Structural studies of the bacteriophage lambda holin and M. tuberculosis secA translocase

Savva, George Christos

15 May 2009

Double stranded DNA bacteriophages achieve release of phage progeny by disrupting the cell envelope of the host cell. This is accomplished by two phage-encoded proteins, the holin and the endolysin. In bacteriophage lambda, the S holin is a small three TMD membrane protein that creates a lesion in the inner membrane of the host at a specific time, programmed in its primary structure. Lesion formation permits the cytoplasmic endolysin R access to the murein cell wall for degradation and cell lysis. Although it has been shown that S oligomerizes in the membrane, the structural nature of this complex has not been elucidated. In this study the S holin was purified using a mild non-ionic detergent and the structure of a ring complex formed by the holin was determined by electron microscopy and single particle analysis at a resolution of 2.6 nm. Biochemical characterization of the rings suggests that such a complex might represent the assembly formed by S in the membrane. Protein translocation in all organisms allows the export of proteins destined for localization outside the cytoplasm. In eubacteria, newly synthesized proteins are directed to the heterotrimeric membrane complex SecYEG by signals embedded in their sequence. The driving force through this complex is provided by the cytoplasmic ATPase SecA which combines ATP hydrolysis to mechanically insert proteins through the protein conducting channel. Using electron microscopy and single particle analysis we have obtained the structure of SecA from M. tuberculosis. The structure indicates that four SecA monomers assemble to form an elongated molecule with D2 symmetry. Docking of the EM map to the crystal structure of tb SecA confirms this arrangement of the subunits. This finding, that M. tuberculosis SecA forms a tetramer raises intriguing possibilities about SecA function.

holin

secA

electron microscopy

single particle analysis

Structural studies of the bacteriophage lambda holin and M. tuberculosis secA translocase

Savva, George Christos

15 May 2009

Double stranded DNA bacteriophages achieve release of phage progeny by disrupting the cell envelope of the host cell. This is accomplished by two phage-encoded proteins, the holin and the endolysin. In bacteriophage lambda, the S holin is a small three TMD membrane protein that creates a lesion in the inner membrane of the host at a specific time, programmed in its primary structure. Lesion formation permits the cytoplasmic endolysin R access to the murein cell wall for degradation and cell lysis. Although it has been shown that S oligomerizes in the membrane, the structural nature of this complex has not been elucidated. In this study the S holin was purified using a mild non-ionic detergent and the structure of a ring complex formed by the holin was determined by electron microscopy and single particle analysis at a resolution of 2.6 nm. Biochemical characterization of the rings suggests that such a complex might represent the assembly formed by S in the membrane. Protein translocation in all organisms allows the export of proteins destined for localization outside the cytoplasm. In eubacteria, newly synthesized proteins are directed to the heterotrimeric membrane complex SecYEG by signals embedded in their sequence. The driving force through this complex is provided by the cytoplasmic ATPase SecA which combines ATP hydrolysis to mechanically insert proteins through the protein conducting channel. Using electron microscopy and single particle analysis we have obtained the structure of SecA from M. tuberculosis. The structure indicates that four SecA monomers assemble to form an elongated molecule with D2 symmetry. Docking of the EM map to the crystal structure of tb SecA confirms this arrangement of the subunits. This finding, that M. tuberculosis SecA forms a tetramer raises intriguing possibilities about SecA function.

holin

secA

electron microscopy

single particle analysis

Structural Analysis of Arabidopsis thaliana CDC48A ATPase using Single Particle Cryo-Electron Microscopy

Aldakheel, Lila A.

05 1900

Cdc48A and its human homologue P97 are from ATPase family, which play a variety of roles in cellular activates and it has a crucial involvement in protein quality control pathways. It is best known for its involvement in endoplasmic reticulum associated protein degradation (ERAD), where it mediates the degradation of the aggerated or misfolded proteins by the proteasome. Considering the multiple functions of Cdc48A in many protein regulatory processes, it is a potential therapeutic target for neurogenerative diseases and cancer. Cdc48A polypeptide comprises N domain, followed by D1 and D2 domains respectively that are joined by linkers, whereas functionally it forms a homo hexameric complex. Since Cdc48A is from the ATPase family, it uses the ATP hydrolysis to generate a mechanical force with its co-factors to perform its functions. There are many cofactors that interact with Cdc48A and two of them are Ufd1-NpI4 which in turn interact with ubiquitinated proteins from the ER membrane. The mechanism linking the conversion of the energy of ATP hydrolysis into mechanical force and unfolding the substrate is vague. My aim is to reconstruct a first 3D- model of plant Cdc48A using single particle cryo-EM, which serves the basis to conduct more detailed mechanistic studies towards substrate unfolding and threading/unfolding in the future. In general, results showed one defined structure of cdc48A at ~ 9.8 Å, which is the ADP-ATP conformation. Although another other structure was also resolved at ~ 8.9 Å, it was hard to characterize due to its dissimilarity with known structures of Cdc48A homologues and thus requires further characterization.

