Produção e avaliação das aplicações de enzimas quitinolíticas e queratinolíticas

Santos, Emerson dos [UNESP]

25 August 2011

Made available in DSpace on 2014-06-11T19:32:09Z (GMT). No. of bitstreams: 0 Previous issue date: 2011-08-25Bitstream added on 2014-06-13T21:03:26Z : No. of bitstreams: 1 santos_e_dr_arafcf.pdf: 7245371 bytes, checksum: cb0c4511a4ad674226e788f40dc0c01a (MD5) / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Universidade Estadual Paulista (UNESP) / Enzimas são catalisadores fundamentais para os sistemas biológicos sendo amplamente estudadas e aplicadas em todo o mundo, especialmente na área da saúde. Neste trabalho foi avaliada a aplicação de enzimas quitinolíticas e queratinolíticas em ensaios in vitro contra Pedicullus humanus capitis e na degradação de calos humanos, respectivamente. Foram selecionados os micro-organismos com maior potencial para produção dessas enzimas e determinados os parâmetros de produção, as condições de separação, purificação e caracterização das enzimas. Os micro-organismos com maior potencial para a produção de quitinases e queratinases foram os fungos Metarhizium anisopliae CG374 e Aspergillus oryzae, respectivamente. As maiores produções de quitinases foram obtidas em biorreator a 28°C, pH 7,0, 1,5 vvm e 200 rpm após 120 h. Quando produzida em biorreator hiperbárico sob pressão de 5 bar, apresentou um aumento de 21,3% na produtividade em relação ao biorreator convencional. Para queratinases em biorreator, os parâmetros de produção foram 28°C, pH 6, 200 rpm, 1,5 vvm e 120 h. A produção das quitinases e queratinases em biorreator foi 83 e 154% maior do que em frascos Erlenmeyer, respectivamente. A quitinase foi concentrada 5,12 vezes na purificação apresentando massas molares aproximadas de 24, 28 e 80 kDa. Fração purificada contendo quitinase apresentou estabilidade a 40°C por 60 minutos. A queratinase foi concentrada 4,52 vezes após purificação com massas molares de 40 e 50 kDa apresentando estabilidade térmica a 40°C por 60 min. A avaliação das enzimas quitinolíticas frente a piolhos humanos apontou para uma eficiência 9,1% maior quando comparadas com produtos comerciais. A avaliação da ação de enzimas queratinolíticas na degradação de calos humanos demonstrou resultados significativos quando comparados com produtos disponíveis no mercado... / Enzymes are catalysts for fundamental biological systems is extensively studied and applied worldwide, especially in health. In this study were evaluated the application of enzymes chitinolytic and keratinolytic in tests in vitro against Pedicullus humanus capitis and degradation of human callus, respectively. Were selected microorganisms with the greatest potential for production of these enzymes and determined the production parameters, conditions of separation, purification and characterization of enzymes. The microorganisms with the higher potential for the production of chitinases and keratinases were Metarhizium anisopliae CG374 and Aspergillus oryzae, respectively. The highest yields of chitinases obtained in fermentations in a bioreactor were 28°C, pH 7.0, 1.5 vvm and 200 rpm after 120 h. When produced in the hyperbaric bioreactor at a pressure of 5 bar, an increase of 21.3% in yield over conventional production in a conventional bioreactor was observed. To keratinases in a bioreactor, the production parameters were 28°C, pH 6.0, 200 rpm, and 1.5 vvm after 120h. The production of chitinases and keratinases in bioreactor was 83 and 154% higher than in Erlenmeyer flasks, respectively. The chitinase was 5.12 times concentred on the purification presenting molar weight of approximately 24, 28 and 78 kDa. Fraction containing purified chitinase showed thermal stability of 40°C for 60 min. Keratinase was concentred 4.52 times after purification and presents molar weight of 40 and 50 kDa. The purified fraction was thermal stability at 40°C for 60 min. Evaluation of chitinolytic enzymes against human lice showed an efficiency of 9.1% higher for the enzymatic extract when compared with commercial products. The evaluation of the action of keratinolytic enzyme in the degradation of human callus showed significative results when compared to products on the market less time reaching maximum degradation

Enzimas - Produção

Quitinase

Queratinase

Enzyme

Chitinase

Keratinase

Biological Control Potential of Streptomyces Isolates on Pathogens (Helminthosporium solani and Pythium ultimum) of Potatoes

