Structural Studies on Heat Shock Protein 90 from Dictyostelium Discoideum and Oryza Sativa

Raman, Swetha

January 2014

Molecular chaperones are proteins that interact with and aid in stabilization and activation of other proteins. Chaperones help proteins attain their three dimensional conformation, without forming a part of the final structure. Many of the chaperones are stress proteins known as Heat shock proteins (Hsps). Their expression is upregulated in response to various kinds of stress such as heat stress, oxidative stress etc., which threaten the protein homeostasis, by structurally destabilizing cellular proteins, and increasing the concentration of aggregation-prone folding intermediates. The Hsps are classified according to their molecular weight into Hsp40, Hsp60, Hsp70, Hsp90, Hsp100, and the small Hsp families. Some of them are constitutively expressed and play a fundamental role in de novo protein folding. They further aid in proteome maintenance by assisting in oligomeric assembly, protein trafficking, refolding of stress denatured protein, preventing protein aggregation and protein degradation. Heat shock protein 90 (Hsp90) are one of the important representatives of this class of proteins. Hsp90 are highly conserved class of molecular chaperones. They are found in bacteria, eukaryotes, but not in archaea. In contrast to the eukaryotes which require a functional cytoplasmic Hsp90 for viability, the bacterial counterpart (HtpG) is typically nonessential. Hsp90 is an ATP dependent chaperone. Hsp90 form dimers, with each protomer consisting of three functional domains: N- terminal, ATP binding domain, Middle domain and C-terminal domain. Hsp90 is a dynamic protein, and undergoes an elaborate conformational cycle during its ATPase cycle, which is essential for its chaperoning activity. The Hsp90 chaperone cycle is regulated by interaction with diverse cochaperones. Hsp90 interacts with specific set of substrate proteins. Many of these substrate proteins function at the heart of several cellular processes like signalling, cell cycle, apoptosis. Studies from protozoans like Leishmania, Plasmodium, Trypanosoma etc. have also implicated the role of Hsp90 in their growth and stage transitions. Thus, selective inhibition of Hsp90 has been explored as an intervention strategy against important human diseases such as cancer, malaria and other protozoan diseases. The ATP binding N-terminal domain (NTD), has been explored as the target domain for inhibition of Hsp90 using competitive inhibitors of ATP. Several chemical classes of Hsp90 inhibitors are known, including ansamycins, macrolides, purines, pyrazoles, and coumarin antibiotics. However, many inhibitors are observed to be toxic, less soluble and unstable. Hence, there is a requirement for new approach to design inhibitors which are more soluble and less toxic and serve as effective therapeutic drugs.inhibitors are observed to be toxic, less soluble and unstable. Hence, there is a requirement for new approach to design inhibitors which are more soluble and less toxic and serve as effective therapeutic drugs. The work presented in this thesis mainly concerns with the structural studies and biochemical and biophysical characterization of Hsp90 from two different sources viz. Dictyostelium discoideum, a cellular slime mould and a plant source Oryza sativa (rice). The structural analyses of these two proteins have been carried out by X-ray crystallography. Though yeast has been explored extensively as a model system to understand the different roles of Hsp90, it lacks the various signalling pathways essential for growth and development present in case of higher eukaryotes. D. discoideum has been employed as a model system to understand multicellular development, which occurs in response to starvation induced stress. D. discoideum has the advantages due to its ease of manipulation. The organism's genome also shows many signalling pathway for growth and differentiation that are conserved between D. discoideum and mammals. With this motivation, we have studied several structural aspects of the cytosolic isoform of Hsp90 from D. discoideum called HspD. HspD was also observed to play a role in the multicellular development of D. discoideum. It has been demonstrated that the treatment of D. discoideum with inhibitors like Geldanamycin or Radicicol causes an arrest in the multicellular development at the mound stage, and the few which escaped this arrest gave rise to abnormal fruiting bodies. A subset of the proteins involved in