Identificação dos neurotransmissores das fibras mielínicas e amielínicas do nervo depressor aórtico de ratos: uma abordagem imunohistoquímica / Identification of the neurotransmitters of myelinated and unmyelinated fibers from aortic depressor nerve: an immunohistochemical approach

Carolina da Silva Carvalho

01 September 2016

O nervo depressor aórtico (NDA) é, primariamente, um conjunto de fibras aferentes que transmitem informações oriundas de alterações da pressão arterial (PA) a partir dos barorreceptores arteriais (mecanorreceptores localizados no arco da aorta ou seio carótico) aos centros de controle cardiovascular localizados no sistema nervoso central (SNC). Este mecanismo é responsável pela regulação reflexa da função cardíaca e vascular, promovendo ajustes nos centros vasoconstritor e vasodilatador, atuando simultaneamente sobre os sistemas simpático e parassimpático. Fato este que, contribui para o aumento da atividade vagal cardíaca e inibição de descargas simpáticas para vasos e coração, garantindo a manutenção dos níveis pressóricos dentro de uma faixa de normalidade. Diversos neurotransmissores foram descritos atuando nos centros de controle cardiocirculatório localizados no tronco encefálico, mais especificamente no bulbo, participando da regulação da PA. Nestas regiões centrais, os neurotransmissores glutamato, GABA (Àcido Gama Aminobutírico) e substância P (SP) foram amplamente investigados. Entretanto, em nenhum destes trabalhos foi realizado um estudo detalhado, investigando a presença da SP em nervos depressores aórticos de forma direta, sendo esta informação ainda desconhecida. Acredita-se que a SP seja um transmissor do reflexo barorreceptor, atuando na modulação deste circuito, na tentativa de atenuar elevações da pressão sanguínea. Existe portanto a necessidade de uma investigação morfológica e imunohistoquímica com o intuito de promover o esclarecimento sobre os neurotransmissores presentes no NDA. Os nervos frênicos foram utilizados como controle positivo, já que neste território a SP já se encontra caracterizada. Inúmeros são os estudos que descrevem a existência da SP em nervos frênicos, fato este que justifica a aplicação do referido nervo como controle do NDA, foco de estudo deste projeto. Baseados nestas necessidades, o objetivo do presente estudo foi primeiramente o de promover a padronização da técnica imunohistoquímica (IHQ), bem como a verificação da viabilidade de utilização do glutaraldeído à 2,5% como um fixativo primário, auxiliando na identificação de neurotransmissores dentro do sistema nervoso periférico. Em seguida, a identificação e quantificação da SP em NDA de ratos normotensos através do método imunohistoquímico indireto (3,3\'- Diaminobenzidina \"DAB\") foram realizados. O referido estudo foi desenvolvido em duas etapas. A primeira parte corresponde a padronização e otimização da técnica de imunohistoquímica em nervos frênicos de ratos Wistar através da localização e caracterização da SP e da enzima colina acetiltransferase (CAT). A segunda fase, trata-se da identificação e quantificação da SP no NDA, sendo este, um possível neurotransmissor ou neuromodulador do reflexo barorreceptor. Para este estudo foram utilizados no total 38 ratos da linhagem Wistar (Rattus Norvegicus), normotensos, com 20 semanas de idade, machos e fêmeas. Deste total, 16 animais machos foram destinados à padronização da técnica de IHQ em nervos frênicos. E para a caracterização e quantificação da SP no NDA foram utilizados 22 ratos Wistar, sendo 12 machos e 10 fêmeas. Nossos resultados demonstram de forma inédita a presença da SP em fibras amielínicas (tipo C) e fibras de pequeno diâmetro (A-delta) no NDA de forma bastante pontualizada em segmentos proximais e difusa distalmente, sugerindo a existência de subpopulações de fibras amielínicas do tipo C. Estes achados confirmam inúmeras suposições de que a SP atue como um dos neurotransmissores de aferências barorreceptoras, podendo participar na modulação do Sistema Nervoso Autônomo (SNA), uma vez que encontra-se localizada em centros responsáveis pela regulação reflexa da PA. Adicionalmente, a análise do percentual de marcação positiva à SP entre os gêneros apresentou um aparente predomínio da SP em machos mas sem diferença significativa entre os grupos. De forma semelhante, a padronização imunohistoquímica em cortes transversais e longitudinais de nervos frênicos apresentaram uma imunomarcação positiva e aleatória da SP em conjuntos de fibras amielínicas (tipo C) e em fibras de pequeno diâmetro localizadas próximo a periferia do espaço endoneural, corroborando com a localização relatada em estudos morfológicos e ultraestruturais, assegurando a especificidade e a reprodutibilidade do método. Distintamente, as fibras de grande e médio diâmetro (A-alfa, beta e gama), consideradas fibras mielinizadas de condução rápida, foram imunorreativas à CAT em nervos frênicos. Por fim, espera-se que a identificação deste neuropeptídeo sirva de gatilho para que futuras pesquisas envolvendo a liberação de neurotransmissores em aferências barorreceptoras sejam explorados. Fato este, que contribuirá para