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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Host induced alteration of eastern equine encephalomyelitis virus in Tenebrio molitor L.

Hartley, Charles Fred, January 1957 (has links)
Thesis (Ph. D.)--University of Wisconsin--Madison, 1957. / Typescript. Vita. eContent provider-neutral record in process. Description based on print version record. Includes bibliographical references (leaves 48-51).
2

Chemosensitivity in mealworms and Darkling beetles (Tenebrio molitor) across oxygen and carbon dioxide gradients

Patterson, Andrew King 30 August 2016 (has links)
No description available.
3

Purificação, caracterização, clonagem e seqüenciamento de β-glicosidades de Tenebrio molitor (Coleoptera) / Purification, characterization, cloning and sequencing of β-glycosidases from Tenebrio molitor (Coleoptera)

Ferreira, Alexandre Hamilton Pereira 14 March 2001 (has links)
No lúmen do intestino médio da larva de Tenebrio molitor existem 4 β-glicosidases (denominadas 1, 2, 3a e 3b), que não estão presentes na comida do animal. Elas foram purificadas usando-se técnicas de eletroforese e cromatografias de troca iônica e interação hidrofóbica. A β-Glicosidase 1 (Mr 59.000) é instável a 30°C mas é estabilizada na presença do substrato. Ela praticamente não tem atividade sobre galactosídeos e cliva di- e oligossacarídeos. A enzima possui apenas 1 sítio ativo que apresenta 4 subsítios para ligação de glicose. Seu papel fisiológico deve ser o da clivagem de oligo- e principalmente dissacarídeos. A β-Glicosidase 2 (Mr 67.000) é muito instável a 30°C e hidrolisar com maior eficiência galactosídeos sintéticos, cliva muito mal lactose e é incapaz de clivar glucosídeos. Ela apresenta dois sítios ativos sendo que um deles cliva MUβDgal e lactose, que é ativado por Triton X-100, enquanto o outro não é ativado pelo detergente e hidrolisa NPβDgal e NPβDfuc. O papel fisiológico para esta enzima não está claro, mas imagina-se que ela esteja envolvida na digestão de galcatolipídeos. As β-Glicosidases 3a e 3b (Mr 59.000) parecem ser isoformas, uma vez que elas têm parâmetros cinéticos semelhantes, perfis de eluição, de peptídeos gerados por clivagem proteolítica, em HPLC idênticos e a mesma seqüência de aminoácidos para um peptídeo interno comum. Um anticorpo específico produzido contra a β-Glicosidase 3a reconhece a β-Glicosidase 3b, mas não reconhece as β-Glicosidases 1 e 2. Dois clones foram obtidos usando esse anticorpo para selecionar uma biblioteca de cDNA obtida dos rnRNAs do intestino médio de Tenebrio molitor. O resultado final mostrou um cDNA de 1.570 pb codificando para uma proteína madura de 485 aminoácidos. As proteínas codificadas pelos dois cDNAs têm somente 4 aminoácidos de diferentes e podem corresponder às β-Glicosidases 3a e 3b. As seqüências mostraram uma alta similaridade com proteínas da família 1 de glicosídeo hidrolases e codificam todos os peptídeos seqüenciados a partir da clivagem das β-Glicosidases 3a e 3b purificadas. Através de imunocitolocalização usando o anticorpo que reconhece as β-Glicosidases 3a e 3b, foi mostrado que essas são secretadas na parte posterior do intestino médio por uma via exocítica. Essas enzimas tem quatro subsítios para a ligação da glicose e podem hidrolisar di- e oligossacarídeos, alquil glicosídeos e glicosídeos tóxicos de plantas. Experimentos de competição entre substratos, mostraram que elas têm só um sítio ativo responsável para a hidrólise de todos os substratos. Seu papel deve ser principalmente a digestão intermediária de hemiceluloses e celulose. / In the midgut lumen of Tenebrio molitor larvae there are 4 β-glycosidases (named 1, 2, 3a and 3b), not present in the animal food. They were purified with electrophoresis, ion exchange and hydrophobic chromatographies. β-glycosidase 1 (relative molecular weight - Mr 59,000) is unstable at 30°C but is stabilized by substrates. The enzyme hydrolyses di- and oligoglucosides and has a residual activity against galactosides. It has 4 subsites for glucose binding in the active site and its physiological role is the hydrolysis of oligo- and mainly disaccharides. β-glycosidase 2 (Mr 67,000) is unstable at 30°C and hydrolyses efficiently only synthetic galactosides, has poor activity against lactose and is unable to use glucosides as substrates. This enzyme has two active sites. One of them is activated by Triton X-100 and hydrolyses MUβDgal. The other active site is not activated by the detergent and act upon NPβDgal and NPβDfuc. The physiological role ofthis enzyme may be the digestion of galactolipids. The β-glycosidases 3a and 3b (Mr 59,000) are likely isoforms, since they have similar kinetic parameters, identical HPLC peptide elution patterns after proteolytic cleavage and the same amino acid sequence of an internal peptide. A specific antibody raised against β-glycosidase 3a recognizes β-glycosidase 3b, but not β-glycosidase 1 and 2. Two clones were obtained screening a cDNA library, trom Tenebrio molitor midgut mRNA, with this antibody. The final result showed a cDNA of 1,570 pb coding for 485 amino acids in mature protein. The protein sequences showed high similarity with family 1 glycoside hydrolases and have the same amino acid sequence determined for peptides obtained after proteolytic hydrolysis of β-glycosidase 3a and 3b. The immunocytolocalization with this antibody showed that β-glycosidase 3a and 3b are secreted by exocytosis of small vesicles present in posterior midgut. These enzymes have four subsites for glucose binding and can hydrolyse di- and oligosaccharides, alkyl glucosides and toxic plant glucosides. Substrate competition experiments showed that they have only one active site responsible for the hydrolysis of all substrates. Their role may be mainly the intermediate digestion of hemicelluloses and cellulose.
4