Taylor, Shae Jamison

30 July 2020

Two fungal pathogen species, Helminthosporium solani and Pythium ultimum, cause significant economic loss to potato (Solanum tuberosum) growers throughout the world. These pathogens have substantial differences in cellular makeup, pathogenicity, and modes of infection. We studied the efficacy of 82 isolates within the bacterial genus Streptomyces in inhibiting these pathogens under laboratory and greenhouse conditions. Derivatives of Streptomyces have significant implications in medicinal use because of their antibiotic and antifungal properties. Under in-vitro conditions, 25% of Streptomyces isolates inhibited growth of P. ultimum, up to 81%. Ninety-five percent of the Streptomyces isolates inhibited growth of H. solani, with a maximum of 70%. In storage, these findings lead us to believe substantial differences between Streptomyces isolates will allow for some isolates to be effective biological controls at controlling diseases on common pathogens of potatoes.

Helminthosporium

Pythium

biocontrol

chitinase

Streptomyces

Life Sciences

Studies on chitin degradation and assimilation systems in hyperthermophilic archaea / 超好熱性アーキアにおけるキチン分解・資化系に関する研究

Mehwish, Aslam

25 September 2017

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第20712号 / 工博第4409号 / 新制||工||1685(附属図書館) / 京都大学大学院工学研究科合成・生物化学専攻 / (主査)教授 跡見 晴幸, 教授 森 泰生, 教授 浜地 格 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM

chitin

hyperthermophile

archaea

hydrogen

chitinase

500

Mass spectrometric analysis of chitooligosaccharides and their interaction with proteins

Bahrke, Sven

January 2008

Chitooligosaccharides are composed of glycosamin and N-acetylglycisamin residues. Gel permeations chromatography is employed for the separation of oligomers, cation exchange chromatography is used for the separation of homologes and isomers. Trideuterioacetylation of the chitooligosaccharides followed by MALDI-TOF mass spectrometry allowes for the quantitation of mixtures of homologes. vMALDI LTQ multiple-stage MS is employed for quantitative sequencing of complex mixtures of heterochitooligosaccharides. Pure homologes and isomers are applied to biological assays. Chitooligosaccahrides form high-affinity non-covalent complexes with HC gp-39 (human cartilage glycoprotein of 39 kDa). The affinity of the chitooligosaccharides depends on DP, FA and the sequence of glycosamin and N-acetylglycosamin moieties. (+)nanoESI Q TOF MS/MS is used for identification of a high-affinity binding chitooligosaccharide of a non-covalent chitinase B - chitooligosaccharide complex. DADAA is identified as the heterochitoisomer binding with highest affinity and biostability to HC gp-39. Fluorescence based enzyme assays confirm the results. / Chitooligosaccharide sind aus Glycosamin und N-Acetylglycosamun aufgebaut. Gelpermeationschromatographie wird für die Trennung von Oligomeren verwendet, die Kationenaustauschchromatographie wird zur Trennung von homologen- und Isomerengemischen angewendet. Trideuterioacetylierung der Chitooligosaccharide gefolgt von einer Analyse mittels MALDI-TOF MS erlaubt die quantitative Analyse von Homologengemischen. vMALDI LTQ multiple-stage MS wird angewendet zur Sequenzanalyse und Quantifizierung komplexer Gemische von Heterochitooligosacchariden. Reine Homologe und Isomere werden für biologische Assays verwendet. Dabei zeigt sich, dass Chitooligosaccharide mit HC gp-39 hochaffine Komplexe bilden. Die Affinität der Chitooligosaccharide hängt vom DP, FA und der Sequenz der Chitooligosaccharide ab. (+)nanoESI Q TOF MS/MS wird erfolgreich angewendet zur Identifizierung eines Chitooligosaccharides, das mit hoher Affinität an Chitinase B (Serratia marcescens) bindet. DADAA wurde als die Sequenz des Isomers identifiziert, das mit höchster Affinität und Biostabilität an aktive Chitinase B bindet. Fluoreszenz basierte Enzymassays konnten dieses Ergebnis bestätigen.