cryo-EM

CDC48A

P97

single particle analysis

Structural biology of Cystic Fibrosis Transmembrane Conductance Regulator, an ATP-binding cassette protein of medical importance

Alzahrani, Ateeq Ahmed Hassan

January 2012

The cystic fibrosis transmembrane conductance regulator (CFTR) is a transmembrane protein that functions as an ion channel. Mutations in this protein cause Cystic Fibrosis. For this reason, it is important to study the structure and function of CFTR. In this study, constructs of CFTR (C-terminii), a CFTR-interacting protein and full-length CFTR were cloned, expressed and purified for structural and functional studies. The purified C-terminal polypeptides of CFTR were soluble and shown to interact with NHERF1 PDZ 1 (a CFTR-interacting protein). The CFTR C-terminus and NHERF1 PDZ 1 domain were co-expressed and co-purified. The purified complex showed a strong interaction that might induces a conformational change. Site-directed mutation of the C-terminus of CFTR was performed in order to examine the effect of removing a potentially flexible amino acid (Arginine) on protein crystallization. Pull-down assay experiments with full-length CFTR demonstrated an interaction between CFTR (in DDM detergent) and NHERF1 PDZ 1(+). No interaction was observed for CFTR in LPG (a relatively denaturing detergent) and NHERF1, implying that the interaction between the PDZ motive of CFTR and NHERF1 requires a stable folded structure for both proteins. In addition, full-length CFTR in DDM has been studied by electron microscopy and Single Particle Analysis in the presence of NHERF1 PDZ 1(+). A 3D structure was generated for the CFTR-NHERF1 PDZ 1(+) complex at a resolution of ~ 18 A. This 3D structure showed a new open conformation of CFTR (V shape). In comparable studies with CFTR alone, a 3D structure was generated at a resolution of 27 A and this structure showed a closed state as previously reported. This new data suggest a possible role for NHERF1 in terms of CFTR channel gating or activation.

616.3

Evaluation of negative stains for single particle analysis in electron microscopy

ĎURINOVÁ, Eva

January 2018

Four negative stains, hafnium chloride and europium, samarium and gadolinium nitrates, were tested in single particle electron microscopy as potential alternatives to uranyl acetate, which is recently being widely restricted for its toxicity. The new stains were applied to a structurally well-described plant photosystem I, visualized by a transmission electron microscope and classified in a single particle analysis. The quality of the stains was evaluated by the obtained resolution and ability to provide reliable structural information.

Structural studies of microbubbles and molecular chaperones using transmission electron microscopy