a agregação de informações pertinentes à modulação ou transmissão da informação neural, propiciando desta forma melhor entendimento da comunicação e atividades barorreflexas associadas a mecanismos cardiovasculares. / The aortic depressor nerve (ADN) is primarily a set of afferent fibers that transmit derived information of changes in arterial blood pressure (BP) from arterial baroreceptors (mechanoreceptors located in the aortic arch and carotid sinus) to sites of cardiovascular control located into central nervous system (CNS). This mechanism is responsible for the reflex regulation of cardiac and vascular function, promoting adjustments of vasoconstrictor and vasodilator centers, simultaneously acting on the sympathetic and parasympathetic systems. In addition, contributes to increased cardiac vagal activity and inhibition of sympathetic discharges to vessels and heart, ensuring the maintenance of blood pressure levels within the normal range. Many neurotransmitters have been described operating in cardio-circulatory control centers located in the brainstem, more specifically in the bulb, participating in the regulation of BP. In these central regions, the neurotransmitters glutamate, GABA (Gamma Aminobutyric Acid) and substance P (SP) have been widely investigated. However, none of these works was carried out a detailed study, investigating the presence of SP in aortic depressor nerves directly, and this information is still unknown. It is believed that SP can be a transmitter at the synapse of the baroreceptor reflex, operating in the modulation of this circuit in an attempt to attenuate elevation of blood pressure. Therefore, there is a need to investigate a morphological and immunohistochemical approach in order to promote the clarification on the present neurotransmitters into ADN. The phrenic nerves were used as a positive control, already as substance P (SP) is characterized in this territory. There have been numerous studies describing the existence of SP in phrenic nerves, a fact that justifies the application of the nerve as control of the ADN, study focus of this project. Based on these requirements, the aim of the present study is two-fold. Firstly, it attempts to promote the standardization of the immunohistochemical (IHC) technique as well as the verification of the feasibility of using glutaraldehyde fixative as a primary, assisting in the identification of neurotransmitters in the peripheral nervous system (PNS). Subsequently, the identification and quantification of SP immunoreactivity in the ADN of normotensive rats by indirect immunohistochemical method (3,3\'-Diaminobenzidine \"DAB\") were done. The study was developed in two stages. The first part corresponds to standardization and optimization of immunohistochemical technique in phrenic nerves of Wistar rats through location and characterization of the SP and enzyme choline acetyltransferase (ChAT). The second phase is about the identification and quantification of the SP into ADN, being a possible neurotransmitter or neuromodulator from the baroreceptor reflex. For this study we used a total of 38 Wistar rats (Rattus norvegicus), normotensive, 20 weeks old, male and female. From this total, 16 male animals were used for standardization of IHC technique in the phrenic nerves. Nonetheless, for the characterization and quantification of SP in ADN were used 22 Wistar rats, 12 males and 10 females. Our results showed an unprecedented manner the presence of SP in unmyelinated fibers (type C) and small diameter fibers (A-delta) into ADN, being quite focused on proximal segments and diffuse distally, suggesting the existence of subsets of unmyelinated fibers. These findings confirm numerous assumptions that the SP acts as a neurotransmitter from afferent baroreceptor and may participate in the modulation of the Autonomic Nervous System (ANS), since it is located in centers responsible for regulating reflex of BP. Further, an analysis of the percentage of positive SP staining between genders, presented an apparent predominance of SP in males but no significant difference between the groups were found. Similarly, IHC standardization in transverse and longitudinal sections of phrenic nerves showed a positive random and immunostaining of SP in sets of unmyelinated fibers (type C) and small diameter fibers located near the periphery of endoneural space, corroborating location reported on morphological and ultrastructural studies, ensuring the specificity and reproducibility of the method. Distinctly, the fibers of large and medium diameters (A-alpha, beta and gamma), considered myelinated fibers of fast conducting, were immunoreactive to ChAT in phrenic nerves. Finally, it is expected that the identification of neuropeptide serve as a trigger for that future studies involving the release of neurotransmitters into afferent baroreceptors be explored. These results could contribute to the aggregation of relevant information for the modulation and transmission of neural information, thus providing better understanding of communication and baroreflex activities associated with cardiovascular mechanisms.

