Inhibitors of SecA as Potential Antimicrobial Agents

Chaudhary, Arpana S

02 August 2013

Protein translocation is essential for bacterial survival and the most important translocation mechanism in bacteria is the secretion (Sec) pathway. Thus targeting Sec pathway is a promising strategy for developing novel antibacterial therapeutics. We report the design, syntheses, mechanistic studies and structure-activity relationship studies using HQSAR and 3-D QSAR Topomer CoMFA analyses of 4-oxo-5-cyano thiouracil derivatives. In summary, introduction of polar group such as –N3 and linker groups such as –CH2-O- enhanced the potency as well as logP and logS several fold. We also report the discovery, optimization and structure-activity relationship study of 1,2,4-triazole containing pyrimidines as novel, highly potent antimicrobial agents. A number of inhibitors have been found to inhibit microbial growth at high nanomolar concentrations.

SecA inhibitors

Sec pathway inhibition

Thiouracil

1

2

4-Triazole

Novel antibacterial therapeutics

Protein translocation inhibition

Reconstitution of retrotranslocation by the Hrd1 ubiquitin ligase with purified components

Vasic, Vedran

27 June 2019

No description available.

572

Protein quality control

Endoplasmic reticulum

Ubiquitination

Protein translocation

ERAD

Membrane proteins

Protein folding

Biologie (PPN619462639)

Translokace proteinů do hydrogenosomů "Trichomonas vaginalis" / Protein translocation into hydrogenosomes of "Trichomonas vaginalis"

Radhakrishna Makki, Abhijith

January 2019

Mitochondria carry out several important functions in eukaryotic cells such as energy metabolism, iron-sulfur cluster assembly, apoptosis, signaling pathways, protein quality control etc. Most mitochondrial proteins are synthesized on the cytosolic ribosomes and transported to the organelles by the cytosolic chaperones and mitochondrial protein import machinery based on specific targeting signals. Although, the basic principles of protein import have been explained, many questions remain unanswered, particularly for highly modified mitochondria such as hydrogenosomes. The aim of the study was to investigate protein translocation into hydrogenosomes of a human parasite, Trichomonas vaginalis (Tv) with a focus on the composition, function and structure of protein translocases and the role of targeting signals. The translocase of the outer membrane (TOM) is responsible for the import of most proteins into the organelle. Even though, the presence of a TOM complex in trichomonad hydrogenosomes was predicted, its components were not known. Moreover, the generic structure of the mitochondrial TOM complex was not resolved. This study showed that the TvTOM complex is highly divergent consisting of two modified core subunits - channel- forming TvTom40 isoforms and a Tom22-like protein, and two...

Underline Mechanisms of Remodeling Diverse Topological Substrate Proteins through Bacterial Clp ATPase using Computer Simulations

Fonseka, Hewafonsekage Yasan Yures

January 2021

No description available.

Biophysics

Protein unfolding

protein translocation

knotted proteins

non-native contacts

force directionality

Protein degradation

Mechanism of Substrate Protein Remodeling by Allosteric Motions of AAA+ Nanomachines

Tonddast-Navaei, Sam, M.S.

17 February 2014

No description available.

Physical Chemistry

Protein unfolding

Protein translocation

Protein degradation

ATPase

p97

Molecular Dynamics

Microfluidic Engineering for Ultrasensitive Molecular Analysis of cells

Cao, Zhenning

05 October 2015

The main focus of this research was the development of microfluidic technology for ultrasensitive and fast molecular analysis of cells. Chromatin immunoprecipitation (ChIP) assay followed by next generation sequencing serves as the primary technique to characterize the genomic locations associated with histone modifications. However, conventional ChIP-seq assay requires large numbers of cells. We demonstrate a novel microfluidics-based ChIP-seq assay which dramatically reduced the required cell number. Coupled with next generation sequencing, the assay permitted the analysis of histone modifications at the whole genome from as few as ~100 cells. Using the same device, we demonstrated that MeDIP-seq with tiny amount of DNA (<5ng) generated high quality genome-wide profiles of DNA methylation. Off-chip sonication often leads to sample loss due to multiple tube transferring. In addition, conventional sonicators are not able to manipulate samples with small volume. We developed a novel microfluidic sonicator, which is able to achieve on-chip DNA/chromatin shearing into ideal fragment size (100~600bp) for both chromatin immunoprecipitation (ChIP) and methylated DNA immunoprecipitation (MeDIP). The integrated on-chip sonication followed by immunoprecipitation (IP) reaction can significantly reduce sample loss and contamination. Simple and accessible detection methods that can rapidly screen a large cell population with single cell resolution have been seriously lacking. We demonstrate a simple protocol for detecting translocation of native proteins using a common flow cytometer which detects fluorescence intensity without imaging. Using our approach, we successfully detected the translocation of native NF-kappa B (an important transcription factor) at its native expression level and examine the temporal dynamics in the process. Droplets with encapsulated beads and cells have been increasingly used for studying molecular and cellular biology. However, a mixed population of droplets with an uneven number or type of encapsulated particles is resulted and used for screening. We developed a fluorescence-activated microfluidic droplet sorter that integrated a simple deflection mechanism. By passing droplets through a narrow interrogation channel, the encapsulated particles were detected individually. The microcontroller conducted the computation to determine the number and type of encapsulated particles in each droplet and made the sorting decision. Our results showed high efficiency and accuracy for sorting and enrichment. / Ph. D.