Chitooligosaccharide

HPLC

Massenspektrometrie

Chitolektine

Chitinase

Chitooligosaccharides

HPLC

Mass Spectrometry

Chitolectins

Chitinase

Chemistry and allied sciences

Functional characterization of the Cydia pomonella granulovirus matrix metalloprotease

Ishimwe, Egide

January 1900

Master of Science / Department of Biology / A. Lorena Passarelli / Cydia pomonella granulovirus (CpGV) is a member of the Baculoviridae family of viruses. The CpGV open reading frame 46 (CpGV-ORF46) predicts a 545 amino acid protein that shares homology with matrix metalloproteases (MMPs), a family of zinc-dependent endopeptidases that degrade extracellular matrix proteins. In silico analyses revealed the presence of putative mmp genes in all species from the Betabaculovirus genus, while no mmps were identified in members of the Alphabaculovirus, Gammabaculovirus or Deltabaculovirus genera. Unlike most cellular MMPs, baculovirus MMPs do not have a propeptide domain, a domain involved in regulating MMP activation, or a hemopexin-like domain, which is necessary for substrate binding and specificity in many MMPs. However, Betabaculovirus MMPs do contain a predicted conserved zinc-binding motif (HEXGHXXGXXHS/T) within their catalytic domain. The function of CpGV-MMP and its effects on baculovirus replication in cultured cells and insect larvae were investigated. CpGV-MMP was expressed in and purified from Escherichia coli, and activity was measured using a generic MMP substrate in vitro. CpGV-MMP had in vitro activity and its activity was specifically inhibited by MMP inhibitors. To study the effects of CpGV-MMP on virus replication and dissemination, CpGV-MMP was expressed from Autographa californica nucleopolyhedrovirus (AcMNPV) under the control of a strong and constitutive promoter, the Drosophila heat shock 70 protein promoter. Expression of CpGV-MMP did not affect virus replication in cultured cells. The effects of expressing CpGV-MMP from AcMNPV during larval infection were evaluated in the presence or absence of the AcMNPV chitinase and cathepsin genes. Insect bioassays showed that the absence of cathepsin resulted in a significant delay in larval time of death; however, this delay was compensated by expression of CpGV-MMP. In addition, larval time of death was accelerated when cathepsin, chitinase, and CpGV-MMP were all expressed. Finally, we determined the effects of CpGV-MMP on larvae melanization and liquefaction. CpGV-MMP was able to promote larvae melanization in the absence of cathepsin. CpGV-MMP, in the absence of cathepsin, was not able to promote larvae liquefaction. When chitinase was engineered to be secreted from cells, CpGV-MMP rescued liquefaction in the absence of cathepsin. In conclusion, CpGV-MMP is a functional MMP which can enhance larvae mortality with the presence of cathepsin. In addition, CpGV-MMP can promote larvae melanization; however, it can only promote liquefaction when chitinase is engineered to be secreted from cells.

Virology

Baculovirus

Matrix metalloproteases

Cathepsin

Chitinase

Biology (0306)

Virology (0720)

Experimental and computational studies of a fungal chitinase

Khan, Faez Iqbal

January 2015

Submitted in fulfillment of the requirements of the degree of Doctor of Philosophy: Chemistry, Durban University of Technology, 2015. / Chitin, the second most abundant natural biopolymer, is composed of repeating units of N-acetyl-β-D-glucosamine and primarily forms the structural component of protective biological matrices such as fungal cell walls and exoskeletons of insects. Chitinases are a ubiquitous class of extracellular enzymes that have gained attention in the past few years due to their wide range of biotechnological applications, especially in the field of agriculture for bio-control of fungal phytopathogens. They play an important role in the defense of organisms against chitin-containing parasites by hydrolyzing the β-1,4-linkages in chitin and hence act as anti-fungal as well as anti-biofouling agents. Moreover, the effectiveness of conventional insecticides is increasingly compromised by the occurrence of resistance and thus, chitinases offer a potential alternative to the use of chemical fungicides. In recent years, thermostable enzymes isolated from thermophilic microorganisms have gained widespread attention in industrial, medical, environmental and biotechnological applications due to their inherent stability at high temperatures and a wide range of pH optima. Determination of the three- dimensional structure of a protein can provide important details about its biological functions and its mode of action. However, despite their significance, the precise three-dimensional structures of most of the chitinases, including those isolated from Thermomyces lanuginosus is not fully characterized so far. Hence, the main focus of the present study was to gain a better understanding of the structural features of chitinases obtained from this thermostable fungus using both experimental and computational techniques, and their relationship with their activity profiles. The genes encoding thermostable chitinase II from T. lanuginosus were isolated and cloned in both E. coli as well as the Pichia pastoris expression system. Analysis of the nucleotide sequences revealed that the chitinase II gene (1196 bp) encodes a 343 amino acid protein of molecular weight 36.65 kDa whereas the chitinase I gene (1538 bp) encodes a 400 amino acid protein of molecular weight 44.14 kDa. In silico protein modeling was helpful in predicting the 3D models of the novel chitinase II enzyme, followed by the prediction of its active sites. The presence of Glu176 was found to be essential for the activity of chitinase II. Similarly, analysis of chitinase I revealed several active sites in its structural framework. A 10 ns Molecular dynamics (MD) simulations was implemented to assess the conformational preferences of chitinases. The MD trajectories at different temperatures clearly revealed that the stability of the enzymes were maintained at higher temperatures. Additionally, a constant pH molecular dynamics simulations at a pH range 2-6 was performed to establish the optimum activity and stability profiles of chitinase I and chitinase II. For this purpose, the Molecular Dynamics simulations were carried out at fixed protonation states in an explicit water environment to evaluate the effect of the physiological pH on chitinase I and II enzymes obtained from T. lanuginosus. The results suggest a strong conformational pH dependence of chitinases. These enzymes retained their characteristic TIM Barrel fold at the respective protonated conditions, thus validated the experimental outcomes. Further, the different stability and flexibility predictions were used to assess the relation of point mutations and enzyme stabilities. Our results pave the way to engineer new and better thermostable enzymes.

