of the available MeGlcA side chains from the birch xylan by the purified AguA were estimated to be 11 h, 38ºC and 18.0 μkatg-1substrate respectively. The optimal values of the hydrolysis parameters for both the removal of the arabinose from oat spelt xylan by the recombinant AbfB and of MeGlcA side chains from birch by the purified AguA could be predicted using quadratic models that fitted the response surface plots with regression coefficients of > 0.9. The effects of in situ selective removal of arabinose and MeGlcA side chains by AbfB and AguA respectively, from water soluble xylans, on their precipitation and adsorption onto cotton lint were investigated. The cotton lint was treated with xylans extracted from bagasse, bamboo, P. patula and E. grandis using the Hoije method in the presence of the recombinant AbfB, AguA and the cocktail of the two enzymes. The effects of in situ selective hydrolysis of model xylans including birch, oat spelt and H2O2 bleached bagasse and E. grandis xylan gel by the enzymes on their adsorption onto cotton lint were used for reference purposes. The purified AguA increased the adsorption of arabinoglucuronoxylans extracted from bagasse bamboo and P. Patula using the Hoije method onto cotton lint the most compared to the effect of the recombinant AbfB and the cocktail of the recombinant AbfB and purified AguA. The purified AguA increased the adsorption of the xylans extracted from bagasse and E. grandis xylans by 334 and 29% respectively, but decreased that of E. grandis xylan gel and H2O2 bleached bagasse xylan by 31 and 6% respectively. Similarly, the presence of the recombinant AbfB increased the adsorption of the bamboo, P. Patula and oat spelt xylans by 31, 44 and 900% respectively, but decreased the adsorption of the xylan extracted from bagasse and the H2O2 bleached bagasse xylan by 13 and 30% respectively. Furthermore, different xylan-cellulose interactions and water adsorption capacities of the cotton lint were observed with the in situ modification and adsorption of the xylans extracted from bagasse, bamboo, E. grandis and P. patula in the presence of the recombinant AbfB and purified AguA. Therefore, the enzyme aided adsorption of xylans could be used to alter or improve functional properties of cellulosic materials. The performance of enzymatically formed xylan nanohydrogels as encapsulation matrices for slow delivery of bioactive agents was evaluated. Insoluble xylan nanohydrogels formed by selective removal of arabinose side chains from water soluble oat spelt xylan by the recombinant AbfB were characterized for particle size distribution, surface charge (zeta potential), morphology stability and ability to encapsulate and slowly release the HRP. The enzymatically formed oat spelt xylan hydrogels were spherical in shape with particle sizes ranging from 18 nm to > 10 000 nm. The xylan nanohydrogels exhibited a negative zeta potential of up to -19 mV and displayed self assembling behaviour when formed at xylan concentrations of higher than 1.5% (w/v) and hydrolysis time beyond 17 h. The xylan concentration significantly (P < 0.05) influenced both the particle size and zeta potential of the oat spelt xylan nanohydrogels whereas the recombinant AbfB hydrolysis time was significant (P < 0.05) on the zeta potential. The oat spelt xylan nanohydrogels successfully encapsulated the HRP enzyme both during and after formation of the oat spelt xylan nanohydrogels and the release of the encapsulated HRP in active form, was sustained for a period of 180 min. Therefore, the xylan side chain removing enzymes have a role in preparation of biodegradable nanoencapsulation devices. Overall, the AbfB and AguA have presented a novel tool for functionalising water soluble xylans to be used as speciality additives, coating and implantation or encapsulation matrices, with reduced impact on the environment. This will advance processing and expand the product spectrum of lignocellulosic materials.
AFRIKAANSE OPSOMMING: Daar is ‘n toenemende belangstelling om spesialiteit biopolimere uit xilaan ontwikkel, en op soortgelyke wyse as hoë molekulêre massa polisakkariede soos stysel en sellulose te benut. Die behoefte om xilaan biodegradeerbare polimere as ‘n alternatief tot sellulose en stysel te gebruik neem toe omdat laasgenoemde baie ander kompeterende gebruike het. Anders as sellulose en stysel is uit xilaan heteropolimere met ‘n hoë graad van substitusie in die hoofketling met sygroepe en lae molekulêre massas, en raak daarom nie geredelik onoplosbaar om hidrojel en biofilms te vorm nie. Gevolglik is xilaan nie geskik vir toepassings van stysel en sellulose as spesialiteit biodegradeerbare bymiddels en bedekkings in die voedsel-, farmaseutiese-, pulp en papier-, tekstiel-, en vele ander industrieë nie. Hierdie studie is uitgevoer om ‘n ensiemtegnologie te ontwikkel gebaseer op rekombinante α-L-arabinofuranosidase en gesuiwerde α-D-glukuronidase met polimeriese xilaan substraat spesifisiteit, vir beheerde vermindering van die oplosbaarheid van wateroplosbare polimeriese xilaan wat lei tot die vorming van onoplosbare nanohidrojels. Alhoewel xilaan volop beskikbaar is, word ‘n groot deel daarvan tans vermors in afvalstrome uit lignosellulose prosessering, primêr verpulping, met min vooruitsigte vir herwinning en toevoeging van waarde. Lignosellulose materiaal wat in Suid-Afrika geproduseer word, insluitend Eucalyptus grandis (E. grandis), Pinus patula (P. patula), Bambusa balcooa (bamboes) en suikerriet (Saccharum officinarum L) (bagasse), is ondersoek as bronne van wateroplosbare xilaan vir ensiem modifikasie. Twee gematigde, lae temperatuur alkali-metodes (‘nalkali lading van < 14% en temperatuur van < 80°C), een met ultrasuiwering aangedui as Hoije en die ander met etanolpresipitasie aangedui as Lopez metode, is evalueer vir selektiewe ekstraksie van wateroplosbare xilaan vanuit die genoemde lignosellulose materiale. Die wateroplosbare xilaan is ge-ekshaheer vanuit P. patula, bagasse, E. grandis en bamboes met die Hoije metode met ekstraksie doeltreffendhede van 71.0, 66.0, 35.0, en 20.0%, onderskeidelik. Met die Lopez metode is xilaan vanuit bagasse en E. grandis geëkstraheer met ekstraksie doeltreffendhede van 28.0% en 12.0%, onderskeidelik. Die xilaan wat vanuit P. patula, bamboes, en bagasse ekstraheer is, is as arabinoglukuronoxilaan geïdentifiseer, wat met arabinose en 4-O-metiel-D glukuronsuur sykettings vervang is, terwyl die xilaan wat vanuit E. grandis ekstraheer is as 4-O-metiel--D-glukuronoxilaan (glukuronoxilaan), met substitusie met MeGlcA en asetiel-groepe op die hoof xilaan-ketting (ruggraat) is. Die glukuronoxilaan het verder spore van arabinose en rhaminose funksionele groepe bevat. Die geëkstraheerde xilaan fraksies het grade van polimerisasie > 10 gehad en was wateroplosbaar, wat die vereiste eienskappe van die xilaan vir doelgemaakte ensiem modifikasies bevredig het. Die selektiewe verwydering van die arabinose, MeGlcA, en asetiel-groepe om xilose eenhede sonder substitusie in polimeriese xilaan te vorm, wat intra- en inter-polimeer binding veroorsaak, word beskou as die belangrikste proses vir die vermindering van die oplosbaarheid van wateroplosbare xilaan. Die α-L-arabinofuranosidase van Aspergillus niger (AbfB) en α-D-glukuronidase van Schizophyllum commune (AguA) is spsialiteutsensieme wat tot dusver is met die vermoë om selektief die arabinose en MeGlcA sykettings, onderskeidelik, vanaf wateroplosbare xilaan te verwyder. Grootskaalse toepassing van die AbfB en AguA ensieme, vir die vermindering van die oplosbaarheid van wateroplosbare xilaan , sal ekstrasellulêre produksie deur mikrobes in groot hoeveelhede en vry van kontaminasie van die xilaan hoofketting degraderende ensieme insluitend die endo-1,4--xilanase vereis. Selektiewe produksie van die AbfB vry van xilanase aktiwiteit is verkry deur kultivering van rekombinante A. niger D15 [abfB], met transkipsie van die abfB-geen beheer deur die gliseraldehied-3-fosfaat dehidrogenase promotor (gpdp) en glukoamilase termineerder (glaAT). Die rekombinante AbfB ensiem is ekstrasellulêr geproduseer in 125 mL skudflesse en ‘n10 L bioreaktor fermentasiekulture met volumetriese aktiwiteite van tot 10.0 en 8.0 nkat mL-1, onderskeidelik, teen para-nitrofenol arabinofuranosied (pNPA). Die uitskeiding van die rekombinante AbfB was groei geassosieerd en het daarom tot 2.5 keer toegeneem met die byvoeging van gekonsentreerde mielieweekvloeistof as ‘n addisionele bron van stikstof in die 2 x minimale standaard kwekingsmedium. Die biomassa spesifieke aktiwiteit van die rekombinante AbfB teen die pNPA substraat was ongeveer 366 nkat g-1 (droë massa basis). Die rekombinante AbfB het ‘n enkele suiwer spesie band getoon op 10% SDS-PAGE gevlek met Coomassie blou en het ‘n beraamde molekulêre massa van 67 kDa gehad. Die rekombinante AbfB het verder optimale aktiwiteit by 40-55°C en pH 3.0-5.0 getoon en was stabiel onder kweking-, storing-, en bedryfstoestande by temperature tussen 30-60°C en pH 3.0-6.0. Die rekombinante AbfB het ook wye substraatspesifisiteit getoon om arabinose sy-groepe selektief te verwyder vanaf lae viskositeit koring-en hawerbiopolimere, lariks arabinogalaktaan, onvertakte arabinaan, en arabinoglukuronoxilaan biopolimere, geëkstraheer vanaf bagasse, bamboes en P.patula wat in Suid-Afrika aangetief word. Die rekombinante AbfB kon xilaan, ge-ekshaheer vanaf bagasse, bamboes en hawer onoplosbaar maak, maar die xilaan geëkstraheer vanaf P. patula nie. Meer as 95% van die aktiwiteit van die rekombinante AbfB teen die pNPA kon hersirkuleer word na selektiewe hidrolise van die xilaan by 40°C vir 16 h. Aan die ander kant kon die gesuiwerde AguA-ensiem slegs berkehout glukuronoxilaan onoplosbaar maak, maar nie glukuronoxilaan wat vanaf E. grandis geëkstraheer is of arabinoglukuronoxilaan wat vanaf bagasse, bamboes en P. patula geëkstraheer is nie. Die sinergistiese aksie van die rekombinante AbfB en die gesuiwerde AguA het die verwydering van die arabinose sykettings vanaf bagassexilaan met 22% vermeerder en met 33% in die geval van bamboesxilaan. Die verwydering van MeGlcA sykettings vanaf bagassexilaan is met slegs 5% vermeerder, terwyl dit met 13% verminder het in die geval van bamboesxilaan. Die selektiewe verwydering van die arabinose sykettings vanaf xilaan van hawer, bagasse, en bamboes deur die rekombinante AbfB het hoër skynbare viskositeit gehad relatief tot die ooreenstemmende onbehandelde xilaan . Die skynbare viskositeit van beide die behandelde en onbehandelde xilaan het egter verminder met toenemende skuiftempo. Die viskositeit het ‘n algehele negatiewe korrelasie met arabinose syketting verwydering gehad en het ‘n minimum van 2.03 mPa.s bereik vir hidrolise van hawerxilaan wat uitgevoer is vir 9.0 h by ‘n temperatuur van 45.8°C met rekombinante AbfB xilaan met ‘n spesifieke dosering van 400.0 nkat g-1substraat. Die wysiging van die viskositeit van die xilaan deur die selektiewe verwydering van die sykettings is van besondere belang in die produksie van spesialiteit emulsifisering, verdikking- en skuimweermiddels. Die optimale waardes vir hidrolisetyd, ensiemdosering en temperatuur vir maksimum graad van arabinose syketting verwydering vanaf hawerxilaan met die rekombinante AbfB, en van MeGlcA syketting verwydering vanaf berkehout xilaan met die gesuiwerde AguA, is vasgestel deur middel van die Box-Benhken responsie oppervlak metode. Die eksperimentele gebied het die xilaanspesifieke dosering met die rekombinante AbfB tussen 18.0 en 540.0 nkat g-1substraat en vir die gesuiwerde AguA xilaan tussen 2.0 en 18.0 μkat g-1substraat by temperature tussen 30 en 50°C en hidrolisetye tussen 1 en 16 h gedek. Die temperatuur, ensiem xilaan spesifieke dosering en hidrolise tyd het elk ‘n beduidende invloed (p<0.05) gehad op beide die selektiewe verwydering van arabinose vanaf hawerxilaan met die rekombinante AbfB en die selektiewe verwydering van MeGlcA vanaf berkehout xilaan met die gesuiwerde AguA. Die interaksie van hierdie hidroliseparameters was egter net beduidend (p<0.05) in die geval van arabinose syketting verwydering vanaf hawer xilaan met die rekombinante AbfB. Die optimale waardes vir die hidrolise tyd, temperatuur, en xilaan spesifieke dosering is beraam om gelyk aan 14-16 h, 38-45°C, en 607.0 nkat g-1substraat, onderskeidelik, te wees vir maksimale verwydering van 43% van die beskikbare arabinose in die hawer xilaan met die rekombinante AbfB. Die optimale waardes vir die hidrolise tyd, temperatuur en xilaan spesifieke dosering vir maksimale verwydering van 0.5% van die beskikbare MeGlcA sykettings vanaf die berkehout xilaan met die gesuiwerde AguA is beraam om gelyk aan 11 h, 38°C, en 18.0 μkat g-1substraat, onderskeidelik, te wees. Die optimale waardes van die hidrolise parameters, vir beide die verwydering van die arabinose vanaf hawer xilaan met die rekombinante AbfB en van MeGlcA sykettings vanaf berkehout met die gesuiwerde AguA, kon voorspel word deur gebruik te maak van kwadratiese modelle wat die responsie-oppervlak grafieke met regressie koeffisiënte > 0.9 gepas het. Die effek van in situ selektiewe verwydering van arabinose en MeGlcA sykettings met rekombinante AbfB en gesuiwerde AguA, onderskeidelik, vanaf wateroplosbare xilaan op hulle presipitasie en adsorpsie op katoen lint is ondersoek. Die katoenlint is behandel met xilaan ge-ekstraheer vanuit bagasse, bamboes, P. patula, en E. grandis deur gebruik te maak van die Hoije metode in die teenwoordigheid van die rekombinante AbfB, AguA, en ‘n mengsel van die twee ensieme. Die effek van in situ selektiewe hidrolise, deur die ensieme van model xilaan insluitende berkehout, hawer en H2O2-gebleikte bagasse en E. grandis xilaan jel, op hulle adsorpsie op katoen lint is gebruik vir verwysingsdoeleindes. Die gesuiwerde AguA het die adsorpsie van arabinoglukuronoxilaan , wat vanuit bagasse, bamboes en P. patula ekstraheer is deur middel van die Hoije metode, op katoenlint die meeste laat toeneem in vergelyking met die effek van die rekombinante AbfB en die mengsel van die rekombinante AbfB en die gesuiwerde AguA. Die gesuiwerde AguA het die adsorpsie van die xilaan wat vanuit bagasse en E. grandis ekstraheer is met 334 en 29%, onderskeidelik, laat toeneem, maar het die adsorpsie van E. grandis xilaanjel en H2O2 gebleikte bagasse xilaan met 31 en 6%, onderskeidelik, laat afneem. Op ‘n soortgelyke wyse het die teenwoordigheid van die rekombinante AbfB die adsorpsie van die bamboes, P. Patula en hawer xilaan met 31, 44, en 900%, onderskeidelik, laat toeneem, maar die adsorpsie van die xilaan ekstraheer vanuit bagasse en die H2O2 gebleikte bagasse xilaan met 13 en 30%, onderskeidelik, laat afneem. Verskillende xilaan-sellulose interaksies en water adsorpsie kapasiteite van die katoen lint is opgemerk met die in situ modifikasie en adsorpsie van die xilaan ekstraheer vanuit die bagasse, bamboes, E. grandis en P. patula in die teenwoordigheid van die rekombinante AbfB en gesuiwerde AguA. Die ensiem bygestaande adsorpsie van xilaan kon daarom gebruik word om die funksionele eienskappe van die sellulose materiaal aan te pas of te verbeter. Die wekverrigting van ensimaties gevormde xilaan nanohidrojels as enkapsuleringmatrikse vir stadige vrystelling van bioaktiewe middels is geevalueer. Onoplosbare xilaan nanohidrojels wat gevorm is deur selektiewe verwydering van arabinose sykettings vanaf wateroplosbare hawer xilaan met die rekombinante AfbA, is gekarakteriseer vir partikelgrootteverspreiding, oppervlaklading (zeta potensiaal), morfologiese stabiliteit, en die vermoë om die ramenas peroksidase te enkapsuleer en stadig vry te stel. Die ensimaties gevormde hawer xilaan hidrojels het ‘n sferiese vorm gehad met partikelgroottes wat gewissel het van 18 nm tot > 10 000 nm. Die xilaan nanohidrojels het ‘n negatiewe zeta potensiaal van tot -19 mV getoon, en het self-vormings gedrag vir partikels ten toon gestel indien dit by xilaankonsentrasies hoër as 1.5% (m/v) en hidrolise tye langer as 17 h gevorm is. Die xilaan konsentrasie het beide die partikelgrootte en die zeta potensiaal van die hawerxilaan nanohidrojels beduidend (P < 0.05) beïnvloed terwyl die rekombinante AbfB hidrolise tyd beduidend (P < 0.05) was op die zeta potensiaal. Die hawer xilaan nanohidrojels, het die ramenasperoksidase ensiem suksesvol enkapsuleer, beide gedurende en na die vorming van die hawer xilaan nanohidrojels en die vrystelling van die geënkapsuleerde ramenas peroksidase in aktiewe vorm is volgehou vir ‘n periode van 180 min. Die ensieme wat die syketting van die xilaan verwyder het, het dus ‘n rol in die voorbereiding van biodegadeerbare nano-enkapsulasie geedskap. In die geheel veskaf die rekombinante AbfB en gesuiwerde AguA ‘n nuwe stel manier voor om wateroplosbare xilaan te funksionaliseer om as spesialiteit bymiddels, bedekking, en inplanting of enkapsulasiematrikse gebruik te word met ‘n verminderde impak op die omgewing. Dit sal prosessering bevorder en die produkspektrum van lignosellulose materiale uitbrei.