Glutaraldeído

Imunohistoquímica

Nervo depressor aórtico

Nervo frênico

Normotensos

Ratos Wistar

Substância P. Colina Acetiltransferase

Aortic depressor nerve

Glutaraldehyde

Immunohistochemistry

Normotensive

Phrenic nerve

Substance P. Choline Acetyltransferase

Wistar rats

A study of chymotrypsin immobilization conditions for improved peptide mapping

Elshalale, Fatma

03 1900

No description available.

Cartographie peptidique

Réticulation

Glutaraldéhyde

Chymotrypsine

Électrophorèse capillaire

Peptide mapping

Cross-linking

Glutaraldehyde

Chymotrypsin

Capillary electrophoresis

Various cross-linking methods inhibit the collagenase I degradation of rabbit scleral tissue

Krasselt, Konstantin, Frommelt, Cornelius, Brunner, Robert, Rauscher, Franziska Georgia, Francke, Mike, Körber, Nicole

11 February 2022

Background: Collagen cross-linking of the sclera is a promising approach to strengthen scleral rigidity and thus to inhibit eye growth in progressive myopia. Additionally, cross-linking might inhibit degrading processes in idiopathic melting or in ocular inflammatory diseases of the sclera. Different cross-linking treatments were tested to increase resistance to enzymatic degradation of the rabbit sclera. Methods: Scleral patches from rabbit eyes were cross-linked using paraformaldehyde, glutaraldehyde or riboflavin combined with UV-A-light or with blue light. The patches were incubated with collagenase I (MMP1) for various durations up to 24 h to elucidate differences in scleral resistance to enzymatic degradation. Degraded protein components in the supernatant were detected and quantified using measurements of Fluoraldehyde o-Phthaldialdehyde (OPA) fluorescence . Results: All cross-linking methods reduced the enzymatic degradation of rabbit scleral tissue by MMP1. Incubation with glutaraldehyde (1%) and paraformaldehyde (4%) caused nearly a complete inhibition of enzymatic degradation (down to 7% ± 2.8 of digested protein compared to control). Cross-linking with riboflavin/UV-A-light reduced the degradation by MMP1 to 62% ± 12.7 after 24 h. Cross-linking with riboflavin/blue light reduced the degradation by MMP1 to 77% ± 13.5 after 24 h. No significant differences could be detected comparing different light intensities, light exposure times or riboflavin concentrations. Conclusions: The application of all cross-linking methods increased the resistance of rabbit scleral tissue to MMP1-degradation. Especially, gentle cross-linking with riboflavin and UV-A or blue light might be a clinical approach in future.

info:eu-repo/classification/ddc/610

ddc:610

info:eu-repo/classification/ddc/000

ddc:000

Alquila??o redutiva da quitosana a partir do glutaralde?do e 3-amino-1-pr / Reductive alkylation of chitosan by glutaraldehyde and 3-amino-1-propanol