Purificação, caracterização, clonagem e seqüenciamento de β-glicosidades de Tenebrio molitor (Coleoptera) / Purification, characterization, cloning and sequencing of β-glycosidases from Tenebrio molitor (Coleoptera)

Alexandre Hamilton Pereira Ferreira 14 March 2001 (has links)
No lúmen do intestino médio da larva de Tenebrio molitor existem 4 β-glicosidases (denominadas 1, 2, 3a e 3b), que não estão presentes na comida do animal. Elas foram purificadas usando-se técnicas de eletroforese e cromatografias de troca iônica e interação hidrofóbica. A β-Glicosidase 1 (Mr 59.000) é instável a 30°C mas é estabilizada na presença do substrato. Ela praticamente não tem atividade sobre galactosídeos e cliva di- e oligossacarídeos. A enzima possui apenas 1 sítio ativo que apresenta 4 subsítios para ligação de glicose. Seu papel fisiológico deve ser o da clivagem de oligo- e principalmente dissacarídeos. A β-Glicosidase 2 (Mr 67.000) é muito instável a 30°C e hidrolisar com maior eficiência galactosídeos sintéticos, cliva muito mal lactose e é incapaz de clivar glucosídeos. Ela apresenta dois sítios ativos sendo que um deles cliva MUβDgal e lactose, que é ativado por Triton X-100, enquanto o outro não é ativado pelo detergente e hidrolisa NPβDgal e NPβDfuc. O papel fisiológico para esta enzima não está claro, mas imagina-se que ela esteja envolvida na digestão de galcatolipídeos. As β-Glicosidases 3a e 3b (Mr 59.000) parecem ser isoformas, uma vez que elas têm parâmetros cinéticos semelhantes, perfis de eluição, de peptídeos gerados por clivagem proteolítica, em HPLC idênticos e a mesma seqüência de aminoácidos para um peptídeo interno comum. Um anticorpo específico produzido contra a β-Glicosidase 3a reconhece a β-Glicosidase 3b, mas não reconhece as β-Glicosidases 1 e 2. Dois clones foram obtidos usando esse anticorpo para selecionar uma biblioteca de cDNA obtida dos rnRNAs do intestino médio de Tenebrio molitor. O resultado final mostrou um cDNA de 1.570 pb codificando para uma proteína madura de 485 aminoácidos. As proteínas codificadas pelos dois cDNAs têm somente 4 aminoácidos de diferentes e podem corresponder às β-Glicosidases 3a e 3b. As seqüências mostraram uma alta similaridade com proteínas da família 1 de glicosídeo hidrolases e codificam todos os peptídeos seqüenciados a partir da clivagem das β-Glicosidases 3a e 3b purificadas. Através de imunocitolocalização usando o anticorpo que reconhece as β-Glicosidases 3a e 3b, foi mostrado que essas são secretadas na parte posterior do intestino médio por uma via exocítica. Essas enzimas tem quatro subsítios para a ligação da glicose e podem hidrolisar di- e oligossacarídeos, alquil glicosídeos e glicosídeos tóxicos de plantas. Experimentos de competição entre substratos, mostraram que elas têm só um sítio ativo responsável para a hidrólise de todos os substratos. Seu papel deve ser principalmente a digestão intermediária de hemiceluloses e celulose. / In the midgut lumen of Tenebrio molitor larvae there are 4 β-glycosidases (named 1, 2, 3a and 3b), not present in the animal food. They were purified with electrophoresis, ion exchange and hydrophobic chromatographies. β-glycosidase 1 (relative molecular weight - Mr 59,000) is unstable at 30°C but is stabilized by substrates. The enzyme hydrolyses di- and oligoglucosides and has a residual activity against galactosides. It has 4 subsites for glucose binding in the active site and its physiological role is the hydrolysis of oligo- and mainly disaccharides. β-glycosidase 2 (Mr 67,000) is unstable at 30°C and hydrolyses efficiently only synthetic galactosides, has poor activity against lactose and is unable to use glucosides as substrates. This enzyme has two active sites. One of them is activated by Triton X-100 and hydrolyses MUβDgal. The other active site is not activated by the detergent and act upon NPβDgal and NPβDfuc. The physiological role ofthis enzyme may be the digestion of galactolipids. The β-glycosidases 3a and 3b (Mr 59,000) are likely isoforms, since they have similar kinetic parameters, identical HPLC peptide elution patterns after proteolytic cleavage and the same amino acid sequence of an internal peptide. A specific antibody raised against β-glycosidase 3a recognizes β-glycosidase 3b, but not β-glycosidase 1 and 2. Two clones were obtained screening a cDNA library, trom Tenebrio molitor midgut mRNA, with this antibody. The final result showed a cDNA of 1,570 pb coding for 485 amino acids in mature protein. The protein sequences showed high similarity with family 1 glycoside hydrolases and have the same amino acid sequence determined for peptides obtained after proteolytic hydrolysis of β-glycosidase 3a and 3b. The immunocytolocalization with this antibody showed that β-glycosidase 3a and 3b are secreted by exocytosis of small vesicles present in posterior midgut. These enzymes have four subsites for glucose binding and can hydrolyse di- and oligosaccharides, alkyl glucosides and toxic plant glucosides. Substrate competition experiments showed that they have only one active site responsible for the hydrolysis of all substrates. Their role may be mainly the intermediate digestion of hemicelluloses and cellulose.
5