It has previously been demonstrated that the biological incorporation and chemical modification of cysteine residues within the active site of the aldolase N-acetylneuraminic acid lyase (NAL) can lead to active chemically modified NAL variants. This thesis reports the exploitation of this joint chemical/biological method in the incorporation of several unnatural amino acids into the active site of Staphylococcus aureus NAL (SaNAL). This work was performed in an attempt to broaden the substrate specificity of the protein, to allow for the catalysis of the retro-aldol reaction of analogues of N-acetylneuraminic acid (the natural substrate of NAL). This method was used to incorporate a range of unnatural amino acids into the active site and kinetic parameters of these proteins were assessed with several varied N-acetylneuraminic acid analogues. The residues F190 and E192 of SaNAL were chosen for chemical modification as they have previously been shown to be important for the catalytic function of the protein. A coupled enzyme assay was used to assess the kinetic parameters of the chemically modified variants of SaNAL with the analogues of N-acetylneuraminic acid. As a result, it was found that a range of chemically modified amino acids at position 192 of SaNAL would allow for improved specific activity (kcat/KM) of the retro aldol reaction with the substrate DPAH, when compared to wild-type SaNAL with DPAH. An interesting relationship was also observed between the functionality of chemically modified amino acids at position 190 and the specific activity of the resulting protein in the retro-aldol of the substrate N-acetylneuraminic acid.