Alves, Keila dos Santos

29 February 2008

Made available in DSpace on 2014-12-17T15:41:41Z (GMT). No. of bitstreams: 1 KeilaSA.pdf: 2159921 bytes, checksum: eaf4fb1bec7305fa007222908f6259ac (MD5) Previous issue date: 2008-02-29 / Coordena??o de Aperfei?oamento de Pessoal de N?vel Superior / Chitosan derivatives were prepared by reductive alkylation using glutaraldehyde and 3-amino-1-propanol. The reducing agent used was the sodium borohydride. Tests of solubility, stability and viscosity were performed in order to evaluate these parameters effects in the reaction conditions (molar ratio of the reactants and presence of nitrogen in the reaction system). The molecular structure of commercial chitosan was determined by infrared (IR) and hydrogen nuclear magnetic resonance spectroscopy (1H NMR). The intrinsic viscosity and average molecular weight of the chitosan were determined by viscosimetry in 0.3 M acetic acid aqueous solution 0.2 M sodium acetate at 25 ?C. The derivatives of chitosan soluble in aqueous acidic medium were characterized by 1H NMR. The rheological behavior of the chitosan and of the derivative of chitosan (sample QV), which presented the largest viscosity, were studied as a function of polymer concentration, temperature and ionic strength of the medium. The results of characterization of the commercial chitosan (the degree of deacetylation obtained equal 78.45 %) used in this work confirmed a sample of low molar weight (Mv = 3.57 x 104 g/mol) and low viscosity (intrinsic viscosity = 213.56 mL/g). The chemical modification of the chitosan resulted in derivatives with thickening action. The spectra of 1H NMR of the soluble derivatives in acid aqueous medium suggested the presence of hydrophobic groups grafted into chitosan in function of the chemical modification. The solubility of the derivatives of chitosan in 0.25 M acetic acid aqueous solution decreased with increase of the molar ratio of the glutaraldehyde and 3-amino-1-propanol in relation to the chitosan. The presence of nitrogen and larger amount of reducing agent in reaction system contributed to the increase of the solubility, the stability and the viscosity of the systems. The viscosity of the polymeric suspensions in function of the shear rate increased significantly with polymer concentration, suggesting the formation of strong intermolecular associations. The chitosan presented pseudoplastic behavior with the increase in polymer concentration at a low shear rate. The derivative QV presented pseudoplastic behavior at all concentrations used and in a large range of shear rate. The viscosity of chitosan in solution decreased with an increase of the temperature and with the presence of salt. However, there was an increase of the viscosity of the chitosan solution at higher temperature (65 ?C) and ionic strength of the medium which were promoted by hydrophobic associating of the acetamide groups. The solutions of the chitosan derivatives (sample QV) were significantly more viscous than chitosan solution and showed higher thermal stability in the presence of salt as a function of the hydrophobic groups grafted into chitosan backbone / Derivados de quitosana foram preparados atrav?s de alquila??o redutiva usando glutaralde?do e 3-amino-1-propanol. O agente redutor utilizado foi o boro hidreto de s?dio. Os efeitos das vari?veis reacionais (propor??es molares dos reagentes e nitrog?nio no meio reacional) nas caracter?sticas dos pol?meros em fun??o das mudan?as estruturais foram avaliados atrav?s de testes de solubilidade, estabilidade e viscosidade. A estrutura molecular da quitosana comercial foi determinada por espectroscopia de infravermelho (IV) e de resson?ncia magn?tica nuclear de hidrog?nio (RMN 1H). A viscosidade intr?nseca e a massa molar m?dia da quitosana foram determinadas por viscosimetria, em ?cido ac?tico 0,3 M acetato de s?dio 0,2 M, a 25 ?C. Os derivados de quitosana sol?veis em meio aquoso ?cido foram caracterizados por RMN 1H. O comportamento reol?gico da quitosana e do seu derivado (amostra QV), que apresentou maior viscosidade, foram estudados em fun??o da concentra??o de pol?mero, da temperatura e da for?a i?nica do meio. Os resultados da caracteriza??o da quitosana comercial utilizada neste trabalho demonstraram uma amostra de baixa massa molar (Mv = 3,57 x 104 g/mol) e de baixa viscosidade (viscosidade intr?nseca = 213,56 mL/g). O grau m?dio de desacetila??o foi 78,45 %. A modifica??o qu?mica da quitosana resultou em derivados com caracter?sticas viscosificantes. Os espectros de RMN 1H dos derivados sol?veis em meio aquoso ?cido mostraram a inser??o de grupos hidrof?bicos na estrutura da quitosana em fun??o da modifica??o qu?mica realizada. A solubilidade dos derivados de quitosana em solu??o aquosa de ?cido ac?tico 0,25 M diminuiu com o aumento da propor??o molar do glutaralde?do e 3-amino-1-propanol em rela??o ? quitosana. A presen?a de nitrog?nio e maior quantidade de agente redutor no meio reacional contribu?ram para o aumento da solubilidade, estabilidade e viscosidade dos sistemas polim?ricos. A viscosidade das dispers?es polim?ricas em fun??o da taxa de cisalhamento aumentou significativamente com a concentra??o de pol?mero, sugerindo a forma??o de fortes associa??es intermoleculares. A quitosana apresentou comportamento pseudopl?stico com o aumento da concentra??o de pol?mero em solu??o e a baixas taxas de cisalhamento, enquanto que o seu derivado, QV, apresentou comportamento pseudopl?stico em todas as concentra??es utilizadas e em uma larga faixa de taxa de cisalhamento. A viscosidade da solu??o de quitosana diminuiu com o aumento da temperatura e com a presen?a de sal. No entanto, houve um aumento da viscosidade da solu??o de quitosana ? temperatura mais alta (65 ?C) e em maior for?a i?nica, promovido por associa??es hidrof?bicas dos grupos acetamido. As solu??es do derivado QV foram significativamente mais viscosas do que as solu??es de quitosana e obtiveram maior estabilidade t?rmica em solu??o na presen?a de sal em fun??o dos grupos hidrof?bicos inseridos na estrutura da quitosana