Využití hmyzí mouky pro potravinářské a krmní účely / Use of insect flour for food and feed purposes

Árendásová, Veronika January 2021 (has links)
Insect meal has excellent potential as food or feed. There is a need to provide enough food for the growing population, which is linked to the increasing demand for livestock production. Meat and fish have always been the staple of the human diet as a rich source of proteins and fats for human nutrition. Fish is a good source of animal protein and fat for humans, which forms the basis of the diet of a large number of people who generally live in coastal areas. The increasing demand for fish is associated with a growing interest in high-quality and affordable fish feed. Nowadays, the main ingredient in fish feed is fishmeal, and the price is constantly increasing. The sustainability of the aquaculture industry depends on finding a substitute for fishmeal with the same nutritional value and availability. Recently, there has been a growing interest in animal protein from insects for fish fattening. This thesis focused on analysing insect meal from mealworm larvae (Tenebrio molitor) and its use for food and feed purposes. The theoretical part describes the mealworm, the use of insect meal for human nutrition, and fish fattening. It also describes the requirements of fish for individual nutrients and the characterisation of insects for feeding purposes, focusing on the mealworm used as an alternative feed ingredient in fish. The individual major nutrients, namely protein, lipids, fatty acids, amino acids, fibre, chitin, and selected minerals, were determined in the experimental part. The experimental part was divided into two parts, and the first part was divided into two phases. The first phase was used to determine the nutritional components in two fractions of insect meal from Tenebrio molitor larvae. The first fraction contained the fine fraction, and the second fraction the coarse fraction of insect meal. In the second phase, the content of nutritionally significant components was only determined in the insect meal from dried larvae without fractionation. A fish feed was designed from the analyses results. In the second part, the effect of the addition of insect meal from Tenebrio molitor for food purposes was investigated; specifically, the sensory properties of muffins were monitored. From the results, it can be observed that the nutritional composition of the insect meal suggests the possibility of using the mealworm larvae as an ingredient in the fish diet. The insect meal contains a high proportion of valuable proteins and lipids necessary for fish farming and a low proportion of carbohydrates, which unlike humans, fish do not need in their diet. The sensory analysis results indicate that consumers are not prepared to eat foods with added insects.
6

Gender in factors influencing the infection of the beetle, Tenebrio molitor with the tapeworm, Hymenolepis diminuta

Shea, John Francis 16 October 2003 (has links)
No description available.
7

Estrutura e função das cisteína proteinases intestinais do besouro Tenebrio molitor / Structure and function of intestinais cysteine proteinases of Tenebrio molitor beetle