chromatin immunoprecipitation(ChIP)

next generation sequencing

microfluidics

droplet sorting

protein translocation

sonication

Analysis of the interplay of protein biogenesis factors at the ribosome exit site reveals new role for NAC

Nyathi, Yvonne, Pool, M.R.

10 June 2020

Yes / The ribosome exit site is a focal point for the interaction of protein-biogenesis factors that guide the fate of nascent polypeptides. These factors include chaperones such as NAC, N-terminal-modifying enzymes like Methionine aminopeptidase (MetAP), and the signal recognition particle (SRP), which targets secretory and membrane proteins to the ER. These factors potentially compete with one another in the short time-window when the nascent chain first emerges at the exit site, suggesting a need for regulation. Here, we show that MetAP contacts the ribosome at the universal adaptor site where it is adjacent to the α subunit of NAC. SRP is also known to contact the ribosome at this site. In the absence of NAC, MetAP and SRP antagonize each other, indicating a novel role for NAC in regulating the access of MetAP and SRP to the ribosome. NAC also functions in SRP-dependent targeting and helps to protect substrates from aggregation before translocation. / This work was supported by grants from the BBSRC [H007202/1] and Wellcome Trust [097820/Z/11/A].

Protein biogenesis

Protein targeting

Protein translocation

Ribosome

Signal recognition particle

NAC

Deciphering the Mechanism of E. coli tat Protien Transport: Kinetic Substeps and Cargo Properties

Whitaker, Neal William 1982-

14 March 2013

The Escherichia coli twin-arginine translocation (Tat) system transports fully folded and assembled proteins across the inner membrane into the periplasmic space. The E. coli Tat machinery minimally consists of three integral membrane proteins: TatA, TatB and TatC. A popular model of Tat translocation is that cargo first interacts with a substrate binding complex composed of TatB and TatC and then is transported across the inner membrane through a channel comprised primarily of TatA. The most common method for observing the kinetics of Tat transport, a protease protection assay, lacks the ability to distinguish between individual transport sub-steps and is limited by the inability to observe translocation in real-time. Therefore, a real-time FRET based assay was developed to observe interactions between the cargo protein pre-SufI, and its initial binding site, the TatBC complex. The cargo was found to first associate with the TatBC complex, and then, in the presence of a membrane potential (∆psi), migrate away from the initial binding site after a 20-45 second delay. Since cargo migration away from the TatBC complex was not directly promoted by the presence of a ∆psi, the delay likely represents some preparatory step that results in a transport competent translocon. In addition, the Tat system has long been identified as a potential biotechnological tool for protein production. However, much is still unknown about which cargos are suitable for transport by the Tat system. To probe the Tat system’s ability to transport substrates of different sizes and shapes, 18 different cargos were generated using the natural Tat substrate pre-SufI as a base. Transport efficiencies for these cargos indicate that not only is the Tat machinery’s ability to transport substrates determined by the protein’s molecular weight, as well as by its dimensions. In total, these results suggest a dynamic translocon that undergoes functionally significant, ∆psi-dependent changes during translocation. Moreover, not every protein cargo can be directed through the Tat translocon by a Tat signal peptide, and this selectivity is not only related to the overall size of the protein, but also dependent on shape.

Protein Translocation

Protein Targeting

Protein Secretion

Protein Export

Membrane Proteins

Intracellular Trafficking

Escherichia coli

Investigation of a Plant Mitochondrial Tat System

Eudy, Kathryn E.

18 November 2021

No description available.

Biochemistry

Cryo-microscopie électronique des complexes de l'adressage et de la translocation co-traductionnelle chez E. coli / Electron cryo-microscopy of complexes in E. coli co-translational targeting and translocation