Chitin--Biotechnology--South Africa

Chitinase--South Africa

Biopolymers--South Africa

Secretion of the chitinolytic machinery in Serratia marcescens

Hamilton, Jaeger

January 2013

There are six known secretion systems in Gram negative bacteria, referred to as Type 1 to Type 6 respectively, which are dedicated to moving substrate across the outer membrane. Secretion systems are broadly separated into those that move their substrate across the cell envelope in a single translocation event (one-step systems), and those that are dependent on the Sec or Tat machineries for export to the periplasm (two-step systems). Serratia marcescens is an important opportunistic human pathogen and has gathered a lot of interest due to its repertoire of secreted proteins. These include the haem-scavenging protein HasA, which is secreted by a Type 1 secretion system, and the cytotoxic haemolysin ShlA, which is secreted as part of a two-partner Type 5 secretion system. Serratia marcescens also encodes a Type 6 secretion system, which is known to translocate at least six effector molecules directly into other bacterial target cells. Serratia marcescens is a model organism in terms of its ability to degrade the quite intractable polymer chitin, for which it produces three chitinase enzymes ChiA, ChiB, ChiC and a chitin-binding protein Cbp21, which hydrolyse the ß-1,4 link in the chitin chain and promote binding of chitinase to the chitin substrate respectively. These chitinolytic enzymes are utilised by S. marcescens for both basic physiology and also in pathogenesis. In this work, genetic, biochemical and proteomic approaches identified, for the first time, genes that are essential for the secretion of all three chitinases as well as Cbp21. A genetic screen identified genes encoding a holin-like membrane protein (ChiW) and a putative L-alanyl-D-glutamate endopeptidase (ChiX). Subsequent quantitative proteomics experiments and biochemical analyses established that ChiW and ChiX were required for secretion of the entire chitinolytic machinery. Chitinase secretion was observed to be blocked at a late stage in the mutant strains as normally secreted enzymes were found to accumulate in the periplasm, thus implicating ChiW and ChiX in a novel outer membrane protein translocation process. It is proposed that the bacterial genome-encoded holin-like protein and endopeptidase identified represent a putative secretion system utilised by Gram-negative bacteria. In addition to this, genes encoding the chitinolytic machinery and the putative secretion apparatus were shown to be bimodally regulated and co-ordinately expressed.

579

Growth of phytopathogenic fungi in the presence of partially acetylated chitooligosaccharides

Oliveira Jr, E. N., Gueddari, Nour E. El, Moerschbacher, Bruno M., Peter, Martin, Franco, Telma