Beton, Daniela 17 December 2009 (has links)
A catepsina L é uma cisteína proteinase da família da papaína (clã CA, família C1), sendo esta família a mais conhecida entre as cisteína proteinase. A catepsina L, como outras proteinases da família C1, é sintetizada como uma pró-enzima inativa que é ativada através da remoção do pró-peptídeo. Os pró-peptídeos das catepsinas da subfamília catepsina L apresentam um motivo consenso, denominado motivo ERFNIN. A catepsina L corresponde a principal proteinase digestiva em Tenebrio molitor. No nosso laboratório 3 pró-catepsinas L (pCALs) foram clonadas e seqüenciadas a partir de uma biblioteca de cDNA de intestino médio de larvas de T. molitor: pCAL1 (CAL lisossomal), pCAL2 e pCAL3 (enzimas digestivas). Estas proteinases apresentam o motivo ERFNIN e os resíduos envolvidos na catálise: Cys25, His169, e Asn175 com Gln19 (numeração da papaína). Neste trabalho descrevemos a clonagem em vetores de expressão e a expressão em bactérias das sequências codificadoras de pCAL1, pCAL2 e pCAL3. As pró-catepsinas L recombinantes foram purificadas por cromatografia de afinidade e a incubação em pH ácido resultou na formação das enzimas maduras CAL1, CAL2 e CAL3 com atividade sobre o substrato Z-FR-MCA. O anticorpo policlonal anti-pCAL2 foi produzido em coelho e reconheceu pCAL2 e CAL2 em immunoblots. Experimentos de immunoblots com diferentes tecidos de T. molitor mostraram que o anticorpo policlonal anti-pCAL3 reconheceu pCAL3 e CAL3 nos dois terços anteriores do intestino médio de larvas de T. molitor. Estudos de imunocitolocalização indicam que a catepsina L 3 ocorre em vesículas no intestino médio anterior e em microvilosidades no intestino médio posterior. Para os experimentos de cristalização, nós expressamos pCAL1, pCAL2 e pCAL3 como mutantes Cys25→Ser inativos. pCAL3Cys26Ser foi cristalizada por difusão de vapor (gota sentada) contra 0,1-1,6M de dihidrogênio fosfato de amônio. Os cristais são monoclínicos com grupo espacial C2 e parâmetros de célula: a=57,634 Å, b=89,322 Å, c=70,076 Å, α=γ=90°, β=92,502° e uma molécula na unidade assimétrica. A e strutura foi determinada por substituição molecular usando a estrutura de Fasciola hepatica (42% de identidade) como modelo. O modelo foi refinado a 2,1 Å com fator R final de 16,19% (Rfree=20,5%). pCAL2Cys25Ser foi cristalizada por difusão de vapor (gota sentada) contra acetato de sódio 0,2M, cacodilato de sódio 0,1M pH6,6-6,7 e 20% de PEG 8000. Os cristais são triclínicos com grupo espacial P1 e parâmetros de célula: a=51,669 Å, b=52,37 Å, c=59,716 Å, α= 91,278°, γ=109,586°, β=91,547° e duas moléculas na unidade assimétrica. A estrutura foi determinada por substituição molecular usando a estrutura da pCAL3 (44% de identidade) como modelo. O modelo foi refinado a 2,0 Å com fator R final de 17,61% (Rfree=22,48%). A estrutura terciária da pró-catepsinas L digestivas é muito similar as estruturas de cisteína proteinases da família da papaína / Cathepsin L is a cysteine proteinase of the papain family (clan CA, family C1), which is the most known among the cysteine proteinases. Cathepsin L, like other proteinases of family C1, is synthesized as an inactive proenzyme that is activated by propeptide removal. The propeptide of cathepsin L-like subfamily contain a highly conserved motif, the so called ERFNIN motif. Cathepsin L corresponds to the major digestive proteinase in Tenebrio molitor. In our laboratory, 3 procathepsins L (pCALs) were cloned and sequenced from a cDNA library prepared from T. molitor larval midguts: pCAL1 (lysosomal CAL), pCAL2 and pCAL3 (digestive enzymes). These proteinases have ERFNIN motif and 3 residues directly involved in catalysis: Cys25, His169, Asn175 with Gln19 (papain numbering). In this work we report the cloning into the expression vector and bacterial expression of the sequences coding pCAL1, pCAL2 and pCAL3. The recombinant procathepsins L were purified by affinity chromatography and activation of these enzymes occurs under acidic conditions. The cathepsins L (CAL1, CAL2 and CAL3) were able to hydrolyse Z-FR-MCA. The polyclonal antibody anti-pCAL2 was produced in rabbit and recognized pCAL2 and CAL2 on immunoblots. Immunoblot analyses of different T. molitor larval tissues demonstrated that the polyclonal antibody anti-pCAL3 recognised pCAL3 and CAL3 in the anterior two-thirds of midgut tissue of T. molitor larvae. Immunolocalization studies indicate that cathepsin L 3 occurs in vesicles in the anterior midgut and microvilli in posterior midgut. To crystallographic studies we expressed pCAL1, pCAL2 and pCAL3 as inactive Cys25→Ser mutants. pCAL3Cys26Ser was crystallized by vapor diffusion in sitting drops against 0.1-1.6 M mono-ammonium dihydrogen phosphate. The crystals are monoclinic, belonging to space group C2, with cell parameters: a = 57.634 Å, b = 89.322 Å, c = 70.076 Å, α = γ =90°, β = 92.502° and contain one molecule in the asymmetric unit. The structure was determined by molecular replacement using the structure of Fasciola hepatica procathepsin L (42.5% identity) as a model. The model was refined at 2.1 Å resolution with an R factor of 16.19% (Rfree = 20.5%). pCAL2Cys25Ser was crystallized by vapor diffusion in sitting drops against 0.2M sodium acetate, 0.1M sodium cacodylate pH 6.6-6.7 and 20% polyethylene glycol 8,000. The crystals are triclinic, belonging to space group P1, with cell parameters: a = 51.669 Å, b = 52.37 Å, c = 59.716 Å, α = 91.278° γ = 109.586°, β = 91.547° and contain two molecules in the asymmetric unit. The structure was determined by molecular replacement using the structure of procathepsin L 3 (44 % identity) as a model. The model was refined at 2.0 Å resolution with an R factor of 17.61% (Rfree = 22.48%). The tertiary structure ofdigestive procathepsins L is very similar to papain-like cysteine proteinases structures
8