Jiang, Qiyang

18 June 2015

La membrane cellulaire est la barrière qui sépare l'intérieur des cellules de l'environnement extérieur. Elle se compose de lipides et de protéines. Les gènes codant pour les protéines membranaires représentent environ 30% des génomes. Les protéines membranaires sont synthétisées dans le cytosol par les ribosomes, mais suivent des voies spécifiques pour s'intégrer dans la membrane cellulaire. Les ribosomes en cours de traduction de protéines membranaires sont reconnus dans le cytosol et adressés à la membrane. Par la suite, les chaînes naissantes de protéines membranaires sont insérées dans la bicouche lipidique puis repliées de façons appropriées, ce mécanisme s'appelle la translocation. Le processus d'adressage est médiée par la particule de reconnaissance du signal (SRP) et son récepteur, tandis que la translocation est effectuée par un certain nombre de complexes de protéines membranaires.Cette thèse décrit deux des complexes impliqués dans cet adressage et translocation co-traductionnelle chez Escherichia coli : Le complexe ribosome-SRP-FtsY pour l'adressage en conformation «fermé» et le complexe dans lequel le ribosome est lié à l'holo-translocon (HTL) qui se compose de sept protéines membranaires. J'ai utilisé principalement la cryo-microscopie électronique pour caractériser ces complexes. La cryo-EM permet de déterminer la structure des échantillons biologiques à une résolution supérieure au nanomètre dans leur environnement natif, sans avoir à le cristalliser. Dans ce travail, j'ai bénéficié des améliorations récentes dans l'équipementet le traitement d'image.A partir d'un ensemble de données de cryo-EM obtenu par les membres du groupe, j‘ai déterminé la structure du complexe ribosome-SRP-FtsY en conformation «fermé» avec une résolution de 5.7 Å. Différentes stratégies de tri des calculsont été appliquées pour identifier la partie la plus homogène de l'ensemble des données. La structure montre un domaine bien résolu SRP ARN et SRP M avec une séquence signal liée. L'interaction entre les SRP et le ribosome pourrait être modélisée avec une grande fidélité. Cette structure révèle également que les GTPases SRP-ftsY sont détachées de la tétra-boucle de l'ARN et sont flexibles, libérant alors le site de sortie du ribosomepermettant la liaison du translocons.Dans le second projet, différentes approches ont été poursuivis pour résoudre la structure du complexe ribosome-HTL à haute résolution. Une structure initiale à 22 Å a été obtenue en mélangeant HTL solubilisés en détergent avec des ribosomes, démontrantla possibilité de préserver le complexe dans les conditions utilisées pour la préparation des grilles. J'ai ensuite exploré l'utilisation de nanodiscs et un nouveau détergent appelé LMNG pour stabiliser HTL dans des tampons sans détergent. Un deuxième ensemble de données a ensuite été recueilli à partir d'échantillon obtenu par gradient de fixation, la structure a été résolue à 17 Å. La préparation des échantillons a été optimisée utilisant entre autre les amphipoles. On a montré que deux types d'amphipole-HTL peuvent se lier au ribosome, et des structures de plus grande résolution devrait être obtenu à partir de ces échantillons. / The cell membrane is the barrier that separates the interior of cells from the outside environment. It consists of lipids and proteins. Genes encoding membrane proteins make up about 30% of the genome. Membrane proteins are synthesized in the cytosol by ribosomes, but employ special pathways to integrate into the cell membrane. Ribosomes translating membrane proteins are recognized by special factors in the cytosol and targeted to the membrane. Subsequently, nascent chains of the membrane proteins are inserted into the lipid bilayer and are folded into their proper structures, a process termed translocation. The targeting process is mediated by the signal recognition particle (SRP) and its receptor, while the translocation is performed by a number of membrane protein complexes.This thesis describes two of the complexes involved in co-translational targeting and translocation in Escherichia coli: The ribosome-SRP-FtsY targeting complex in the “closed” conformation and the complex of a ribosome with the holo-translocon (HTL) consisting of seven membrane proteins. I mainly used electron cryo-microscopy to characterize these complexes. Cryo-EM allows structural determination of biological samples at sub-nanometer resolution in their native environment, without the need to crystallize the specimen. In this work, I took advantage of the recent advances in both the hardware and the image processing.Starting from a cryo-EM dataset obtained by group members, I have determined the structure of ribosome-SRP-FtsY complex in the “closed” conformation at 5.7 Å resolution. Different computational sorting strategies were applied to identify the most homogeneous sub-pool of the dataset. The structure shows a well-resolved SRP RNA and SRP M domain with a signal sequence bound. The interaction between SRP and ribosome could be modeled with high confidence. This structure also reveals that the SRP-FtsY GTPases are detached from the RNA tetraloop and are flexible, thus liberating the ribosomal exit site for binding of the translocation machinery.In the second project, different approaches were pursued to solve the structure of the ribosome-HTL complex at high resolution. An initial structure at 22 Å was obtained by mixing detergent-solubilized HTL with the ribosome, demonstrating that it is possible to preserve the complex under the conditions used for specimen preparation. I have then explored the use of nanodiscs and a new detergent called LMNG to stabilize HTL in detergent-free buffers. A second dataset was subsequently collected from a sample prepared by gradient-fixation, and the structure was solved at 17 Å. Sample preparation has been optimized further using amphipols. Two types of amphipol-HTL complexes were shown to bind to the ribosome, and higher resolution structures are expected to be obtained from these samples.

Cryo-microscopie électronique

Protéine membranaire

Ribosome

Adressage des protéines

Translocation des protéines

Electron cryo-microscopy

Membrane protein

Ribosome

Protein targeting

Protein translocation

500

570