this mound arrest phenotype, were observed to have homologs in humans, which are clients of Hsp90. Therefore, a structural perspective of HspD can aid in better understanding of the role of this protein in the organism, as well as, elucidate any structural differences observed as compared to other species, which may have an impact on its activity. Studies on the physiological role of Hsp90 in plants began much later as compared to fungi and humans. In plants Hsp90 are involved in various abiotic stress responses. In addition, their roles have also been implicated in plant growth and development, innate immune response and buffering genetic variations. However, the molecular mechanisms of these various actions are not clearly understood. Also, the structural aspects of plant Hsp90 are yet to be explored. The structure of the NTD of Hsp90 from barley is the only one available from a plant source till now. We have initiated the studies on rice Hsp90 with the objective to understand the mechanism of Hsp90 in plants, which may aid in improving stress tolerance in plants. The thesis has been divided into five chapters. The first chapter introduces the various aspects of Hsp90 protein. The chapter starts with a general overview of concept of molecular chaperones and describes briefly the different classes of molecular chaperones. This is followed by a detailed description of different aspects of Hsp90 with main emphasis on the structure and its conformational flexibility. The chapter describes the association of Hsp90 with other accessory proteins like cochaperones and its interaction with its substrate proteins and explains the functional significance of Hsp90 as a drug target and the need for the development of new class of inhibitors, followed by the significance of the study of Hsp90 in the two model systems (D. discoideum and rice) chosen to be studied. The second chapter gives a brief overview of the principles behind the different experimental methods employed during the course of this research, which includes the tools of X-ray crystallography and other biochemical and biophysical techniques employed for the characterization of the protein. Chapter 3 describes the crystal structure of NTD of Hsp90 from D. discoideum. The structure of NTD was solved in two different native (ligand-free) forms viz. monoclinic and hexagonal. The two forms differed in local structural rearrangement of a segment of NTD known as the lid region. The lid region in the hexagonal form showed a shift in its position as compared to the other solved structures of NTD. The structure of NTD was also solved in complex with various ligands which include ADP, substrate analogs and an inhibitor molecule. A comparison of all the structures showed that the overall structure is well-conserved. One of the crystal structures of NTD showed a heptapeptide (part of the vector) bound at the active site. The peptide was observed to make several complementary interactions with the residues of the ATP binding pocket and retain several interactions which the nucleotide makes with the NTD. The NTD showed subtle conformational differences when compared with the NTD of Hsp90 from yeast. Chapter 4 details the structural and functional characteristics of full length Hsp90 protein from D. discoideum. Due to the large size and flexibility, the full length protein did not crystallize in spite of several attempts. Hence, HspD was studied using different solution studies like Small Angle X-ray Scattering (SAXS) and Dynamic Light Scattering (DLS). Both the studies showed the presence of higher oligomers. The SAXS data showed the presence of tetramers and hexamers while, the addition of the ligand shifts the protein from a dimer to a higher oligomer as observed from DLS studies. The chapter also describes the study of interaction of HspD with a cochaperone protein p23. The interactions were studied using ITC, which showed a strong binding. The ATPase activity was also evaluated in the presence of increasing concentrations of p23, which was observed to decline with increasing concentrations of p23. In chapter 5, we describe the biochemical characterization of Hsp90 from Oryza sativa (rice) and the crystallographic analysis of its NTD. Binding of the rice Hsp90 to ATP and an inhibitor were studied by fluorescence. The ATPase activity of rice Hsp90 was checked by radioactive assay and the protein was observed to be active. The NTD of rice Hsp90 crystallized as a monomer in complex with a substrate analog AMPPCP and the structure was determined.