Härmark, Johan

January 2016

Ultrasound contrast agents (CAs) are typically used in clinic for perfusion studies (blood flow through a specific region) and border delineating (differentiate borders between tissue structures) during cardiac imaging. The CAs used during ultrasound imaging usually consist of gas filled microbubbles (MBs) (diameter 1-5 μm) that are injected intravenously into the circulatory system. This thesis partially involves a novel polymer-shelled ultrasound CA that consists of air filled MBs stabilized by a polyvinyl alcohol (PVA) shell. These MBs could be coupled with superparamagnetic iron oxide nanoparticles (SPIONs) in order to serve as a combined CA for ultrasound and magnetic resonance imaging. The first three papers (Paper A-C) in this thesis investigate the structural characteristic and the elimination process of the CA. In Paper A, two types (PVA Type A and PVA Type B) of the novel CA were analyzed using transmission electron microscopy (TEM) images of thin sectioned MBs. The images demonstrated that the SPIONs were either attached to the PVA shell surface (PVA Type A) or embedded in the shell (PVA Type B). The average shell thickness of the MBs was determined in Paper B by introducing a model that calculated the shell thickness from TEM images of cross-sectioned MBs. The shell thickness of PVA Type A was determined to 651 nm, whereas the shell thickness of PVA Type B was calculated to 637 nm. In Paper C, a prolonged blood elimination time was obtained for PVA-shelled MBs compared to the lipid-shelled CA SonoVue used in clinic. In addition, TEM analyzed tissue sections showed that the PVA-shelled MBs were recognized by the macrophage system. However, structurally intact MBs were still found in the circulation 24 h post injection. These studies illustrate that the PVA-shelled MBs are stable and offer large chemical variability, which make them suitable as CA for multimodal imaging. This thesis also involves studies (Paper D-E) of the molecular chaperones (Hsp21 and DNAJB6). The small heat shock protein Hsp21 effectively protects other proteins from unfolding and aggregation during stress. This chaperone ability requires oligomerization of the protein. In Paper D, cryo-electron microscopy together with complementary structural methods, obtained a structure model which showed that the Hsp21 dodecamer (12-mer) is kept together by paired C-terminal interactions.The human protein DNAJB6 functions as a very efficient suppressor of polyglutamine (polyQ) and amyloid-β42 (Aβ42) aggregation. Aggregation of these peptides are associated with development of Huntington’s (polyQ) and Alzheimer’s (Aβ42) disease. In Paper E, a reconstructed map of this highly dynamic protein is presented, showing an oligomer with two-fold symmetry, indicating that the oligomers are assembled by two subunits. / <p>QC 20160527</p>

Transmission electron microscopy

Contrast agent

Microbubble

Polyvinyl alcohol

Single particle analysis

Heat shock protein

Molecular chaperone

Automontagem de filamentos de septinas estudada por microscopia eletrônica / Self-assembling of septine filaments studied by electron microscopy

Mendonça, Déborah Cezar

06 March 2018

Septinas são GTPases consideradas como um novo componente do citoesqueleto. Essas proteínas interagem entre si para formar heterocomplexos filamentosos e estruturas de alta ordem que são importantes para a citocinese e uma variedade de outros processos celulares. Existem muitos aspectos mecânicos dessas proteínas que não são totalmente compreendidos, incluindo a forma como os heterocomplexos se agrupam corretamente. Em humanos, há 13 genes que codificam septinas, classificadas em quatro grupos quanto à similaridade em relação à estrutura primária. O complexo hexamérico SEPT7-SEPT6-SEPT2-SEPT2-SEPT6-SEPT7 foi o melhor caracterizado, com uma estrutura cristalina resolvida à 4 &Aring;. Segundo às Regras de Kinoshita, as septinas desse complexo podem ser substituídas nesse arranjo por outras pertencentes ao mesmo grupo. Neste trabalho utilizamos a técnica de microscopia eletrônica de transmissão com análise de partícula