Estrutura e função das cisteína proteinases intestinais do besouro Tenebrio molitor / Structure and function of intestinais cysteine proteinases of Tenebrio molitor beetle

Daniela Beton 17 December 2009 (has links)
A catepsina L é uma cisteína proteinase da família da papaína (clã CA, família C1), sendo esta família a mais conhecida entre as cisteína proteinase. A catepsina L, como outras proteinases da família C1, é sintetizada como uma pró-enzima inativa que é ativada através da remoção do pró-peptídeo. Os pró-peptídeos das catepsinas da subfamília catepsina L apresentam um motivo consenso, denominado motivo ERFNIN. A catepsina L corresponde a principal proteinase digestiva em Tenebrio molitor. No nosso laboratório 3 pró-catepsinas L (pCALs) foram clonadas e seqüenciadas a partir de uma biblioteca de cDNA de intestino médio de larvas de T. molitor: pCAL1 (CAL lisossomal), pCAL2 e pCAL3 (enzimas digestivas). Estas proteinases apresentam o motivo ERFNIN e os resíduos envolvidos na catálise: Cys25, His169, e Asn175 com Gln19 (numeração da papaína). Neste trabalho descrevemos a clonagem em vetores de expressão e a expressão em bactérias das sequências codificadoras de pCAL1, pCAL2 e pCAL3. As pró-catepsinas L recombinantes foram purificadas por cromatografia de afinidade e a incubação em pH ácido resultou na formação das enzimas maduras CAL1, CAL2 e CAL3 com atividade sobre o substrato Z-FR-MCA. O anticorpo policlonal anti-pCAL2 foi produzido em coelho e reconheceu pCAL2 e CAL2 em immunoblots. Experimentos de immunoblots com diferentes tecidos de T. molitor mostraram que o anticorpo policlonal anti-pCAL3 reconheceu pCAL3 e CAL3 nos dois terços anteriores do intestino médio de larvas de T. molitor. Estudos de imunocitolocalização indicam que a catepsina L 3 ocorre em vesículas no intestino médio anterior e em microvilosidades no intestino médio posterior. Para os experimentos de cristalização, nós expressamos pCAL1, pCAL2 e pCAL3 como mutantes Cys25→Ser inativos. pCAL3Cys26Ser foi cristalizada por difusão de vapor (gota sentada) contra 0,1-1,6M de dihidrogênio fosfato de amônio. Os cristais são monoclínicos com grupo espacial C2 e parâmetros de célula: a=57,634 Å, b=89,322 Å, c=70,076 Å, α=γ=90°, β=92,502° e uma molécula na unidade assimétrica. A e strutura foi determinada por substituição molecular usando a estrutura de Fasciola hepatica (42% de identidade) como modelo. O modelo foi refinado a 2,1 Å com fator R final de 16,19% (Rfree=20,5%). pCAL2Cys25Ser foi cristalizada por difusão de vapor (gota sentada) contra acetato de sódio 0,2M, cacodilato de sódio 0,1M pH6,6-6,7 e 20% de PEG 8000. Os cristais são triclínicos com grupo espacial P1 e parâmetros de célula: a=51,669 Å, b=52,37 Å, c=59,716 Å, α= 91,278°, γ=109,586°, β=91,547° e duas moléculas na unidade assimétrica. A estrutura foi determinada por substituição molecular usando a estrutura da pCAL3 (44% de identidade) como modelo. O modelo foi refinado a 2,0 Å com fator R final de 17,61% (Rfree=22,48%). A estrutura terciária da pró-catepsinas L digestivas é muito similar as estruturas de cisteína proteinases da família da papaína / Cathepsin L is a cysteine proteinase of the papain family (clan CA, family C1), which is the most known among the cysteine proteinases. Cathepsin L, like other proteinases of family C1, is synthesized as an inactive proenzyme that is activated by propeptide removal. The propeptide of cathepsin L-like subfamily contain a highly conserved motif, the so called ERFNIN motif. Cathepsin L corresponds to the major digestive proteinase in Tenebrio molitor. In our laboratory, 3 procathepsins L (pCALs) were cloned and sequenced from a cDNA library prepared from T. molitor larval midguts: pCAL1 (lysosomal CAL), pCAL2 and pCAL3 (digestive enzymes). These proteinases have ERFNIN motif and 3 residues directly involved in catalysis: Cys25, His169, Asn175 with Gln19 (papain numbering). In this work we report the cloning into the expression vector and bacterial expression of the sequences coding pCAL1, pCAL2 and pCAL3. The recombinant procathepsins L were purified by affinity chromatography and activation of these enzymes occurs under acidic conditions. The cathepsins L (CAL1, CAL2 and CAL3) were able to hydrolyse Z-FR-MCA. The polyclonal antibody anti-pCAL2 was produced in rabbit and recognized pCAL2 and CAL2 on immunoblots. Immunoblot analyses of different T. molitor larval tissues demonstrated that the polyclonal antibody anti-pCAL3 recognised pCAL3 and CAL3 in the anterior two-thirds of midgut tissue of T. molitor larvae. Immunolocalization studies indicate that cathepsin L 3 occurs in vesicles in the anterior midgut and microvilli in posterior midgut. To crystallographic studies we expressed pCAL1, pCAL2 and pCAL3 as inactive Cys25→Ser mutants. pCAL3Cys26Ser was crystallized by vapor diffusion in sitting drops against 0.1-1.6 M mono-ammonium dihydrogen phosphate. The crystals are monoclinic, belonging to space group C2, with cell parameters: a = 57.634 Å, b = 89.322 Å, c = 70.076 Å, α = γ =90°, β = 92.502° and contain one molecule in the asymmetric unit. The structure was determined by molecular replacement using the structure of Fasciola hepatica procathepsin L (42.5% identity) as a model. The model was refined at 2.1 Å resolution with an R factor of 16.19% (Rfree = 20.5%). pCAL2Cys25Ser was crystallized by vapor diffusion in sitting drops against 0.2M sodium acetate, 0.1M sodium cacodylate pH 6.6-6.7 and 20% polyethylene glycol 8,000. The crystals are triclinic, belonging to space group P1, with cell parameters: a = 51.669 Å, b = 52.37 Å, c = 59.716 Å, α = 91.278° γ = 109.586°, β = 91.547° and contain two molecules in the asymmetric unit. The structure was determined by molecular replacement using the structure of procathepsin L 3 (44 % identity) as a model. The model was refined at 2.0 Å resolution with an R factor of 17.61% (Rfree = 22.48%). The tertiary structure ofdigestive procathepsins L is very similar to papain-like cysteine proteinases structures
9