Content: Unhairing process brought serious pollution, and enzyme application for replacing polluting chemicals in unhairing process attracted much attention in recent years. However, the unhairing enzymes haven’t been accepted widely in actual production due to low purity, complex composition and poor stability. To solve these problems, unhairing enzyme is suggested to be improved by genetic modification in this research. The High-keratinase-producing gene (KerT), which was extracted from B. amyloliquefaciens TCCC11319, was introduced into the B.subtilis WB600 by heterologous expression. Because Bacillus subtilis WB600 is deficient in six extracellular proteases, this process successfully reduced the collagenolytic protease content in crude broth as well as improved the keratinase content. Meantime, the recombinant KerT produced by B.subtilis WB600 had the obviously unhairing effect to remove hairs. The results showed that the collagen degradability of recombinant KerT was slightly and it did not cause any adverse effects on the hide quality. This research will contribute to the development of unhairing enzyme, and the novel unhairing enzyme might be applied as the key factor for the advanced cleaning biotechnology in leather production process. Take-Away: 1. The keratinase gene KerT was firstly reported and analyzed which was extracted from B. amyloliquefaciens TCCC11319. 2. The collagenolytic protease activity of unhairing enzyme was successfully inhibited by heterologous expression of kerT. 3. The unhairing effect of this novel unhairing enzyme was similar to current Sulphur-lime method without damaging hide structure.