Oryza Sativa (Rice) Heat Shock Proteins

Molecular Chaperones

Heat Shock Proteins

Heat Shock Protein 90 (Hsp90)

Chaperone Proteins

Heat Shock Protein D. Discoideum (HspD)

Microbial Heat Shock Proteins

Plant Heat Shock Proteins

Dictyostelium discoideum Hsp90

Oryza sativa Hsp90

Molecular Biophysics

Role of Grp 75 Chaperone Folding Machinery in the Maintenance of Mitochondrial Protien Quality Control

Goswami, Arvind Vittal

January 2013

My research focuses on understanding the importance of human mitochondrial Hsp70 (Grp75) chaperone machinery for the maintenance of protein quality control inside the mitochondrial matrix. The investigations carried out during this study have been addressed towards gaining better insights into the working of Grp75 chaperone folding machinery in association with its diverse set of co-chaperones residing in human mitochondria. Additionally, the research also focuses on explaining the various modes of Grp75 participation leading to multiple disease conditions. The thesis has been divided into the following sections as follows: Chapter I: An introduction to the mitochondrial import machinery and role of mitochondrial Hsp70 chaperone folding machinery for the maintenance of protein quality control: Mitochondrion is an essential organelle present in the eukaryotic cell and requires more than 1500 proteins for its proper functioning. Although, mitochondria harbour their own genome, it encodes for only 13 proteins in humans. The rest of the entire proteome is encoded by the nuclear genome and requires proper targeting of proteins to different compartments of mitochondria. Remarkably, mitochondrial matrix alone requires more than 60% of the proteome for its suitable functioning. Briefly, the mitochondrial matrix destined polypeptide passes through the outer membrane translocon; the ‘TOM’ complex and then enters the TIM23 translocon present in the inner membrane of mitochondria. The complete translocation of the polypeptide into the mitochondrial matrix side requires the assistance of mtHsp70 based motor system present on the matrix side which pulls the polypeptide into the matrix in an ATP-dependent manner and with the assistance of various co-chaperones. Subsequently, the unfolded polypeptide is to be folded back to its native state, which is ensured again by the mtHsp70 based chaperone folding machinery. Importantly, while 20% of mtHsp70 is involved in protein import, 80% of mtHsp70 is dedicated for protein folding. In addition to mtHsp70, the chaperone folding machinery consists of various soluble co-chaperones such as the J-proteins which stimulate the ATP hydrolysis rate of Hsp70. Furthermore, another co-chaperone termed as a nucleotide exchange factor ensures binding of fresh ATP molecule onto Hsp70 ensuring multiple rounds of folding cycles. To understand the relevance of mitochondrial Hsp70 chaperone folding machine in the maintenance of protein quality control, Chapter I of the thesis has been divided into multiple sections as follows: Briefly, the initial portion of Chapter I provide a glimpse of the translocon components present in mitochondria for targeting of proteins to outer membrane, inner membrane and inter-membrane space. Owing to the vast proteome size of the mitochondrial matrix, the following section describes the detailed mechanism and translocation process of the mitochondrial matrix targeted proteins. Additionally, subsequent sections of Chapter I provide a comprehensive description of each of the mtHsp70 chaperone folding components, which maintain the protein quality control in the matrix. The players that constitute the chaperone folding machines are mitochondrial Hsp70, J-proteins, nucleotide exchange factors and the newly discovered human escort protein. Essentially, the section provides information about the cellular distribution, structure and function of each of these players constituting the mtHsp70 chaperone folding machine. Loss of regulation between these players leads to defects in protein folding. Imbalance in protein homeostasis is one of the primary causes for mitochondrial dysfunction leading to various diseases. Importantly, recent literature has highlighted the involvement of mtHsp70 chaperone folding players in Parkinson’s disease (PD), Myelodysplastic syndrome (MDS) and cancer. In accordance, the last section of the Chapter I has been dedicated to describe the basic cell biology and proposed mechanisms for the above diseased states. Interestingly, in comparison to yeast and bacteria, the composition of mtHsp70 chaperone folding machinery in humans is unique and distinctly different. Owing to a lack of information about the functioning of human mitochondrial Hsp70 chaperone folding machinery and with an emphasis on understanding its role in various disease manifestations, the objectives that were laid for my PhD thesis are as follows: 1) Functional in vitro reconstitution of the human Grp75 chaperone folding machinery by purifying all the Grp75 chaperone folding machinery players namely; Grp75 (human mtHsp70), hTid-1L and hTid-1S (J-proteins), GrpEL1 (nucleotide exchange factor) and Human escort protein (Hep). 2) Dissection of the intrinsic biochemical defects associated with the variants of Grp75 reported in Parkinson’s disease (PD). 