Função de subsítios de uma catepsina digestiva de Tenebrio molitor / Subsites role of a Tenebrio molitor digestive cathepsin

Damasceno, Ticiane Fraga 27 May 2014 (has links)
A catepsina L, uma cisteína proteinase da família da papaína, é a principal proteinase digestiva do besouro Tenebrio molitor. Estudos anteriores do nosso grupo mostraram que existem três catepsinas L no intestino médio do T. molitor, uma delas é lisossômica (CAL 1) e as outras duas são digestivas (CAL 2 e CAL 3). As estruturas 3D das enzimas digestivas foram recentemente elucidadas. Com o objetivo de estudar em detalhes as propriedades das enzimas digestivas, CAL 3 foi expressa como um zimógeno em E. coli, purificada por cromatografia de afinidade e autoativada em meio ácido. Foram realizados ensaios de atividade com 63 peptídeos FRET derivados da sequência Abz-KLRSSKQ-EDDnp em um espectrofluorímetro termostatizado a 30 ºC, monitorando-se continuamente a variação de fluorescência em 320 nm (λex) e 420 nm (λem). Os parâmetros kcat e KM obtidos foram utilizados na determinação da hidrofobicidade dos subsítios (H) e da função de cada subsítio através da razão das energias livres de ativação do complexo enzima-substrato (ΔG‡T) e de ligação da enzima com o substrato (ΔGs). Os resultados mostram que o subsítio S2 está envolvido prioritariamente em catálise e é bastante seletivo para substratos com resíduos hidrofóbicos em P2. Esse subsítio é o mais hidrofóbico dentre os analisados, encontrando-se num bolsão localizado no interior da enzima. O subsítio S\'2, por outro lado, é o que apresentou a menor especificidade dentre os analisados. Este subsítio está envolvido prioritariamente na ligação com o substrato e se localiza na superfície da enzima, o que pode facilitar a acomodação de diferentes cadeias laterais em P\'2 do substrato, não oferecendo muitas restrições espaciais. O subsítio S1, hidrofílico, não é muito seletivo, o que pode ser consequência de sua localização na superfície da enzima. Esse subsítio está prioritariamente envolvido na ligação com o substrato. O subsítio S\'1, assim como S1, está localizado na superfície da enzima, é hidrofílico e não muito seletivo. No entanto, esse subsítio tem papel na catálise além de atuar na ligação do substrato. Numa análise inicial da estrutura 3D deste subsítio, sua função catalítica foi atribuída à presença de parte da cavidade oxiânica. Uma enzima com mutação no resíduo W187, pertencente à cavidade oxiânica e a S\'1, foi produzida e purificada, no entanto essa enzima não apresentou atividade. Uma análise mais aprofundada mostrou que a falta de atividade pode ser atribuída ao fato do resíduo de aminoácido mutado fazer parte de um cluster aromático essencial à estabilização da tríade catalítica. Os dados obtidos na caracterização de S\'1 e S\'2 permitem inferir que a acilação é o passo limitante da reação da CAL 3. Além disso, os resultados deste trabalho mostram que o conceito de hidrofobicidade de subsítios proposto anteriormente pelo grupo parece ser aplicável a subsítios que apresentem especificidades mais restritas. / Cathepsin L, a cysteine proteinase of the papain family, is the major digestive proteinase in the beetle Tenebrio molitor. Previous studies of our group showed that there are three cathepsins L in T. molitor midgut, one is lysosomal (CAL1) and two are digestive (CAL2 and CAL3). The 3D structures of the digestive enzymes were recently elucidated. With the aim to study in details the digestive enzymes specificities, CAL3 was expressed in E. coli as a zymogen, purified by affinity chromatography and autoactivated in acid conditions. Activity assays were performed in a thermostated spectrofluorometer at 30 ºC with 63 FRET peptides derived from the lead sequence Abz-KLRSSKQ-EDDnp, continuously monitoring the fluorescence changes at 320 nm (λex) and 420 nm (λem). The parameters kcat and KM were used in the determination of subsite hydrophobicity (H) and subsite role based on the ratio of complex enzyme-substrate activation energy (ΔG‡T) and free energy of substrate binding (ΔGs). The data obtained suggest that the S2 is mainly involved in catalysis and is very selective to substrates with hydrophobic residues in P2. This subsite is the most hydrophobic among the analyzed and is located in a pocket in the enzyme interior. S\'2, on the other hand, is the less selective subsite and is mainly involved in substrate binding and is located on the enzyme surface, what can ease the accommodation of different side chains located in P\'2 by not imposing many spatial restrictions. S1, is hydrophilic and not very selective, what may be a consequence of its location on the enzyme surface. This subsite is mainly involved in substrate binding. S\'1, just like S1, is located on the enzyme surface, is hydrophilic and not very selective. However this subsite has a role in catalysis besides the role in substrate binding. In an initial 3D structure analysis its catalytic function was attributed to the presence of a part of the oxyanion hole. An enzyme with mutation in the residue W187, which apparently belonged both to the oxyanion hole and S\'1, was produced and purified, but this enzyme was inactive. A better analysis showed that the lack of activity can be attributed to the fact that the mutated residue belongs to an aromatic cluster that is essential to the catalytic triad stabilization. The data obtained in S\'1 and S\'2 characterization suggest that acylation is the limiting step in CAL 3 reaction. The results presented in this work support the concept of subsite hydrophobicity previously proposed by our group, which seems to be true to subsites with more restrict specificities
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Ecologie évolutive du priming immunitaire chez le ténébrion meunier, Tenebrio molitor / Evolutionary ecology of immune priming in the mealworm beetle, Tenebrio molitor