La recherche de nouveaux debouches pour les co-produits de culture du tournesol, a ete motivee par les tonnages eleves de residus generes. Dans un premier temps, une etude approfondie des caracteristiques physico-chimiques des differentes parties de la plante, debarrassee de ses graines, nous a permis de cibler deux produits interessants : une huile essentielle fortement odorante utilisable en parfumerie, et des pectines, connues pour leur teneur elevee dans le capitule, mais egalement presentes dans la moelle de la tige. Un approfondissement de cette etude a permis d'identifier les principaux constituants de huile essentielle, jusqu'a present inconnue. Parallelement, l'analyse de l'evolution des pectines de capitule au cours de la croissance de la plante nous a amene a relier leur faible degre de methylation (deja connu), a l'activite accrue des pectines methylesterases (pme) en fin de maturation de la plante. Ceci a conduit a envisager une strategie transgenique, ayant pour but de controler l'action des pme afin d'obtenir des pectines de degre de methylation superieur, utilisables dans le domaine des gelifiants. Une autre voie de valorisation des pectines a egalement ete etudiee a travers leur modification chimique, par esterification, avec des alcools a longue chaine. Cette etude a abouti a la synthese, sous activation micro-ondes, de molecules tensioactives dont les proprietes pourront offrir de nouvelles opportunites dans des domaines tels que les detergents ou les peintures. Enfin, dans une derniere partie, l'ensemble du procede de valorisation est aborde, incluant : les problemes lies a l'organisation de la recolte, les procedes d'obtention des extraits a l'echelle pilote, et la fabrication, suivie de la caracterisation mecanique, de materiaux type carton ondule, ou de materiaux faible densite a base de moelle destines aux domaines du calage et de l'emballage. En conclusion, un schema global de valorisation des co-produits est propose.

Wyosine derivatives are highly complex modified ribonucleic acid (RNA) bases found in archaea and eukarya. They are a modification of a genetically encoded guanosine found at position 37 of phenylalanine encoding transfer ribonucleic acid (tRNA). The second step in the biosynthesis of all wyosine derivatives, in both archaea and eukarya, is the transformation of N-methylguanosine to 4-demethylwyosine by the radical S-adenosyl-l-methionine enzyme TYW1. When these studies were initiated, the substrate of TYW1 was unknown. Four possible substrates; acetyl CoA, acetyl phosphate, phosphoenolpyruvate, and pyruvate; were tested for activity. Only incubation with pyruvate led to production of 4-demethylwyosine. As only two new carbons are incorporated into the RNA base at this step, ¹³C isotopologues were used to identify the carbons that are transferred into 4-demethylwyosine. These experiments revealed that C2 and C3 of pyruvate are incorporated into 4-demethylwyosine, with C1 lost as an unknown byproduct. Utilizing pyruvate containing deuteriums in place of protons on the C3 carbon, the regiochemistry of the addition was determined. It was found that C3 forms the methyl group of 4-demethylwyosine and C2 becomes the bridging carbon in the imidazoline ring. The site of hydrogen atom abstraction by 5'-deoxyadenosyl radical was identified as the N-methylguanosine methyl group through the use of tRNA containing a deuterated methyl group. The putative mechanism for this transformation involved the formation of an enzyme substrate Schiff base through a conserved lysine residue. Utilizing sodium cyanoborohydride a Schiff base was trapped between TYW1 and pyruvate. The mass of the trapped adduct responded as expected when different isotopologues of pyruvate were used, demonstrating that it is due to pyruvate. Moreover, the fragment of TYW1 that contained the trapped adduct contained two lysine residues, one of which was shown to be required for activity both in vivo and in vitro. It was initially proposed that TYW1 contained two iron-sulfur clusters, and then subsequently shown to have two 4Fe-4S clusters. Site directed mutagenesis, along with iron and sulfide analysis identified the cysteines; as C26, C39, and C52; coordinating the second 4Fe-4S cluster. This study identified pyruvate as the substrate of TYW1, and provided evidence for key steps in the transformation of N-methylguanosine to 4-demethylwyosine.

La méthylation de l'adénine en position 58 des ARNt (m1A58) est présente dans les trois domaines de vie et joue un rôle crucial chez plusieurs organismes. Sa formation est catalysée par la méthyltransférase SAM-dépendante TrmI. Alors que chez les eucaryotes et les bactéries, TrmI est site-spécifique pour l'adénine en position 58, chez l'archée Pyrococcus abyssi, TrmI est région-spécifique puisqu'elle catalyse également la méthylation de l'adénine en position 57. Nous nous sommes intéressés à cette enzyme, PabTrmI, pour comprendre cette différence de spécificité par rapport à ses homologues eucaryotes et bactériens.La structure cristallographique de l'enzyme, en complexe avec son cofacteur SAM ainsi qu'avec le produit de la réaction, la SAH, nous a conduit à construire différents mutants de la protéine et de son substrat ARNt. Nous avons ainsi montré que His78, située à l'entrée du site actif, est mobile et est importante pour l'efficacité catalytique de PabTrmI. L'analyse des positions de méthylation par spectrométrie de masse, simple et en tandem, montre qu'une partie de la région-spécificité de l'enzyme pour certains ARNt de P. abyssi, est liée à la présence de trois adénines consécutives, PabTrmI ne méthylant que la première adénine d'une séquence AA.En vue d'étudier les cinétiques rapides du mécanisme de retournement de la base de l'ARNt par l'enzyme région-spécifique PabTrmI et l'enzyme bactérienne site-spécifique TthTrmI de T. thermophilus, nous avons vérifié dans un premier temps, par spectrométrie de masse, qu'un mini-ARNt, constitué de la tige acceptrice et de la tige-boucle T, est substrat de TrmI.