3) To understand the correlation between elevated levels of Grp75 and its contribution to malignancy. In conclusion, the current study has highlighted some of the key features of human Grp75 chaperone folding machinery and its regulation in the maintenance of human mitochondrial matrix protein quality control, failure of which leads to pathological conditions. Chapter II: Reconstitution of the human Grp75 chaperone folding machinery to understand the functional interplay between the multiple protein components: The mitochondrial Heat shock protein 70 (mtHsp70) machinery components are highly conserved among eukaryotes, including humans. However, the functional properties of human mtHsp70 machinery components have not been characterized among all eukaryotic families. To study the functional interactions, we have reconstituted the components of mtHsp70 chaperone machine (Hsp70/J-protein/GrpE/Hep) and systematically analyzed in vitro conditions for biochemical functions. We observed that the sequence-specific interaction of human mtHsp70 towards mitochondrial client proteins differs significantly from its yeast counterpart Ssc1. Interestingly, the helical lid of human mtHsp70 was found dispensable to the binding of P5-peptide as compared to the other Hsp70’s. We observed that the two human mitochondrial matrix J-protein splice-variants differentially regulate the mtHsp70 chaperone cycle. Strikingly, our results demonstrated that human Hep possesses a unique ability to stimulate the ATPase activity of mtHsp70 as well as to prevent the aggregation of unfolded client proteins similar to J-proteins. We observed that Hep binds with the C-terminus of mtHsp70 in a full-length context, and this interaction is distinctly different from unfolded client-specific or J-protein binding. In addition, we found that the interaction of Hep at the C-terminus of mtHsp70 is regulated by the helical lid region. However, the interaction of Hep at the ATPase domain of the human mtHsp70 is mutually exclusive with J-proteins, thereby promoting a similar conformational change that leads to ATPase stimulation. Moreover, we have also dissected out the inter-domain defective nature associated with the point mutant of Grp75 implicated in Myelodysplastic syndrome thus providing an explanation for the loss of function of Grp75 eventually leading to loss of protein quality control in the diseased state. Chapter III: Enhanced J-protein interaction and compromised protein stability of Grp75 variants leads to mitochondrial dysfunction in Parkinson’s disease: Parkinson’s disease (PD) is the second most prevalent progressive neurological disorder commonly associated with impaired mitochondrial function in dopaminergic neurons. Although familial PD is multi-factorial in nature, a recent proteomic screen involving PD-patients revealed two mitochondrial Hsp70 variants (P509S and R126W) that are implicated in PD-pathogenesis. However, molecular mechanisms underlying how mtHsp70 PD-variants are centrally involved in PD-progression is totally elusive. In this report, we provide mechanistic insights into the mitochondrial dysfunction associated with human mtHsp70 PD-variants. Biochemically, R126W variant showed severely compromised protein stability and was found highly susceptible to aggregation at physiological conditions. Strikingly, on the other hand, P509S variant exhibits significantly enhanced interaction with J-protein co-chaperones involved in folding and import machinery, thus altering the overall regulation of chaperone mediated folding cycle and protein homeostasis. To assess the impact of mtHsp70 PD-mutations at the cellular level, we have developed yeast as a model system by making analogous mutations in Ssc1 ortholog. Interestingly, PD-mutations in yeast (R103W and P486S) exhibit multiple in vivo phenotypes, which are associated with ‘mitochondrial dysfunction’ such as mitochondrial DNA (mtDNA) loss and increased susceptibility to oxidative stress recapitulating the cellular features of dopaminergic neurons similar to those reported in other PD-models. Together, our observations for both the variants strongly indicate a definite involvement of mtHsp70 as a susceptibility factor in Parkinson’s disease. Chapter IV: To understand the correlation between elevated levels of Grp75 and its contribution to malignancy: Multiple studies carried out by various groups have reported the presence of elevated levels of Grp75 in cancer cells. Furthermore, proteomic screens show a positive correlation with the higher levels of Grp75 and the aggressive or metastatic nature of cancer. Importantly, cancer cells also exhibit altered mitochondrial metabolism and are found to be under constant oxidative stress pressure. Moreover, Grp75 actively participates in maintenance of mitochondrial function and as well is reported to interact with many putative oncoproteins. However, there is little information available on the possible role of Grp75 in modulating the cellular niche which might favor towards increased malignant transformation of cells. To identify pathways for explaining the correlation between Grp75 and cancer, our initial attempts have focused on monitoring the multiple cellular changes influenced by elevated levels of Grp75 in a cell line based system. To our surprise, transient transfection of cells with Grp75 led to a tremendous increase in the reactive oxygen species levels. Furthermore, a strong positive correlation between the extent of increased levels of Grp75 and the amount of ROS generated in these cells was established. As expected, increased ROS levels observed in Grp75 overexpressing cells also resulted in reduced cell viability. Notably, mitochondrial superoxide generation was found to be the major source for the observed increment in ROS levels in Grp75 expressing cells. In addition, the localization profile of the exogenously expressed Grp75 protein highlighted the fact that the protein was found to be predominantly targeted to mitochondria. Strikingly, the elevated Grp75 levels led to an increase in mitochondrial mass and also displayed a higher proportion of circular and fragmented mitochondria in these cells. Together, the above preliminary observations hint towards a strong correlation between the levels of Grp75 and its influence on the redox biology of cells providing an additional and a possible explanation of the mode of participation of Grp75 in generation and progression of malignancy.