Dhinaut, Julien 06 December 2017 (has links)
Il est maintenant connu que de nombreux invertébrés peuvent moduler leur réponse immunitaire en fonction de leur expérience immunologique. Ce phénomène est appelé priming immunitaire. Si les mécanismes du priming immunitaire restent encore assez méconnus, il a pour conséquence d’apporter un bénéfice aux individus lors d’une seconde rencontre avec un agent pathogène, via une élévation de leur immunocompétence. Une caractéristique assez étonnante du priming immunitaire est qu’il peut se manifester chez la descendance. Ce transfert trans-générationnel d’immunité (TTGI), ainsi que le priming immunitaire, doivent avoir évolués à la suite de challenges répétitifs par les mêmes agents pathogènes durant la vie des individus et au fil des générations. Ainsi, le priming et le TTGI doivent être plus efficaces et moins coûteux vis à vis des parasites exposant l’hôte à la plus grande probabilité de réinfection. De plus, il est maintenant prouvé que la réponse immunitaire chez les insectes est génétiquement variable. Pour comprendre l’évolution du TTGI et de son potentiel de réponse à la sélection, il convient d’étudier la composante génétique de sa variabilité. Au cours de cette thèse, j’ai associé l’expression du priming et du TTGI chez un insecte à un type de bactéries, qui a du agir comme la principale pression de sélection sur le système immunitaire de cette espèce hôte. Cela s’est fait via l’identification de différents coûts et bénéfices, qui ont également mis en exergue certains mécanismes possibles dans la réalisation de ces phénomènes immunitaires. Pour ce faire, j’ai utilisé comme organisme modèle le ténébrion meunier, Tenebrio molitor.Dans le premier chapitre, nous avons étudié la survie d’individus adultes de T. molitor face à une infection bactérienne, en fonction de leur propre expérience immunitaire ou de celle de leur mère. Nous avons constaté que le priming et le TTGI étaient plus efficaces et moins coûteux vis à vis des bactéries à Gram-positif. Cetté étude a également révélé que, contrairement à ce que de précédentes recherches suggérent, les hémocytes ne jouent pas nécessairement un rôle majeur dans le priming immunitaire et le TTGI.Dans le deuxième chapitre, nous avons stimulé le système immunitaire de femelles adultes de T. molitor avec deux bactéries Gram-positives. Nous avons mis en évidence que la protection transmise aux oeufs pouvait résulter d’un transfert maternel de peptides antibactérien, ou que ces peptides pouvaient être produits par l’œuf lui-même, en fonction de la bactérie utilisé pour stimuler la mère. Il s’avère que quel que soit le mécanisme, le TTGI améliore le taux d’éclosion des œufs et peut même s’accompagner d’un bénéfice en survie pour les jeunes larves.Dans le troisième chapitre, nous avons stimulé le système immunitaire de femelles de lignées consanguines afin de quantifier la variation génétique de l'investissement maternel à la protection des œufs et mesuré d’autres traits associés à la valeur sélective des mères et de la descendance. Malheureusement, du fait d’un nombre trop faible de lignées et d’individus utilisés au sein de nos lignées, il nous a été impossible de conclure quant à l’existence de bases génétiques associées au TTGI.Dans le quatrième chapitre, nous avons passé en revue l’ensemble des études concernant le TTGI. Cela nous a permis de mettre en exergue les principales caractéristiques et les mécanismes identifiés, en fonction de l’écologie et de l’évolution du phénomène.Les bénéfices et les coûts associés au priming ainsi qu’au TTGI suggèrent que les bactéries à Gram-positif ont été la principale pression de sélection ayant contraint l’évolution du système immunitaire de T. molitor. En ce qui concerne le TTGI, de plus amples recherches sont nécessaires afin de trancher quant à l’existence de bases génétiques associées au phénomène. / Many