Biocatalytic membranes (BMs) have promising applications in a diversity of fields including food, pharmaceutical and water treatment industries. Of particular relevance, Alcalase is a commercially important protease that has been applied for the production of peptides from the hydrolysis of proteins. In this study, two different approaches were applied for the modification of electrospun polyacrylonitrile nanofibrous membranes (EPNMs) for Alcalase immobilization. The first approach is alkali modification of EPNMs followed by EDC/NHS coupling for covalent bonding with Alcalase, whereas the other is based on polydopamine coating with or without glutaraldehyde grafting as a covalent linker. Immobilized Alcalase on these prepared BMs were studied and compared with free enzymes. It was found that the stabilities of Alcalase on BMs created using both approaches were improved, which enabled their reuse of 10 cycles with significant retention of enzymatic activity. A continuous reactor housing BMs were tested for hydrolysis of both model substrate, azo-casein and soybean meal protein (SMP). It was found that decreasing flux could improve the extent of hydrolysis and that a single-layer reactor can hydrolyze about 50% of the substrate to peptides with the molecular weight of 10 kDa or less. Hydrolysis of SMPs was demonstrated in a continuous five-layer BM reactor and both BMs showed excellent hydrolysis capacity. This study provides the groundwork for the development of high-efficiency BM for continuous and cost-effective protein hydrolysis for the production of value-added peptides.

La transcétolase (TK, EC 2.2.1.1) est une enzyme catalysant la formation de cétoses de configuration D-thréo à partir d'aldéhydes α-hydroxylés (2R), par formation stéréospécifique d'une liaison C-C. L'objectif de ces travaux est d'inverser l'énantiosélectivité de cette enzyme par ingénierie afin d'obtenir des cétoses L-érytho (recherchés pour leurs applications potentielles dans les domaines pharmaceutique et/ou nutritionnel) à partir d'aldéhydes α-hydroxylés (2S). Dans ce but, une TK thermostable (mTKgst) issue de la bactérie thermophile Geobacillus stearothermophillus a d'abord été identifiée et produite. L'étude de sa structure tridimensionnelle a permis d'identifier deux résidus du site actif ayant un rôle potentiel dans l'inversion de son énantiosélectivité : Leu382 et Asp470. Des banques demTKgst mutées ont alors été créées, selon deux stratégies : rationnelle et semi-rationnelle. La première a consisté à muter les deux résidus sélectionnés par mutagenèse par saturation de site, tandis que la seconde a consisté à modifier deux séquences de cinq résidus contigus à aux positions clés, selon la mutagenèse par cassette. Afin d'identifier les mTKgst mutées d'intérêt, un test de criblage à haut-débit a été mis au point, basé sur le suivi pH-métrique de la réaction en présence de rouge de phénol. A l'issue du criblage, le variant mTKgst-L382D/D470S a été mis en évidence. Son activité vis-à-vis d'un aldéhyde modèle de configuration (2S) a été augmentée d'un facteur 5 par rapport à l'enzyme sauvage et la perte de l'énantiosélectivité vis-à-vis desaldéhydes (2R) a été confirmée.

This thesis describes the rational design of a novel enzyme, a thiolester hydrolase, derived from human glutathione transferase (GST) A1-1 by the introduction of a single histidine residue. The first section of the thesis describes the design and the determination of the reaction mechanism. The design was based on the crystal structure of human GST A1-1 complexed with S-benzylglutathione. The resulting enzyme, A216H, catalyzed the hydrolysis of the non-natural substrate GSB, a thiolester of glutathione and benzoic acid. The reaction followed saturation kinetics with a kcat of 0.00078 min-1 and KM of 5 μM. The rate constant ratio, (kcat/KM)/kuncat, was found to be more than 107 M-1. The introduction of a single His residue in position 216 opened up a novel reaction pathway in human GST A1-1 and is a nice example of catalytic promiscuity. The substrate requirements were investigated and A216H was found to be selective since only two out of 18 GS-thiolesters tested were substrates for A216H. The reaction mechanism of the A216H-catalyzed hydrolysis of GSB was determined and found to proceed via an acyl intermediate at Y9. The hydrolysis was catalyzed by H216 that acts as a general base and the deacylation was found to be the rate-determining step. The Y9-intermediate could be selectively trapped by oxygen nucleophiles and primary alcohols, in particular 1-propanol and trifluoroethanol, were the most efficient. In addition, saturation kinetics was obtained in the acyl transfer reaction with 1-propanol indicating the presence of a second binding site in A216H. The second section of this thesis describes the site-specific covalent modification of human GST A1-1. The addition of GSB to the wild-type protein results in a site-specific benzoylation of only one tyrosine residue, Y9, out of ten present in the protein (one out of totally 51 nucleophiles). The reaction was tested with five GST classes (Alpha, Mu, Pi, Theta and Omega) and found to be specific for the Alpha class isoenzymes. The covalent modification reaction was further refined to target a single lysine residue, K216, providing a more stable linkage in the form of an amide bond. The reaction was found to be versatile and approximately 50% of the GS-thiolesters tested acylated K216, including a fluorophore.

On the day of the public defence the status of article II was: Submitted and article IV was: In press.