Quitosana

Alquila??o redutiva

Glutaralde?do

3-Amino-1-propanol

Solubilidade

Comportamento reol?gico

Chitosan

Reductive alkylation

Glutaraldehyde

3-Amino-1-propanol

Solubility

Rheological behavior

Protein Microparticles for Printable Bioelectronics

Nadhom, Hama

January 2015

In biosensors, printing involves the transfer of materials, proteins or cells to a substrate. It offers many capabilities thatcan be utilized in many applications, including rapid deposition and patterning of proteins or other biomolecules.However, issues such as stability when using biomaterials are very common. Using proteins, enzymes, as biomaterialink require immobilizations and modifications due to changing in the structural conformation of the enzymes, whichleads to changes in the properties of the enzyme such as enzymatic activity, during the printing procedures andrequirements such as solvent solutions. In this project, an innovative approach for the fabrication of proteinmicroparticles based on cross-linking interchange reaction is presented to increase the stability in different solvents.The idea is to decrease the contact area between the enzymes and the surrounding environment and also preventconformation changes by using protein microparticles as an immobilization technique for the enzymes. The theory isbased on using a cross-linking reagent trigging the formation of intermolecular bonds between adjacent proteinmolecules leading to assembly of protein molecules within a CaCO3 template into a microparticle structure. TheCaCO3 template is removed by changing the solution pH to 5.0, leaving behind pure highly homogenous proteinmicroparticles with a size of 2.4 ± 0.2 μm, according to SEM images, regardless of the incubation solvents. Theenzyme model used is Horse Radish Peroxidase (HRP) with Bovine Serum Albumin (BSA) and Glutaraldehyde (GL)as a cross-linking reagent. Furthermore, a comparison between the enzymatic activity of the free HRP and the BSAHRPprotein microparticles in buffer and different solvents are obtained using Michaelis-Menten Kinetics bymeasuring the absorption of the blue product produced by the enzyme-substrate interaction using a multichannelspectrophotometer with a wavelength of 355 nm. 3,3’,5,5’-tetramethylbenzidine (TMB) was used as substrate. As aresult, the free HRP show an enzymatic activity variation up to ± 50 % after the incubation in the different solventswhile the protein microparticles show much less variation which indicate a stability improvement. Moreover, printingthe microparticles require high microparticle concentration due to contact area decreasing. However, usingmicroparticles as a bioink material prevent leakage/diffusion problem that occurs when using free protein instead.

Printed electronic

ink

ink materials

biosensor

protein

immobilization

modification

free enzyme

protein microparticles

enzymatic activity

structural conformation

substrate

Michaelis-Menten kinetic

Km

cross-linking

TMB

stability

pH

temperature

buffer

PBS

solvents

2-Propanol

Acetonitrile

Ethylene Glycol

incubation

stability

reagent

Glutaraldehyde

CaCO3 template

HRP

BSA-HRP MP

contact area

bioink

leakage/diffusion

drop-cast.