organisms can improve their immune response as a function of their immunological experience, a phenomenon called immune priming. While the mechanisms through which immune priming is achieved remain unknown, individuals that survived to a given parasite are better protected against subsequent exposures. This immune priming can cross generations (trans-generational immune priming – TGIP), preparing offspring for prevailing parasite environment. Both individual and trans-generational immune priming might be adaptive and may have evolved from repeated challenges by the same pathogens during the host lifetime or across generation. While protection could be cross-reactive, a certain level of specificity may exist in response to the range of pathogens from which immue priming may have evolved. Thus, immune priming and TGIP should be more efficient and less costly with respect to pathogens exposing the host to the greatest probability of re-infection. Moreover, it is now known that insect immune response is genetically variable. To understand the evolution of TGIP and its impact on life history evolution, we need to explore its quantitative genetics. During my thesis, I found that the expression of individual immune priming and TGIP in the mealworm beetle, Tenebrio molitor, is dependent of a range of pathogens that might have been a major selective pressure on the immune system of this insect species. This was done through the characterisation of costs and benefits of the expression of immune priming in response to challenges with a large range of bacterial pathogens. This work also highlighted potential mechanisms through which these immune phenomena could be achieved.In a first chapter of this thesis, we examined the survival of individuals to infection with different bacteria according to their own immunological experience or that of their mother with these bacteria. We found that priming response to Gram-positive bacteria was particularly more efficient and less costly than priming response to Gram-negative bacteria. This study also shows that, contrary to what is currently believed, the cellular component of the T. molitor immune system does not necessarly play a major role in providing immune protection through individual immune priming or TGIP.In a second chapter, we have stimulated the immune system of adult females with two Gram-positive bacteria to study maternal transfer of immunity to the eggs. We found that the process throght which eggs are protected is dependent on the bacterial pathogen used to immune challenge the mother. Indeed, depending of the bacterial pathogen that immune challenged the mother, antibacterial activity in the eggs are either transfeered by the mother or produced by the egg itself, Furthermore, whatever the mechanism through which egg protection was achieved, primed eggs exhibited enhanced hatching rate and the resulting larvae even showed improved early survival to food privation.In a third chapter, we used inbred lines of T. molitor to study the quantitative genetics of TGIP. The aim of this work was to test whether TGIP could be heritable and whether its expression is genetically associated to other fintness traits of mothers and offspring. Unfortunately, due to a low number of inbred lines available and a low number of samples within some of these lines, it was impossible to conclude about the genetic basis associated to TGIP.In a fourth chapter, we produced a review on TGIP. This allowed us to highlight the main characteristics and mechanisms curently identified, and the ecology and the evolution of the phenomenon.Costs and benefits associated to immune priming and TGIP suggest that Gram-positive bacteria might have been a major selective pressure at the origin of these phenomena in T. molitor. Whether TGIP has genetic basis still required further research.

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