única para estudar dois complexos de septinas. Um dos complexos estudados neste projeto é formado por septinas humanas, para as quais atualmente não há informações estruturais disponíveis. O complexo SEPT5-SEPT6-SEPT7 foi expresso heterólogamente em E. coli e purificado em alta concentração salina para evitar a polimerização. A análise de partículas únicas de imagens por contrastação negativa mostrou a presença de partículas alongadas de aproximadamente 25 nm de comprimento, compostos por seis monômeros, como esperado. Com o objetivo de localizar a posição da SEPT5 no complexo, foi realizada uma fusão com MBP (Maltose Binding Protein) e imunomarcação com anticorpo monoclonal anti-SEPT5, concluindo que a SEPT5 está localizada na extremidade do complexo hexamérico. Porém, a SEPT5 pertence ao mesmo grupo da SEPT2, que foi relatada estar localizada no centro do hexâmero. Este resultado possibilitou uma nova discussão sobre a maneira que as septinas formam os complexos e, como a sensibilidade à concentração salina está relacionada com a fragilidade da interface NC, análogo ao observado em complexos de Saccharomyces cerevisiae. Um complexo de Ciona intestinalis incluindo a SEPT2, SEPT6, SEPT7 e SEPT9, também expresso heterólogamente em E. coli, foi preparado por contrastação negativa. A análise de partícula única das imagens coletadas mostrou um heterocomplexo aparentemente hexamérico, embora fosse esperado um octâmero devido à presença das quatro septinas diferentes, sendo uma pertencente à cada um dos quatro grupos. Os resultados deste trabalho proporcionaram um avanço na compreensão da formação de heterocomplexos de septinas e como essas proteínas interagem umas com as outras nesta montagem. / Septins are GTPases that appear to be a novel component of the cytoskeleton. These proteins interact with each other to form filamentous heterocomplexes and high order structures which are important for cytokinesis and a variety of other cellular processes. There are many mechanistic aspects of these proteins that are not fully understood, including how the heterocomplexes correctly assemble. In humans, there are 13 genes encoding septins, classified in four groups based on primary structure. The SEPT7-SEPT6-SEPT2-SEPT2-SEPT6-SEPT7 hexameric complex was the best characterized, with a crystalline structure solved at 4 &Aring;. According to Kinoshita´s Rules, the septins of this complex can be replaced in this arrangement by others belonging to the same group. In this work, we used transmission electron microscopy with single particle analysis to study two septin complexes. One of the complexes studied in this project is composed of three human septins, for which there is currently no structural information available. The SEPT5-SEPT6-SEPT7 complex was heterologously expressed in E. coli and purified at high salt concentration to avoid polymerization. Single particle analysis of negatively stained samples showed the presence of elongated particles of approximately 25 nm in length. To locate SEPT5 in the complex, a fusion with MBP (Maltose Binding Protein) and immunoblotting with anti-SEPT5 monoclonal antibody was performed, concluding that SEPT5 is located at the end of the hexameric complex. However, SEPT5 belongs to the same group as SEPT2, which was reported to be located in the center of the hexamer. This result allowed for a new discussion on the way that septins form heterocomplexes and also, on how the sensitivity of the NC interface in related to salt concentration, analogous to that observed in the heterocomplex of Saccharomyces cerevisiae. A Ciona intestinalis complex including SEPT2, SEPT6, SEPT7 and SEPT9, also expressed heterologously in E. coli, was prepared by negative staining. The single particle analysis of the collected images showed an apparently hexameric heterocomplex, although an octamer was expected due to the presence of the four different septins, one belonging to each of the four groups. The results of this work represent advances in the understanding of the formation of septin heterocomplexes and how these proteins interact with each other during assembly.