Clustered regularly interspaced short palindromic repeats (CRISPR) are derived from a bacterial and archaeal adaptive immune system. The core enzymes of CRISPR are RNA-guided endonucleases that sequence-specifically cleave foreign double-stranded DNA. Improving and controling the properties of the CRISPR system is a crucial step in advancing the therapeutic potential of CRISPR technology. Several classes of these enzymes exist and are being adapted for biotechnology, such as genome engineering. Cas12a (Cpf1) is a Type V CRISPR-associated (Cas) enzyme that naturally uses only one guide RNA, in contrast to Type II CRISPR-Cas9 enzymes. Thus, Cpf1 may represent a simpler, more practical tool for applications such as gene editing and therapeutics. This dissertation comprises four related studies in this area. To better understand the functional requirements for Cpf1-crRNA interaction and develop modified crRNAs suitable for synthetic biology and therapeutic applications, the first study performed nucleotide substitutions in the crRNA. It focused on the protein-interaction motif of the crRNA by incorporating base changes at the 2ʹ position that alter hydrogen-bonding capacity, sugar pucker, and flexibility. DNA substitutions in RNA can probe the importance of A-form structure, 2ʹ-hydroxyl contacts, and conformational constraints within RNA-guided enzymes. In addition, Chemical modifications include 2'-deoxy, 2'-fluoro, 2'- deoxy-arabinonucleic acid, and oxepane. Our study discovered that 2'-fluoro maintains the A-form structure and is compatible with AsCpf1 activity. Biochemical endonuclease activity, gene editing efficiency, Cpf1 binding affinity, and ribonucleoprotein stability were used to assess the tolerance and effects of modification. Characterizing structure-function requirements for Cpf1-crRNA interaction will facilitate better design and tuning of Cpf1 enzymes. The second study established a FRET-based assay in collaboration with a computational collaborator to identify small molecule inhibitors predicted by virtual docking and simulations. This study aims to lay the foundation for efficient, safe implementation of CRISPR-Cpf1. The third study used chemically modified Cas9-guide RNAs to offset known weaknesses of CRISPRi. It takes advantage of the high binding affinity and nuclease resistance of modified guides to potentially reduce the required components for CRISPRi.

L'utilisation d'enzymes de substitution est une approche pour le traitement des maladies consécutives à une déficience enzymatique. Malheureusement, la réaction immunitaire vis-à-vis de protéines étrangères est la source de graves complications. Dans le but d'étudier la réponse immunitaire déclenchée par les administrations multiples d'une enzyme chez la souris, la glucose oxydase d'Aspergillus niger (GO, EC 1. 1. 3. 4. ) a été choisie comme macromolécule-modèle à cause de sa stabilité et de sa résistance aux modifications chimiques. Les groupes hydrophobes ont été greffés sur les groupes aminés de la GO afin d'étudier la modulation de la réponse immunitaire envers la glucose oxydase, entrainée par les groupes hydrophobes. Les résultats montrent que l'ablation des cofacteurs FAD ou des résidus sucrés de la GO ne change pas la capacité de cette enzyme d'induire la formation d'anticorps. A la suite du greffage d'une courte chaine aliphatique (-C6H13), la GO n'induit plus qu'une faible production d'anticorps chez la souris après injections intraveineuses ou sous-cutanées répétées. Ce résultat peut offrir une solution au problème des réactions immunitaires lors du remplacement d'enzyme.

Parkinson's disease (PD) is a prevalent neurodegenerative disorder which affects over a million people in the United States. This disease is marked by the selective loss of dopaminergic neurons in the substantia nigra, leading to a decrease in the important neurotransmitter dopamine (DA), which is essential for the initiation and execution of coordinated movement. Currently, the pathogenesis behind PD is unknown, but there is evidence that both exogenous causes, such as pesticides and metals, as well as endogenous causes, such as reactive oxygen species or reactive metabolism intermediates, may play a role in the onset and progression of the disease. DA is catabolized by monoamine oxidase to 3,4-dihydroxyphenylacetaldehyde (DOPAL), which is further metabolized by aldehyde dehydrogenase and aldehyde reductase to the acid and alcohol products, respectively. Studies have demonstrated the reactivity of DOPAL with peptides and proteins, leading to covalent modification which may be detrimental to protein action. Furthermore, studies have shown that DOPAL is toxic, leading to a decrease in cell viability. Due to this, it was of interest to further study DOPAL and how it may play a role in the onset and progression of PD. It was of particular interest to determine protein targets of DOPAL modification. Until recently, no protein targets were identified and the cellular consequence of elevated DOPAL had not been fully studied. It has been previously shown that the important enzyme, tyrosine hydroxylase (TH) is inhibited by other catechols, including DA. This enzyme catalyzes the rate-limiting step in DA synthesis, oxidizing tyrosine to L-DOPA which is further metabolized to DA. Therefore, it was of interest to determine the effect of DOPAL on TH activity. It was hypothesized that DOPAL modifies and inhibits TH, leading to a decrease in the production of L-DOPA and DA. This work employed the use of a dopaminergic cell model (PC6-3 cells), to positively identify TH as a protein target of DOPAL modification. It also used both cell lysate as well as PC6-3 cell studies to investigate the effect of DOPAL modification on TH activity. Mass spectrometry was also utilized to determine sites of protein modification on TH. Results show that TH is potently inhibited by DOPAL modification, leading to a significant decrease in both L-DOPA and DA. Furthermore, DOPAL inhibition appears to be slowly-irreversible, with enzyme activity showing a time- and concentration dependent in recovery after preincubation with DOPAL. A novel cloning and purification procedure was used to clone human recombinant TH, which was used in mass spectrometry studies in which five sites of DOPAL modification were discovered. Furthermore, a real-time assay for TH activity was developed using a plate reader to spectrophotometrically observe the formation of L-DOPA over time. These data demonstrate the toxicity and potent enzyme inhibition by DOPAL and implicate DOPAL as a neurotoxin relevant in the pathogenesis of PD.

Le procédé de liquéfaction des fruits, nécessite l'emploi d'enzymes pectinolytiques, considérées comme des auxiliaires technologiques. L’optimisation de l'hydrolyse enzymatique passe par une meilleure connaissance de la paroi cellulaire du fruit. La paroi cellulaire de la fraise a été isolée du fruit par une extraction à l'alcool. Le matériel ainsi obtenu (MIA) a été soumis à des extractions successives par l'acide trans-1,2-diamino-cyclohexane-n,n,n',n'-tétraacétique, un tampon succinate pH 4,8, l'acide chlorhydrique dilué à chaud et la soude diluée à froid. L’analyse des différents extraits a permis de montrer que 87% des pectines solubles de la fraise sont extractibles par un agent chélatant du calcium (CDTA). Ces pectines sont faiblement méthylées et peu ramifiées. Les pectines les plus ramifiées nécessitent des conditions d'extraction plus drastiques (HCl et NaOH dilués). Le fractionnement par chromatographie échangeuse d'ions a permis de montrer que certaines fractions pectiques sont riches en oses neutres pouvant provenir des hémicelluloses (xylose, glucose), et en protéines. Les résultats obtenus permettent de suspecter la présence de liaisons entre les pectines, les hémicelluloses et les protéines au sein de la paroi cellulaire. La liquéfaction de la paroi (MIA) et de l'extrait insoluble dans le CDTA à l'aide d'enzymes industrielles a mis en évidence, outre la synergie entre les activités pectinolytiques et cellulolytiques, l'importance des activités hémicellulolytiques et protéolytiques. Ces études ont permis de mettre au point une nouvelle formulation enzymatique permettant d'améliorer le rendement d'extraction du jus et d'optimiser la stabilité des anthocyanes (couleur) au cours du stockage. En outre, cette étude a montré l'effet néfaste de la pasteurisation et de la concentration sur la couleur des jus