Mitochondrial Protein

Glucose-regulated Proteins (Grp75)

Heat Shock Proteins (Hsp70)

Multiple Disease Conditions

Human Mitochondrial Proteins

Molecular Chaperones

Protein Folding

Grp75 - Malignancy

Grp75 - Parikinson's Disease

Chaperone Folding Cycle

Mitochondrial Hsp70 (mtHsp70)

J-protein Cochaperone

Biochemistry

Convergent evolution of heat-inducibility during subfunctionalization of the Hsp70 gene family

Krenek, Sascha, Schlegel, Martin, Berendonk, Thomas U.

28 November 2013

Background: Heat-shock proteins of the 70 kDa family (Hsp70s) are essential chaperones required for key cellular functions. In eukaryotes, four subfamilies can be distinguished according to their function and localisation in different cellular compartments: cytosol, endoplasmic reticulum, mitochondria and chloroplasts. Generally, multiple cytosol-type Hsp70s can be found in metazoans that show either constitutive expression and/or stress-inducibility, arguing for the evolution of different tasks and functions. Information about the hsp70 copy number and diversity in microbial eukaryotes is, however, scarce, and detailed knowledge about the differential gene expression in most protists is lacking. Therefore, we have characterised the Hsp70 gene family of Paramecium caudatum to gain insight into the evolution and differential heat stress response of the distinct family members in protists and to investigate the diversification of eukaryotic hsp70s focusing on the evolution of heat-inducibility. Results: Eleven putative hsp70 genes could be detected in P. caudatum comprising homologs of three major Hsp70-subfamilies. Phylogenetic analyses revealed five evolutionarily distinct Hsp70-groups, each with a closer relationship to orthologous sequences of Paramecium tetraurelia than to another P. caudatum Hsp70-group. These highly diverse, paralogous groups resulted from duplications preceding Paramecium speciation, underwent divergent evolution and were subject to purifying selection. Heat-shock treatments were performed to test for differential expression patterns among the five Hsp70-groups as well as for a functional conservation within Paramecium. These treatments induced exceptionally high mRNA up-regulations in one cytosolic group with a low basal expression, indicative for the major heat inducible hsp70s. All other groups showed comparatively high basal expression levels and moderate heat-inducibility, signifying constitutively expressed genes. Comparative EST analyses for P. tetraurelia hsp70s unveiled a corresponding expression pattern, which supports a functionally conserved evolution of the Hsp70 gene family in Paramecium. Conclusions: Our analyses suggest an independent evolution of the heat-inducible cytosol-type hsp70s in Paramecium and in its close relative Tetrahymena, as well as within higher eukaryotes. This result indicates convergent evolution during hsp70 subfunctionalization and implies that heat-inducibility evolved several times during the course of eukaryotic evolution.