Marquage fluorescent des protéines pour étudier les enzymes protéolytiques solubles et immobilisées par la cartographie peptidique électrophorétique

Gan, Shao MIng

06 1900

La cartographie peptidique est une méthode qui permet entre autre d’identifier les modifications post-traductionnelles des protéines. Elle comprend trois étapes : 1) la protéolyse enzymatique, 2) la séparation par électrophorèse capillaire (CE) ou chromatographie en phase liquide à haute performance (HPLC) des fragments peptidiques et 3) l’identification de ces derniers. Cette dernière étape peut se faire par des méthodes photométriques ou par spectrométrie de masse (MS). Au cours de la dernière décennie, les enzymes protéolytiques immobilisées ont acquis une grande popularité parce qu’elles peuvent être réutilisées et permettent une digestion rapide des protéines due à un rapport élevé d’enzyme/substrat. Pour étudier les nouvelles techniques d’immobilisation qui ont été développées dans le laboratoire du Professeur Waldron, la cartographie peptidique par CE est souvent utilisée pour déterminer le nombre total de peptides détectés et leurs abondances. La CE nous permet d’avoir des séparations très efficaces et lorsque couplée à la fluorescence induite par laser (LIF), elle donne des limites de détection qui sont 1000 fois plus basses que celles obtenues avec l’absorbance UV-Vis. Dans la méthode typique, les peptides venant de l’étape 1) sont marqués avec un fluorophore avant l’analyse par CE-LIF. Bien que la sensibilité de détection LIF puisse approcher 10-12 M pour un fluorophore, la réaction de marquage nécessite un analyte dont la concentration est d’au moins 10-7 M, ce qui représente son principal désavantage. Donc, il n’est pas facile d’étudier les enzymes des peptides dérivés après la protéolyse en utilisant la technique CE-LIF si la concentration du substrat protéique initial est inférieure à 10-7 M. Ceci est attribué à la dilution supplémentaire lors de la protéolyse. Alors, afin d’utiliser le CE-LIF pour évaluer l’efficacité de la digestion par enzyme immobilisée à faible concentration de substrat,nous proposons d’utiliser des substrats protéiques marqués de fluorophores pouvant être purifiés et dilués. Trois méthodes de marquage fluorescent de protéine sont décrites dans ce mémoire pour étudier les enzymes solubles et immobilisées. Les fluorophores étudiés pour le marquage de protéine standard incluent le naphtalène-2,3-dicarboxaldéhyde (NDA), la fluorescéine-5-isothiocyanate (FITC) et l’ester de 6-carboxyfluorescéine N-succinimidyl (FAMSE). Le FAMSE est un excellent réactif puisqu’il se conjugue rapidement avec les amines primaires des peptides. Aussi, le substrat marqué est stable dans le temps. Les protéines étudiées étaient l’-lactalbumine (LACT), l’anhydrase carbonique (CA) et l’insuline chaîne B (INB). Les protéines sont digérées à l’aide de la trypsine (T), la chymotrypsine (CT) ou la pepsine (PEP) dans leurs formes solubles ou insolubles. La forme soluble est plus active que celle immobilisée. Cela nous a permis de vérifier que les protéines marquées sont encore reconnues par chaque enzyme. Nous avons comparé les digestions des protéines par différentes enzymes telles la chymotrypsine libre (i.e., soluble), la chymotrypsine immobilisée (i.e., insoluble) par réticulation avec le glutaraldéhyde (GACT) et la chymotrypsine immobilisée sur billes d’agarose en gel (GELCT). Cette dernière était disponible sur le marché. Selon la chymotrypsine utilisée, nos études ont démontré que les cartes peptidiques avaient des différences significatives selon le nombre de pics et leurs intensités correspondantes. De plus, ces études nous ont permis de constater que les digestions effectuées avec l’enzyme immobilisée avaient une bonne reproductibilité. Plusieurs paramètres quantitatifs ont été étudiés afin d’évaluer l’efficacité des méthodes développées. La limite de détection par CE-LIF obtenue était de 3,010-10 M (S/N = 2,7) pour la CA-FAM digérée par GACT et de 2,010-10 M (S/N = 4,3) pour la CA-FAM digérée par la chymotrypsine libre. Nos études ont aussi démontrées que la courbe d’étalonnage était linéaire dans la région de travail (1,0×10-9-1,0×10-6 M) avec un coefficient de corrélation (R2) de 0,9991. / Peptide mapping is a routine method for identifying post-translational modifications of proteins. It involves three steps: 1) enzymatic proteolysis, 2) separation of the peptide fragments by capillary electrophoresis (CE) or high performance liquid chromatography (HPLC), 3) identification of the peptide fragments by photometric methods or mass spectrometry (MS). During the past decade, immobilized enzymes for proteolysis have been gaining in popularity because they can be reused and they provide fast protein digestion due to the high ratio of enzyme-to-substrate. In order to study new immobilization techniques developed in the Waldron laboratory, peptide mapping by CE is frequently used, where the total number of peptides detected and their abundance are related to enzymatic activity. CE allows very high resolution separations and, when coupled to laser-induced fluorescence (LIF), provides excellent detection limits that are 1000 times lower than with UV-Vis absorbance. In the typical method, the peptides produced in step 1) above are derivatized with a fluorophore before separation by CE-LIF. Although the detection sensitivity of LIF can approach 10 12 M for a highly efficient fluorophore, a major disadvantage is that the derivatization reaction requires analyte concentrations to be approx. 10 7 M or higher. Therefore, it is not feasible to study enzymes using CE-LIF of the peptides derivatized after proteolysis if the initial protein substrate concentration is <10-7 M because additional dilution occurs during proteolysis. Instead, to take advantage of CE-LIF to evaluate the efficiency of immobilized enzyme digestion of low concentrations of substrate, we propose using fluorescently derivatized protein substrates that can be purified then diluted. Three methods for conjugating fluorophore to protein were investigated in this work as a means to study both soluble and immobilized enzymes. The fluorophores studied for derivatization of protein standards included naphthalene-2,3-dicarboxaldehyde (NDA), fluoresceine-5-isothiocyanate (FITC) and 6-carboxyfluorescein N-succinimide ester (FAMSE). The FAMSE was found to be an excellent reagent that conjugates quickly with primary amines and the derivatized substrate was stable over time. The studied substrates were -lactalbumin (LACT), carbonic anhydrase (CA) and insulin chain-B (INB). The CE-LIF peptide maps were generated from digestion of the fluorescently derivatized substrates by trypsin (T), chymotrypsin (CT) or pepsin (PEP), either in soluble or insoluble forms. The soluble form of an enzyme is more active than the immobilized form and this allowed us to verify that the conjugated proteins were still recognized as substrates by each enzyme. The digestion of the derivatized substrates with different types of chymotrypsin (CT) was compared: free (i.e., soluble) chymotrypsin, chymotrypsin cross-linked with glutaraldehyde (GACT) and chymotrypsin immobilized on agarose gel particles (GELCT), which was available commercially. The study showed that, according to the chymotrypsin used, the peptide map would vary in the number of peaks and their intensities. It also showed that the digestion by immobilized enzymes was quite reproducible. Several quantitative parameters were studied to evaluate the efficacy of the methods. The detection limit of the overall method (CE-LIF peptide mapping of FAM-derivatized protein digested by chymotrypsin) was 3.010-10 M (S/N = 2.7) carbonic anhydrase using insoluble GACT and 2.010-10 M (S/N = 4.3) CA using free chymotrypsin. Our studies also showed that the standard curve was linear in the working region (1.0×10-9-1.0×10-6 M) with a correlation coefficient (R2) of 0.9991.