Análise de partícula única

Microscopia eletrônica de transmissão

Septinas

Septins

Single particle analysis

Transmission electron microscopy

Automontagem de filamentos de septinas estudada por microscopia eletrônica / Self-assembling of septine filaments studied by electron microscopy

Déborah Cezar Mendonça

06 March 2018

Septinas são GTPases consideradas como um novo componente do citoesqueleto. Essas proteínas interagem entre si para formar heterocomplexos filamentosos e estruturas de alta ordem que são importantes para a citocinese e uma variedade de outros processos celulares. Existem muitos aspectos mecânicos dessas proteínas que não são totalmente compreendidos, incluindo a forma como os heterocomplexos se agrupam corretamente. Em humanos, há 13 genes que codificam septinas, classificadas em quatro grupos quanto à similaridade em relação à estrutura primária. O complexo hexamérico SEPT7-SEPT6-SEPT2-SEPT2-SEPT6-SEPT7 foi o melhor caracterizado, com uma estrutura cristalina resolvida à 4 &Aring;. Segundo às Regras de Kinoshita, as septinas desse complexo podem ser substituídas nesse arranjo por outras pertencentes ao mesmo grupo. Neste trabalho utilizamos a técnica de microscopia eletrônica de transmissão com análise de partícula única para estudar dois complexos de septinas. Um dos complexos estudados neste projeto é formado por septinas humanas, para as quais atualmente não há informações estruturais disponíveis. O complexo SEPT5-SEPT6-SEPT7 foi expresso heterólogamente em E. coli e purificado em alta concentração salina para evitar a polimerização. A análise de partículas únicas de imagens por contrastação negativa mostrou a presença de partículas alongadas de aproximadamente 25 nm de comprimento, compostos por seis monômeros, como esperado. Com o objetivo de localizar a posição da SEPT5 no complexo, foi realizada uma fusão com MBP (Maltose Binding Protein) e imunomarcação com anticorpo monoclonal anti-SEPT5, concluindo que a SEPT5 está localizada na extremidade do complexo hexamérico. Porém, a SEPT5 pertence ao mesmo grupo da SEPT2, que foi relatada estar localizada no centro do hexâmero. Este resultado possibilitou uma nova discussão sobre a maneira que as septinas formam os complexos e, como a sensibilidade à concentração salina está relacionada com a fragilidade da interface NC, análogo ao observado em complexos de Saccharomyces cerevisiae. Um complexo de Ciona intestinalis incluindo a SEPT2, SEPT6, SEPT7 e SEPT9, também expresso heterólogamente em E. coli, foi preparado por contrastação negativa. A análise de partícula única das imagens coletadas mostrou um heterocomplexo aparentemente hexamérico, embora fosse esperado um octâmero devido à presença das quatro septinas diferentes, sendo uma pertencente à cada um dos quatro grupos. Os resultados deste trabalho proporcionaram um avanço na compreensão da formação de heterocomplexos de septinas e como essas proteínas interagem umas com as outras nesta montagem. / Septins are GTPases that appear to be a novel component of the cytoskeleton. These proteins interact with each other to form filamentous heterocomplexes and high order structures which are important for cytokinesis and a variety of other cellular processes. There are many mechanistic aspects of these proteins that are not fully understood, including how the heterocomplexes correctly assemble. In humans, there are 13 genes encoding septins, classified in four groups based on primary structure. The SEPT7-SEPT6-SEPT2-SEPT2-SEPT6-SEPT7 hexameric complex was the best characterized, with a crystalline structure solved at 4 &Aring;. According to Kinoshita´s Rules, the septins of this complex can be replaced in this arrangement by others belonging to the same group. In this work, we used transmission electron microscopy with single particle analysis to study two septin complexes. One of the complexes studied in this project is composed of three human septins, for which there is currently no structural information available. The SEPT5-SEPT6-SEPT7 complex was heterologously expressed in E. coli and purified at high salt concentration to avoid polymerization. Single particle analysis of negatively stained samples showed the presence of elongated particles of approximately 25 nm in length. To locate SEPT5 in the complex, a fusion with MBP (Maltose Binding Protein) and immunoblotting with anti-SEPT5 monoclonal antibody was performed, concluding that SEPT5 is located at the end of the hexameric complex. However, SEPT5 belongs to the same group as SEPT2, which was reported to be located in the center of the hexamer. This result allowed for a new discussion on the way that septins form heterocomplexes and also, on how the sensitivity of the NC interface in related to salt concentration, analogous to that observed in the heterocomplex of Saccharomyces cerevisiae. A Ciona intestinalis complex including SEPT2, SEPT6, SEPT7 and SEPT9, also expressed heterologously in E. coli, was prepared by negative staining. The single particle analysis of the collected images showed an apparently hexameric heterocomplex, although an octamer was expected due to the presence of the four different septins, one belonging to each of the four groups. The results of this work represent advances in the understanding of the formation of septin heterocomplexes and how these proteins interact with each other during assembly.

Análise de partícula única

Microscopia eletrônica de transmissão

Septinas

Septins

Single particle analysis

Transmission electron microscopy

3D rekonstrukce makromolekulárních komplexů pomocí kryoelektronové mikroskopie / 3D reconstruction of macromolecular complexes by cryoelectron microscopy

Skoupý, Radim

January 2016

Semester project deals with the processing of data from TEM and their analysis (to- mography, single particle analysis). The main aim of this work is to determine the 3D structure of the studied enzyme. As a test sample with low symmetry is used restriction endonuclease EcoR124I.

Regularizační metody pro řešení diskrétních inverzních problémů v single particle analýze / Regularization methods for discrete inverse problems in single particle analysis

Havelková, Eva

January 2019

The aim of this thesis is to investigate applicability of regulariza- tion by Krylov subspace methods to discrete inverse problems arising in single particle analysis (SPA). We start with a smooth model formulation and describe its discretization, yielding an ill-posed inverse problem Ax ≈ b, where A is a lin- ear operator and b represents the measured noisy data. We provide theoretical background and overview of selected methods for the solution of general linear inverse problems. Then we focus on specific properties of inverse problems from SPA, and provide experimental analysis based on synthetically generated SPA datasets (experiments are performed in the Matlab enviroment). Turning to the solution of our inverse problem, we investigate in particular an approach based on iterative Hybrid LSQR with inner Tikhonov regularization. A reliable stopping criterion for the iterative part as well as parameter-choice method for the inner regularization are discussed. Providing a complete implementation of the proposed solver (in Matlab and in C++), its performance is evaluated on various SPA model datasets, considering high levels of noise and realistic distri- bution of orientations of scanning angles. Comparison to other regularization methods, including the ART method traditionally used in SPA,...