January 2008

Four phytopathogenic fungi were cultivated up to six days in media containing chitooligosaccharide mixtures differing in average DP and FA. The three different mixtures were named Q3 (which contained oligosaccharides ofDP2–DP10, withDP2–DP7 asmain components), Q2 (which contained oligosaccharides of DP2–DP12, with DP2–DP10 as main components) and Q1 (which derived from Q2 and contained oligomers of DP5–DP8 with hexamer and a heptamer as the main components). The novel aspect of this work is the description of the effect of mixtures of oligosaccharides with different and known composition on fungal growth rates. The growth rate of Alternaria alternata and Rhizopus stolonifer was initially inhibited by Q3 and Q2 at higher concentrations. Q1 had a growth stimulating effect on these two fungi. Growth of Botrytis cinerea was inhibited by Q3 and Q2, while Q1 had no effect on the growth of this fungus. Growth of Penicillium expansum was only slightly inhibited by higher concentrations of sample Q3, while Q2 and Q1 had no effect. The inhibition of growth rates or their resistance toward chitooligosaccharides correlated with the absence or presence of chitinolytic enzymes in the culture media, respectively.

Chitosan

Chitinase

Fungi

Oligosaccharides

Phytopathogens

Chemistry and allied sciences

Purification of Brassica juncea chitinase BJCHI1 from transgenic tobacco

馮景良, Fung, King-leung.

January 2001

published_or_final_version / Botany / Master / Master of Philosophy

Brassica.

Chitinase.

Plant defenses.

Functions of the viral chitinase (CHIA) in the processing, subcellular trafficking and cellular retention of proV-CATH from Autographa californica multiple nucleopolyhedrovirus

Hodgson, Jeffrey James

05 January 2012

The baculovirus chitinase (CHIA) and cathepsin protease (V-CATH) enzymes cause terminal host insect liquefaction, thereby enhancing dissemination of progeny virions in nature. Regulated and delayed cellular release of these host tissue-degrading enzymes ensures liquefaction starts only after optimal viral replication has occurred. Baculoviral CHIA remains intracellular due to its C-terminal KDEL endoplasmic reticulum (ER) retention motif. However, the intracellular processing and trafficking of the baculovirus v-cath expressed cathepsin (V-CATH) is poorly understood and a mechanism for cellular retention of the inactive V-CATH progenitor (proV-CATH) has not been determined. The cathepsins of Autographa californica multiple nucleoplyhedrovirus (AcMNPV) and most other group I alphabaculoviruses have well-conserved chymotrypsin cleavage (Y11) and myristoylation sites (G12) suggestive of proteolytic cleavage to generate proV-CATH, and subsequent acylation which could promote membrane anchoring in order to foster cellular retention of the protein. Proteolytic iii N-terminal processing of baculoviral procathepsin was determined by fusing HA epitope-coding tags to the 5’ and/or 3’ ends of v-cath, indicating that the gene is expressed as a pre-proenzyme. However no evidence for myristoylation of proV-CATH was found, suggesting that another mechanism is responsible for retaining proV-CATH in cells. Prior evidence suggested that CHIA is a proV-CATH folding chaperone and that lack of chiA expression causes proV-CATH to become insoluble and unable to mature into V-CATH enzyme. A putative CHIA chaperone activity for assisting in proV-CATH folding implies that proV-CATH and CHIA interact in the ER of infected cells. Fluorescence microscopy demonstrated co-localization of CHIA-GFP and proV-CATH-RFP fusion proteins in the ER. An mRFP-based bimolecular fluorescence complementation (BiFC) assay helped to determine not only that AcMNPV proV-CATH interacts directly with the full-length viral CHIA, but also that it independently binds to the N-terminal chitin-binding domain (CBD) and C-terminal active site domain (ASD) of CHIA, in the ER during virus replication. Moreover, reciprocal Ni/HIS pull-downs of HIS-tagged proteins confirmed the proV-CATH interactions with CHIA, or with the CBD and ASD biochemically. The reciprocal co-purification of proV-CATH with all three polypeptides (CHIA, CBD, ASD) suggests proV-CATH specifically interacts with each of them, and corroborates the BiFC data. Furthermore, CHIA KDEL deletion allowed for premature secretion of not only CHIA but also of proV-CATH, suggesting that the CHIA/proV-CATH interaction in the ER aids cellular retention of proV-CATH. In contrast to prior reports, it was also determined that CHIA is iv dispensable for correct folding of proV-CATH since proV-CATH produced by a chiA-deficient virus was soluble, prematurely secreted from cells and could mature into V-CATH enzyme. Taken together, these data indicate that the viral chitinase plays a major role in ensuring that proV-CATH is neither prematurely secreted nor activated to V-CATH enzyme.

baculovirus

chitinase

proV-CATH

enzymes

protein-protein interactions