α-Lactalbumine

Anhydrase carbonique

Insuline chaîne B

Naphtalène-2,3-dicarboxaldéhyde (NDA)

Fluorescéine-5-isothiocyanate (FITC)

Marquage fluorescent

Enzymes immobilisées

Glutaraldéhyde (GA)

Cartographie peptidique

Électrophorèse capillaire (CE)

Fluorescence induite par laser (LIF)

α-Lactalbumin

Carbonic anhydrase

Insulin chain B

Naphthalene-2,3-dicarboxaldehyde (NDA)

Fluorescein-5-isothiocyanate (FITC)

6-carboxyfluorescein

Fluorescent conjugation

Immobilized enzymes

Glutaraldehyde (GA)

Peptide mapping

Marquage fluorescent des protéines pour étudier les enzymes protéolytiques solubles et immobilisées par la cartographie peptidique électrophorétique

Gan, Shao MIng

06 1900

No description available.

α-Lactalbumine

Anhydrase carbonique

Insuline chaîne B

Naphtalène-2,3-dicarboxaldéhyde (NDA)

Fluorescéine-5-isothiocyanate (FITC)

Marquage fluorescent

Enzymes immobilisées

Glutaraldéhyde (GA)

Cartographie peptidique

Électrophorèse capillaire (CE)

Fluorescence induite par laser (LIF)

α-Lactalbumin

Carbonic anhydrase

Insulin chain B

Naphthalene-2,3-dicarboxaldehyde (NDA)

Fluorescein-5-isothiocyanate (FITC)

6-carboxyfluorescein

Fluorescent conjugation

Immobilized enzymes

Glutaraldehyde (GA)

Peptide mapping