info:eu-repo/classification/ddc/570

ddc:570

Estudo da degradação da proteína Tau hiperfosforilada por vias independentes do proteassoma, em modelo experimental de neurodegeneração / Study of hyperphosphorylated Tau protein degradation by proteasome-independent pathways, in an experimental model of neurodegeneration

Farizatto, Karen Lisneiva Garcia

28 April 2014

O desenvolvimento das doenças neurodegenerativas, como a doença de Alzheimer, está associado à presença de agregados proteicos contendo Tau hiperfosforilada (p-Tau). Esta disfunção da Tau leva a prejuízos na homeostase celular. Um mecanismo chave para diminuir e/ou prevenir os danos promovidos pelos agregados contendo Tau seria o estímulo de sua degradação. Neste sentido, a proposta do presente estudo foi analisar a degradação da proteína Tau após aumento da expressão exógena da cochaperona Bag-2, a qual influencia o sistema proteassomal de degradação; bem como avaliar a ativação dos sistemas de degradação, a fim de correlacionar estes sistemas em cultura de células primárias e organotípica do hipocampo de ratos. Os resultados mostraram que a rotenona foi capaz de aumentar os níveis de p-Tau e que a superexpressão de Bag-2, foi eficiente em prevenir e degradar a p-Tau. O mecanismo envolvido neste processo envolve a coordenação dos sistemas proteassomal e lisossomal, já que a Rab7 e a Rab24 (envolvidas na via lisossomal) mostraram-se diminuídas na fase que antecede a agregação proteica, enquanto houve aumento da Rab24 na presença dos agregados proteicos. Com relação ao peptídeo beta amiloide, foi demonstrado tendência de aumento de p-Tau acompanhado de diminuição da atividade proteassomal e lisossomal. O tratamento com PADK (ativador lisossomal) foi capaz de reverter este efeito nestas diferentes condições. A análise da interrelação entre os sistemas mostrou que uma inibição do proteassoma favorece a via lisossomal e que o inverso não se repete. Os resultados sugerem que a modulação das vias de degradação pode ser interessante para o estudo, prevenção e tratamento das doenças neurodegenerativas associadas à agregação de proteínas / Neurodegenerative diseases, such as Alzheimer\'s, are associated to protein inclusions containing hyperphosphorylated Tau (p-Tau). It is well established that Tau dysfunction impairs cell homeostasis. A key mechanism to prevent and/or reduce the damage promoted by aggregates of Tau might be its degradation. In view of this, the aims of the present study are to evaluate p- Tau clearance following exogenous expression of Bag-2, which stimulates proteasome; as well as to analyze the activation of both lysosome and proteasome pathways in order to understand the crosstalk between these two systems in primary and organotypic cultures of rat hippocampus. Results showed that rotenone was able of increasing p-Tau that was prevented and degraded by Bag-2 overexpression. Mechanisms involved in this process involve the coordination of cell degradation systems, depending upon aggregation status, since Rab7 and Rab24 (involved in lysosomal pathway) were decreased before protein aggregation, while Rab24 increased in the presence of protein inclusions. Amyloid-beta peptide also increased p-Tau accompanied by decreased proteasome and lysosome activity. PADK (lysosomal activator) treatment reverted the inhibition promoted by amyloidbeta peptide. Inhibition of proteasome leads to activation of lysosome, but lysosome inhibition does not affect proteasome. Overall, results suggest that targeting degradation pathways might be useful to understand, prevent and treat neurodegenerative diseases associated with protein deposits

Doenças neurodegenerativas

Envelhecimento/efeito de drogas

Hipocampo

Hippocampus, Aging

Lisossomos

Lysosomes

Modelos animais

Models animal

Molecular chaperones

Neurodegenerative diseases

Proteínas Tau

Rab GTP-binding proteins

Ratos endogâmicos Lewis

Ratos Sprague-Dawley

Rats inbreed Lewis

Rats Sprague-Dawley

Rotenona/farmacologia

Rotenone/pharmacology

Tau proteins

Estudo da degradação da proteína Tau hiperfosforilada por vias independentes do proteassoma, em modelo experimental de neurodegeneração / Study of hyperphosphorylated Tau protein degradation by proteasome-independent pathways, in an experimental model of neurodegeneration