Depuis l'apparition du terme "biosensor" à travers un article de Lyons et Clark en 1962, les biocapteurs ont connu un véritable essor tant au niveau académique qu'industriel. Le principal objectif de ce travail de thèse était de créer une surface permettant l'immobilisation spécifique par liaison covalente de simple ou double brin d'ADN puis d'étudier les interactions pouvant exister entre une protéine donnée et l'ADN. Pour préparer la surface à cette immobilisation, nous avons opéré une réduction électrochimique de sel d'aryldiazoniums. Ce type de modification nous a permis de fixer de manière covalente sur la surface conductrice des fonctions de type Ar-SO2Cl. Par l'utilisation de la QCM et de l'AFM, nous avons pu par la suite détailler les mécanismes de fonctionnement de protéines (HsRad51 et Transposase) en interaction avec l'ADN simple ou double brin fixé, que ce soit d'un point de vue cinétique ou bien structural.

Naturally occurring enzymatic pathways enable highly specific, rapid thiophenic sulfur cleavage occurring at ambient temperature and pressure, which may be harnessed for the desulfurization of petroleum-based fuel. One pathway found in bacteria is a four-step catabolic pathway (the 4S pathway) converting dibenzothiophene (DBT), a common crude oil contaminant, into 2-hydroxybiphenyl (HBP) without disrupting the carbon-carbon bonds. 2’-Hydroxybiphenyl-2-sulfinate desulfinase (DszB), the rate-limiting enzyme in the enzyme cascade, is capable of selectively cleaving carbon-sulfur bonds. Accordingly, understanding the molecular mechanisms of DszB activity may enable development of the cascade as industrial biotechnology. Based on crystallographic evidence, we hypothesized that DszB undergoes an active site conformational change associated with the catalytic mechanism. Moreover, we anticipated this conformational change is responsible, in part, for enhancing product inhibition. Rhodococcus erythropolis IGTS8 DszB was recombinantly produced in Escherichia coli BL21 and purified to test these hypotheses. Activity and the resulting conformational change of DszB in the presence of HBP were evaluated. The activity of recombinant DszB was comparable to the natively expressed enzyme and was competitively inhibited by the product, HBP. Using circular dichroism, global changes in DszB conformation were monitored in response to HBP concentration, which indicated that both product and substrate produced similar structural changes. Molecular dynamics (MD) simulations and free energy perturbation with Hamiltonian replica exchange molecular dynamics (FEP/λ-REMD) calculations were used to investigate the molecular-level phenomena underlying the connection between conformation change and kinetic inhibition. In addition to the HBP, MD simulations of DszB bound to common, yet structurally diverse, crude oil contaminates 2’2-biphenol (BIPH), 1,8-naphthosultam (NTAM), 2-biphenyl carboxylic acid (BCA), and 1,8-naphthosultone (NAPO) were performed. Analysis of the simulation trajectories, including root mean square fluctuation (RMSF), center of mass (COM) distances, and strength of nonbonded interactions, when compared with FEP/λ-REMD calculations of ligand binding free energy, showed excellent agreement with experimentally determined inhibition constants. Together, the results show that a combination of a molecule’s hydrophobicity and nonspecific interactions with nearby functional groups contribute to a competitively inhibitive mechanism that locks DszB in a closed conformation and precludes substrate access to the active site. Limitations in DszB’s potential applications in industrial sulfur fixation are not limited to turnover rate. To better characterize DszB stability and to gain insight into ways by which to extend lifetime, as well as to pave the way for future studies in inhibition regulation, we evaluated the basic thermal and kinetic stability of DszB in a variety of solvation environments. Thermal stability of DszB was measured in a wide range of different commercially available buffer additives using differential scanning fluorimetry (DSF) to quickly identify favorable changes in protein melting point. Additionally, a fluorescent kinetic assay was employed to investigate DszB reaction rate over a 48 hr time period in a more focused group of buffer to link thermal stability to DszB life-time. Results indicate a concerningly poor short-term stability of DszB, with an extreme preference for select osmolyte buffer additives that only moderately curbed this effect. This necessitates a means of stability improvement beyond alteration of solvation environment. To this end, a more general investigation of glycosylation and its impact on protein stability was performed. Post-translational modification of proteins occurs in organisms from all kingdoms life, with glycosylation being among the most prevalent of amendments. The types of glycans attached differ greatly by organism but can be generally described as protein-attached carbohydrate chains of variable lengths and degrees of branching. With great diversity in structure, glycosylation serves numerous biological functions, including signaling, recognition, folding, and stability. While it is understood that glycans fulfill a variety of important roles, structural and biochemical characterization of even common motifs and preferred rotamers is incomplete. To better understand glycan structure, particularly their relevance to protein stability, we modeled and computed the solvation free energy of 13 common N- and O-linked glycans in a variety of conformations using thermodynamic integration. N-linked glycans were modeled in the β-1,4-linked conformation, attached to an asparagine analog, while O-linked glycans were each modeled in both the α-1,4 and β-1,4-linked conformations attached to both serine and threonine analogs. Results indicate a strong preference for the β conformation and show a synergistic effect of branching on glycan solubility. Our results serve as a library of solvation free energies for fundamental glycan building blocks to enhance understanding of more complex protein-carbohydrate structures moving forward.

Choline oxidase from Arthrobacter globiformis is a flavin-dependent enzyme that catalyzes the oxidation of choline to betaine aldehyde through two sequential hydride-transfer steps. The study of this enzyme is of importance to the understanding of glycine betaine biosynthesis found in pathogenic bacterial or economic relevant crop plants as a response to temperature and salt stress in adverse environment. In this study, chemical modification of choline oxidase using two irreversible inhibitors, tetranitromethane and phenylhydrazine, was performed in order to gain insights into the active site structure of the enzyme. Choline oxidase can also be inactivated irreversibly by freezing in 20 mM sodium phosphate and 20 mM sodium pyrophosphate at pH 6 and -20 oC. The results showed that enzyme inactivation was due to a localized conformational change associated with the ionization of a group in close proximity to the flavin cofactor and led to a complete lost of catalytic activity.

Chemical modification of proteins is critical for many areas of biochemistry and medicine. Several methods for site-selective protein modification are reported in this Thesis that are useful in accessing both natural and artificial protein architectures. Multiple, complementary methods for the conversion of cysteine to dehydroalanine are described. Dehydroalanine is used as a general precursor to several post-translational modifications and glycosylation, polyprenylation, phosphorylation, and lysine methylation and acetylation are all accessible. These modifications and their mimics were explored on multiple proteins, including histone proteins. Unnatural modifications were also explored. The first examples of olefin metathesis and Suzuki-Miyaura cross-coupling on protein substrates are reported. Allyl sulfides were discovered to be remarkably reactive substrates in olefin metathesis, allowing use of this reaction in water and on proteins. For Suzuki-Miyaura cross-coupling, a new catalyst is described that is fully compatible with proteins. Both olefin metathesis and cross-coupling allow the formation of carbon-carbon bonds on proteins. The prospects of these transformations in chemical biology are discussed. Finally, a novel strategy is reported for the installation of natural, unnatural, and post-translationally modified amino acid residues on proteins. This technology relies on addition of carbon radicals to dehydroalanine. This method of "chemical mutagenesis" is anticipated to complement standard genetic manipulation of protein structure.

Today, enzymes are extensively used for many industrial applications, this includes bulk and fine-chemical synthesis, pharmaceuticals and consumer products. Though Nature has perfected enzymes for many millions of years, they seldom reach industrial performance targets. Natural enzymes could benefit from protein redesign experiments to gain novel functions or optimize existing functions. Glutathione transferases (GSTs) are detoxification enzymes, they also display disparate functions. Two Mu-class GSTs, M1-1 and M2-2, are closely related but display dissimilar substrate selectivity profiles. Saturation mutagenesis of a previously recognized hypervariable amino acid in GST M2-2, generated twenty enzyme variants with altered substrate selectivity profiles, as well as modified thermostabilities and expressivities. This indicates an evolutionary significance; GST Mu-class enzymes could easily alter functions in a duplicate gene by a single-point mutation. To further identify residues responsible for substrate selectivity in the GST M2-2 active site, three residues were chosen for iterative saturation mutagenesis. Mutations in position10, identified as highly conserved, rendered enzyme variants with substrate selectivity profiles resembling that of specialist enzymes. Ile10 could be conserved to sustain the broad substrate acceptance displayed by GST Mu-class enzymes. Enzymes are constructed from primarily twenty amino acids, it is a reasonable assumption that expansion of the amino acid repertoire could result in functional properties that cannot be accomplished with the natural set of building blocks. A combination approach of site-directed mutagenesis and chemical modifications in GST M2-2 and GST M1-1 resulted in novel enzyme variants that displayed altered substrate selectivity patterns as well as improved enantioselectivities. The results presented in this thesis demonstrate the use of different protein redesign techniques to modulate various functions in Mu-class GSTs. These techniques could be useful in search of optimized enzyme variants for industrial targets.
biokemi och organisk kemi

La conformation moleculaire des lipides et des proteines est etudiee par spectroscopie de diffusion raman. La spectroscopie raman permet de decrire la structure secondaire du recepteur cholinergique et la position de certains acides amines aromatiques. Etude de la structure d'une neurotoxine. L'influence de deux modifications chimiques portant sur les acides amines conserves dans la sequence des neurotoxines. La conformation structurale de l'acetylcholine esterase est egalement abordee

This thesis concerns the electrochemical investigation of high-potential laccases. These multicopper oxidases are efficient electrocatalysts for the dioxygen reduction reaction. A method for stabilising laccase on a graphite electrode was established. The method involved modification of the graphite surface by diazonium coupling of a 2-anthracene molecule. A laccase ‘film’ adsorbed on this modified surface remained stable for over two months and, typically, the current density for dioxygen reduction was doubled compared to a laccase ‘film’ on an unmodified surface. Protein film voltammetry was used to investigate thermodynamic and kinetic aspects of the electrochemical behaviour of laccase. The effect of inhibitors on the magnitude of reduction current and the position of the wave (related to the overpotential for the reaction) was also studied. Fluoride, chloride and azide showed different modes of inhibition and inhibition constants ranged from micromolar for azide to millimolar for chloride. In cyclic voltammetry experiments it was only in the presence of high concentrations of the inhibitors fluoride, chloride and azide that a non-turnover signal, corresponding to a one electron transfer process, was revealed. The evidence suggested that the non-turnover signal arose from interfacial electron transfer between the electrode and the type 1 or ‘blue’ copper. Evaluation of the peak areas allowed determination of the catalytic rate constant, kcat, as 300 s–1, and the electroactive surface coverage as four pmol cm–2. The rate of interfacial electron transfer was rapid enough to not limit catalysis at high overpotentials. A spectroelectrochemical cell was designed to investigate the behaviour of the type 1 copper in the presence of inhibitors and at different pH values. The inhibitors fluoride, chloride and azide had little effect on the reduction potential of the type 1 copper, but at higher pH values the reduction potential of the type 1 copper was decreased.

The activity of protein kinases is heavily dependent on the phosphorylation state of the protein. Kinase phosphorylation states have been prepared through biological or enzymatic means for biochemical evaluation, but the use of protein chemical modification as an investigative tool has not been addressed. By chemically reacting a genetically encoded cysteine, phosphocysteine was installed via dehydroalanine as a reactive intermediate. The installed phosphocysteine was intended as a surrogate to the naturally occurring phosphothreonine or phosphoserine of a phosphorylated protein kinase. Two model protein kinases were investigated on: MEK1 and p38α. The development of suitable protein variants and suitable reaction conditions on these two proteins is discussed in turn and in detail, resulting in p38α-pCys180 and MEK1-pCys222. Designed to be mimics of the naturally occurring p38α-pThr180 and MEK1-pSer222, these two chemically modified proteins were studied for their biological function. The core biological studies entailed the determination of enzymatic activity of both modified proteins, and included the necessary controls against their active counterparts. In addition, the studies on p38α-pCys180 also included a more detailed quantification of enzymatic activity, and the behaviour of this modified protein against known inhibitors of p38α was also investigated. Both modified proteins were shown to be enzymatically active and behave similarly to corresponding active species. The adaptation of mass spectrometry methods to handle the majority of project's analytical requirements, from monitoring chemical transformations to following enzyme kinetics was instrumental in making these studies feasible. The details of these technical developments are interwoven into the scientific discussion. Also included in this thesis is an introduction to the mechanism and function of protein kinases, and on the protein chemistry methods employed. The work is concluded with a projection of implications that this protein chemical modification technique has on kinase biomedical research.