Karen Lisneiva Garcia Farizatto

28 April 2014

O desenvolvimento das doenças neurodegenerativas, como a doença de Alzheimer, está associado à presença de agregados proteicos contendo Tau hiperfosforilada (p-Tau). Esta disfunção da Tau leva a prejuízos na homeostase celular. Um mecanismo chave para diminuir e/ou prevenir os danos promovidos pelos agregados contendo Tau seria o estímulo de sua degradação. Neste sentido, a proposta do presente estudo foi analisar a degradação da proteína Tau após aumento da expressão exógena da cochaperona Bag-2, a qual influencia o sistema proteassomal de degradação; bem como avaliar a ativação dos sistemas de degradação, a fim de correlacionar estes sistemas em cultura de células primárias e organotípica do hipocampo de ratos. Os resultados mostraram que a rotenona foi capaz de aumentar os níveis de p-Tau e que a superexpressão de Bag-2, foi eficiente em prevenir e degradar a p-Tau. O mecanismo envolvido neste processo envolve a coordenação dos sistemas proteassomal e lisossomal, já que a Rab7 e a Rab24 (envolvidas na via lisossomal) mostraram-se diminuídas na fase que antecede a agregação proteica, enquanto houve aumento da Rab24 na presença dos agregados proteicos. Com relação ao peptídeo beta amiloide, foi demonstrado tendência de aumento de p-Tau acompanhado de diminuição da atividade proteassomal e lisossomal. O tratamento com PADK (ativador lisossomal) foi capaz de reverter este efeito nestas diferentes condições. A análise da interrelação entre os sistemas mostrou que uma inibição do proteassoma favorece a via lisossomal e que o inverso não se repete. Os resultados sugerem que a modulação das vias de degradação pode ser interessante para o estudo, prevenção e tratamento das doenças neurodegenerativas associadas à agregação de proteínas / Neurodegenerative diseases, such as Alzheimer\'s, are associated to protein inclusions containing hyperphosphorylated Tau (p-Tau). It is well established that Tau dysfunction impairs cell homeostasis. A key mechanism to prevent and/or reduce the damage promoted by aggregates of Tau might be its degradation. In view of this, the aims of the present study are to evaluate p- Tau clearance following exogenous expression of Bag-2, which stimulates proteasome; as well as to analyze the activation of both lysosome and proteasome pathways in order to understand the crosstalk between these two systems in primary and organotypic cultures of rat hippocampus. Results showed that rotenone was able of increasing p-Tau that was prevented and degraded by Bag-2 overexpression. Mechanisms involved in this process involve the coordination of cell degradation systems, depending upon aggregation status, since Rab7 and Rab24 (involved in lysosomal pathway) were decreased before protein aggregation, while Rab24 increased in the presence of protein inclusions. Amyloid-beta peptide also increased p-Tau accompanied by decreased proteasome and lysosome activity. PADK (lysosomal activator) treatment reverted the inhibition promoted by amyloidbeta peptide. Inhibition of proteasome leads to activation of lysosome, but lysosome inhibition does not affect proteasome. Overall, results suggest that targeting degradation pathways might be useful to understand, prevent and treat neurodegenerative diseases associated with protein deposits

Doenças neurodegenerativas

Envelhecimento/efeito de drogas

Hipocampo

Lisossomos

Modelos animais

Proteínas Tau

Ratos endogâmicos Lewis

Ratos Sprague-Dawley

Rotenona/farmacologia

Hippocampus, Aging

Lysosomes

Models animal

Molecular chaperones

Neurodegenerative diseases

Rab GTP-binding proteins

Rats inbreed Lewis

Rats Sprague-Dawley

Rotenone/pharmacology

Tau proteins